Your search keyword '"Vijayakumar, S. P."' showing total 332 results

101. Aircraft measurements of aerosol black carbon from a coastal location in the north-east part of peninsular India during ICARB

Author

Babu, S. Suresh, Satheesh, S. K., Moorthy, K. Krishna, Dutt, C. B. S., Nair, Vijayakumar S., Alappattu, Denny P., and Kunhikrishnan, P. K.

Published

2008

102. Multi-criteria decision-making and artificial bee colony algorithm for optimization of process parameters in pyramid solar still

Author

Paulsingarayar, S., Suresh Kumar, R., Vijayakumar, S. Joseph Dominic, and Kumar, N. Mathan

Abstract

This study focuses on optimizing process parameters for pyramid solar still using Multi-Criteria Decision-Making Grey Relational Analysis (MCDM-GRA) and bio-inspired metaheuristic Artificial Bee Colony (ABC) algorithm. The objective is to enhance the performance of the pyramid solar still (PSS) performance integrated with a peripheral solar water heater under different operational parameters, including saline water flow rate, temperature, and solar intensity. Experiments are designed using Taguchi's L9(33) orthogonal array (OA), and the outputs are optimized with MCDM-GRA. The optimum conditions for maximized productivity and system efficiency are a solar intensity of 1000 W/m2, a saline water mass of 3 kg, and a saline water temperature of 40 °C. With these settings, the system achieves an efficiency of 65.33 % and produces 1.96 kg of potable water. The ABC Algorithm, on the other hand, suggests that the optimal conditions for achieving maximum productivity and system efficiency involve a solar intensity of 1000 W/m2, a mass of 3 kg for the saline water, and a water inlet temperature of 30 °C. In this scenario, the system produced 1.92 kg of potable water with an efficiency rate of 64 %. Analysis of variance (ANOVA) shows that solar intensity contributes significantly towards productivity by 81.72 % with an error of 3.82 % and regression coefficient of 96.18 %. Regression models are developed from the results obtained and fed to ABC for further optimization, yielding results similar to MCDM-GRA.

Published

2024

103. Walkerana muduga Dinesh & Vijayakumar & Ramesh & Jayarajan & Chandramouli & Shanker 2020, sp. nov

Author

Dinesh, K. P., Vijayakumar, S. P., Ramesh, Vijay, Jayarajan, Aditi, Chandramouli, S. R., and Shanker, Kartik

Subjects

Insecta, Arthropoda, Haglotettigoniidae, Walkerana, Animalia, Orthoptera, Biodiversity, Walkerana muduga, Taxonomy

Abstract

Walkerana muduga sp. nov. (Table 1, 2; Fig. 1,2,3,4,5) Holotype: ZSI / WRC /A/2211 (CESF 1607), an adult male (SVL 27.9 mm) collected by S.P. Vijayakumar and team in October 2010 from Muthikulam, (N 10.945; E 76.644) a high elevation site (1544 amsl) in the hill range Elivalmala / Elivalmalai located north of Palghat Gap. Paratype: ZSI / WRC /A/2212 (CESF 1606), an adult female (SVL 44.9 mm), collection data same as the holotype. Etymology: The new species is named after the ���Mudugar��� indigenous community of Palghat district, Kerala who speak ���Muduga��� language (Menon, 1996). The species epithet is used as an invariable noun in apposition to the generic name. The suggested common name is ���Muduga mountain leaping frog���. Lineage diagnosis: Walkerana muduga sp. nov. can be diagnosed phylogenetically as a member of the ��� Walkerana clade��� (Fig. 2), and exhibits 5.7% genetic divergence from W. leptodactyla, 7.5% divergence from W. phrynoderma and 11.7% divergence from W. diplosticta at the 16S rRNA fragment. The species is highly divergent in morphology from all known species (see comparison section). Phylogenetic analysis also shows another undescribed lineage from the adjacent massif (north of Elival Mala), exhibiting high genetic divergence of 3.8 % for 16S rRNA (CESF 1554). However, due to the availability of only a single poorly preserved specimen (CESF 1554), we defer the description of this lineage. Description of Holotype ZSI/WRC/A/2211 (CESF 1607) (Fig. 2, 3). A medium sized species of Walkerana (SVL = 27.9 mm) with squat, raised body; head width (HW = 11.3 mm) sub equal to head length (HL = 10.3 mm); snout bluntly pointed (ES = 4.7 mm) in both dorsal and ventral view and more than 1.2 times of eye diameter (ED = 3.9 mm); canthus rostralis angular, loreal region concave, inter orbital space flat (IO = 3.0 mm) and sub equal to upper eye lid (UEW = 2.4 mm); nostrils oval, nearer to tip of snout than to eye; eyes relatively smaller (EL/HL = 0.37), protruding out of the head; tympanum (TYH = 2.2 mm) distinct below the supratympanic fold and 1.7 times of eye diameter; minute vomerine ridges present with 2 to 3 spinular teeth; tongue bifid with a raised papilla; symphysial knob weak. Fore arm slender (UAL = 4.7 mm) and sub equal to hand (PAL = 7.6 mm); fingers short and thin (dermal fringes distinct in the ventral view on the finger 2, 3 and 4); first finger shorter than second (f1 = 3.7 mm and f2 = 4.2 mm); finger tips with truncated enlarged discs with minute dorsoterminal grooves; fingers free without webbing between fingers; rounded subarticular tubercles moderate (one each on finger 1 and 2, and two each on finger 3 and 4); prepollex indistinct and palmar tubercle distinct, supernumerary tubercles absent. Hind limbs moderately long, strongly overlap when folded at right angles to the body and tibio-tarsal articulation reaches beyond the snout tip; femur length less than tibia length (FEL = 14.9 mm; TBL = 18.2 mm); foot length is 1.8 times more than the tarsus length (FOL = 14.9 mm, TAR = 8.1 mm), relative toe length ISecondary sexual characters: No visible external sexual dimorphism was noticeable except for the amplected pairs where males are smaller than the females. Additional information from paratypes and variations: Morphological data are given in Table 1. Paratype ZSI / WRC /A/2212 (CESF 1606), an adult female (SVL 44.9 mm) and other reference collections (CESF 1608, male, SVL 22.7 mm) were similar to holotype in all the external morphological characters. Distribution: Walkerana muduga sp. nov. is known from the Elivalmalai range, north of the Palghat Gap and south of Nilgiri Massif. Comparisons: All the described species of Walkerana are known to occur in the high elevation ranges south of the Palghat Gap. There are no congeners for Walkerana muduga sp. nov. north of the Palghat Gap. However, there is a deeply divergent lineage (CESF 1554) (see diagnosis) recovered from an adjacent massif. Walkerana muduga sp. nov. differs from the undescribed Walkerana sp. (CESF 1554) in having higher HL/SVL ratio of 0.370 to 0.405 (n=2) (vs. lower HL/SVL ratio of 0.342 (n=1)); higher HW/SVL ratio of 0.397 to 0.406 (n=2) (vs. lower HW/SVL ratio of 0.390 (n=1)); lower TYH/SVL ratio of 0.079 to 0.080 (n=2) (vs. higher TYH/SVL ratio of 0.083 (n=1)); higher IO/SVL ratio of 0.107 to 0.109 (n=2) (vs. lower IO/SVL ratio of 0.097 (n=1)); higher PAL/SVL ratio of 0.257 to 0.271 (n=2) (vs. lower PAL/SVL ratio of 0.234 (n=1)); higher f1/SVL ratio of 0.119 to 0.133 (n=2) (vs. lower f1/SVL ratio of 0.112 (n=1)); higher f2/SVL ratio of 0.131 to 0.151 (n=2) (vs. lower f2/SVL ratio of 0.123 (n=1)); lower FEL/SVL ratio of 0.535 to 0.536 (n=2) (vs. higher FEL/SVL ratio of 0.545 (n=1)); lower TAR/SVL ratio of 0.287 to 0.291 (n=2) (vs. higher TAR/SVL ratio of 0.295 (n=1)); higher FOL/SVL ratio of 0.536 to 0.565 (n=2) (vs. lower FOL/SVL ratio of 0.530 (n=1)). Walkerana muduga sp. nov. differs from species found south of the Palghat Gap (see key to the species of Walkerana by Dahanukar et al. 2016) in having distinct canthus rostralis and smooth skin (vs. indistinct canthus rostralis and warty skin in W. phrynoderma); lacking a distinct pair of black patches on the loin (vs. distinct black patch on the loin in W. diplosticta) and tympanum relatively smaller than the diameter of eye (vs. tympanum three-fourth of the diameter of eye in W. leptodactyla)., Published as part of Dinesh, K. P., Vijayakumar, S. P., Ramesh, Vijay, Jayarajan, Aditi, Chandramouli, S. R. & Shanker, Kartik, 2020, A deeply divergent lineage of Walkerana (Anura: Ranixalidae) from the Western Ghats of Peninsular India, pp. 266-276 in Zootaxa 4729 (2) on pages 269-271, DOI: 10.11646/zootaxa.4729.2.7, http://zenodo.org/record/3632638, {"references":["Menon, M. T. (1996) The encyclopedia of Dravidian tribes. Vol. II. Thiruvananthapuram, Kerala. International School of Dravidian Linguistics, 1996, 1 - 347.","Dahanukar, N., Modak, N., Krutha, K., Nameer, P. O., Padhye, A. D. & Molur, S. (2016) Leaping frogs (Anura: Ranixalidae) of the Western Ghats of India: An integrated taxonomic review. Journal of Threatened Taxa, 8, 9221 - 9288. https: // doi. org / 10.11609 / jott. 2532.8.10.9221 - 9288"]}

Published

2020

104. Walkerana

Author

Dinesh, K. P., Vijayakumar, S. P., Ramesh, Vijay, Jayarajan, Aditi, Chandramouli, S. R., and Shanker, Kartik

Subjects

Insecta, Arthropoda, Haglotettigoniidae, Walkerana, Animalia, Orthoptera, Biodiversity, Taxonomy

Abstract

Phylogeny of Walkerana and generic allocation of the new lineage Among the members of Ranixalidae, we recovered two well supported clades assignable to the genera, Walkerana and Indirana, as in the studies of Dahanukar et al. (2016) and Garg & Biju (2016). The new deeply divergent lineage is assigned to the genus Walkerana, based on its phylogenetic position within Ranixalidae (Fig. 2)., Published as part of Dinesh, K. P., Vijayakumar, S. P., Ramesh, Vijay, Jayarajan, Aditi, Chandramouli, S. R. & Shanker, Kartik, 2020, A deeply divergent lineage of Walkerana (Anura: Ranixalidae) from the Western Ghats of Peninsular India, pp. 266-276 in Zootaxa 4729 (2) on page 269, DOI: 10.11646/zootaxa.4729.2.7, http://zenodo.org/record/3632638, {"references":["Dahanukar, N., Modak, N., Krutha, K., Nameer, P. O., Padhye, A. D. & Molur, S. (2016) Leaping frogs (Anura: Ranixalidae) of the Western Ghats of India: An integrated taxonomic review. Journal of Threatened Taxa, 8, 9221 - 9288. https: // doi. org / 10.11609 / jott. 2532.8.10.9221 - 9288","Garg, S. & Biju, S. D. (2016) Molecular and morphological study of leaping frogs (Anura, Ranixalidae) with description of two new species. PLoS ONE, 11 (11), e 0166326. https: // doi. org / 10.1371 / journal. pone. 0166326"]}

Published

2020

105. The impact of age and comorbidity on survival outcomes and treatment patterns in prostate cancer

Author

Hall, W H, Jani, A B, Ryu, J K, Narayan, S, and Vijayakumar, S

Published

2005

106. Clinical characteristics of African-American men with hereditary prostate cancer: the AAHPC study

Author

Ahaghotu, C, Baffoe-Bonnie, A, Kittles, R, Pettaway, C, Powell, I, Royal, C, Wang, H, Vijayakumar, S, Bennett, J, Hoke, G, Mason, T, Bailey-Wilson, J, Boykin, W, Berg, K, Carpten, J, Weinrich, S, Trent, J, Dunston, G, and Collins, F

Published

2004

107. Safety and outcome after fludarabine–thiotepa–TBI conditioning for allogeneic transplantation: a prospective study of 30 patients with hematologic malignancies

Author

van Besien, K, Devine, S, Wickrema, A, Jessop, E, Amin, K, Yassine, M, Maynard, V, Stock, W, Peace, D, Ravandi, F, Chen, Y-H, Cheung, T, Vijayakumar, S, Hoffman, R, and Sosman, J

Published

2003

108. Evolution of toxicity after conformal radiotherapy for prostate cancer

Author

Abdalla, I, Ignacio, L, Vaida, F, Mei-Hsu, Awan, A, Jani, A, Mamo, C, Weichselbaum, R R, and Vijayakumar, S

Published

2002

109. Defect analysis and evaluation of mechanical properties of tig welded chrome alloy steel joints for high temperature applications

Author

Pydi, Hari Prasadarao, Pasupulla, Ajay Prakash, Vijayakumar, S., and Indira, K. P.

Published

2022

110. Determining levels of cryptic diversity within the endemic frog genera, Indirana and Walkerana, of the Western Ghats, India

Author

Ramesh, Vijay, primary, Vijayakumar, S. P., additional, Gopalakrishna, Trisha, additional, Jayarajan, Aditi, additional, and Shanker, Kartik, additional

Published

2020

111. Hypolipidemic effect of flavonoids from Solanum melongena

Author

Sudheesh, S., Presannakumar, G., Vijayakumar, S., and Vijayalakshmi, N. R.

Published

1997

112. Molecular dynamics simulations of DNA and a protein-DNA complex including solvent

Author

Beveridge, D. L., McConnell, K. J., Young, M. A., Vijayakumar, S., and Ravishanker, G.

Published

1995

113. Analyze of facial expression and hand gestures using deep learning

Author

Gopinath, D., Vijayakumar, S., and Harish, Jai

Published

2022

114. Exploring the Drug Potential of Phytochemicals as a Novel Therapeutic Drug Candidate for Herpesvirus: An In-silico Evaluation

Author

Rani, A. Christy, Kalaimathi, K., Jayasree, S., Prabhu, S., Vijayakumar, S., Ramasubbu, Raju, and Priya, N. Sathammai

Abstract

Generally, the herpes virus is categorized into HSV-1 and HSV-2, with HSV-1 being transmitted through oral contacts. In contrast, HSV-2 is transmitted during sexual intercourse; hence known as genital herpes. In the infected individual, the majority of HSV infections are asymptomatic, although herpes can cause painful blisters or ulcers. On the other hand, HSV-2 infection increases the possibility of both transmission and contraction of HIV. In order to eradicate these viral infection complications and avoid the possibility of contracting HIV, few drugs have been prescribed for decades when infected with this viral infection. However, the prescribed drugs are not effective in eradicating this virus from infected individuals, which means few virus particles are latent after treatment with these drugs. Therefore, to investigate the novel anti-herpes potential of phytochemicals, the Maestro V13.3 was run with LigPrep, Grid Generation, SiteMap, Glide XP Docking, Pharmachophores and MM-GBSA. Ultimately, the docking result showed that all examined phytocomponents except ellagic acid had good docking values of − 8.321 (epicatechin), − 8.001 (rac 8-prenylnaringenin), − 7.531 (apigenin) and − 7.252 (−D-(+)-catechin) exhibited. In this in-silico assessment, we confirmed that the phytochemicals had more potential scores in docking scores, binding affinity, and MM-GBSA scores compared to the corresponding anti-herpes drugs. Apart from the molecular docking and MM-GBSA values, the phytochemicals were found to have good pharmacological potentials through pharmacophore and pharmacokinetic assessments. Moreover, we believe that compounds such as epicatechin, Rac 8-prenylnaringenin, apigenin and -D-(+)-catechin would reveal possible therapeutic effects when tested in-vitro and in-vivo trials. Finally, the present research suggests that although these molecules have such therapeutic potential, a detailed toxicological study of these molecules should be performed in a dose-dependent manner prior to clinical trials.

Published

2022

115. Speckle noise reduction in SAR images using type-II neuro-fuzzy approach

Author

Vijayakumar, S. and Santhi, V.

Abstract

Synthetic aperture RADAR (SAR) images play a vital role in remote sensing applications and thus it insists the requirement of quality enhancement as it gets affected with speckle noise. It is a kind of noise that gets multiplied with pixel intensities due to interference of backscattering signal. In this paper, computational intelligence-based approach is proposed to remove speckle noise by preserving edges and texture information. In particular, the proposed system uses type-II neuro-fuzzy approach using pixel neighbourhood topologies. The performance efficiency of the proposed system is proved by comparing its results with existing methods.

Published

2022

116. MOVEMENT PREDICTION AND ALERT GENERATION IN SLACK USING MOTION SENSORS INTEGRATED WITH MOBILE ADHOC NETWORKS.

Author

GOPAL, R., KUMARESAN, M., ANNAMALAI, S., VIJAYAKUMAR, S., and MATHIVANAN, M.

Published

2021

117. Microauris Pal & Vijayakumar & Shanker & Jayarajan & Deepak 2018, gen. nov

Author

Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi, and Deepak, V.

Subjects

Reptilia, Squamata, Animalia, Biodiversity, Microauris, Chordata, Agamidae, Taxonomy

Abstract

Microauris gen. nov. (Fig. 8b) Type species. Calotes aurantolabium (Krishnan, 2008) Etymology. The genus epithet is derived by adding the word ‘Micro’ as a prefix to the Latin word ‘auris’ meaning ear, referring to the extremely small tympanum of this genus. Diagnosis. Microauris gen.nov. differs from all other members of draconinae lizards from the Indian subcontinent in having the smallest tympanum. Microauris gen.nov. differs from Mantheyus phuwuanensis by the absence of femoral pores (Manthey & Nabhitabhata, 1991; Ananjeva & Stuart 2001); from the members of the genus Bronchocela by the absence of a fold of skin from angle of jaw to shoulder (Hallermann & Böhme 2000). Microauris gen. nov. can be easily diagnosed from the genera Otocryptis, Sarada and Sitana by the presence of a well-developed fifth toe (Smith, 1935; Deepak et al, 2016); from Cophotis, Ceratophora, Lyriocephalus, Ptyctolaemus, Phoxophrys, Japalura otai, J. planidorsata, J. sagittifera and Otocryptis by the presence of external tympanum (Boulenger, 1885; Smith, 1935; Inger, 1 960; Pethiyagoda & Manamendra-Arachchi 1998; Schulte II et al. 2004; Bahir & Silva 2005; Manamendra-Arachchi et al. 2006; Samarawickrama et al. 2006). Microauris gen. nov. can be diagnosed from other members of genus Japalura by the absence of heterogenous dorsal scales and short and thick nuchal scales; from Salea by the absence of enlarged plate like scales between the eye and tympanum (Smith, 1 935). Microauris gen. nov. can be diagnosed from the members of Psammophilus and Monilesaurus by the absence of a well developed antehumeral fold. Microauris gen. nov. can be diagnosed from Complictus nigrigularis, Hypsicalotes kinabaulensis, Malayadracon robinsonii, Oriocalotes, Pseudocophotis and Pseudocalotes by the absence of enlarged row of suborbital scales (Smith, 1935; Taylor 1963; Ota & Hikida, 1991; Manthey & Denzer 1992; Inger & Steubing 1994; Ota & Hikida, 1996; Hallermann & Böhme 2000; Manthey & Denzer, 2000; Hallermann & McGuire 2001; Leong 2001; Manamendra-Arachchi et al. 2006; Samarawickrama et al. 2006; Ananjeva et al. 2007; Hallermann & Böhme 2007; Das & Lakim 2008; Hallermann et al. 2010; Mahony 2010; Harvey et al. 2014; Denzer et al. 2015; Grismer LL et al. 2016; Harvey et al. 2017). Microauris gen.nov. can be distinguished from the members of the genus Calotes (C. bachae, C. bhutanensis, C. calotes, C. ceylonensis, C. chincollium, C. desilvai, C. emma, C. grandisquamis, C. hutunwini, C. irawadi, C. jerdoni, C. liocephalus, C. liolepis, C. versicolor, C. manamendrai, C. maria, C. medgoensis, C. minor, C. mystaceus, C. nemoricola, C. nigrilabris, C. nigriplicatus and C. pethiyagodai) and Lophocalotes (Günther, 1872) in having the smallest tympanum (Hardwicke & Gray, 1827; Duméril and Bibron, 1837; Gray, 1845; Jerdon, 1854; Günther, 1864; Günther, 1870, Günther, 1872, Günther, 1875; Boulenger, 1885; Biswas, 1975; Zhao & Li, 1984; Hallerman, 2000; Vindum et al. 2003; Hallerman et al. 2004; Bahir & Maduwage, 2005; Zug et al. 2006; Manthey, 2008; Krishnan, 2008; Hartmann et al. 2013; Amarasinghe et al. 2014a, b; Deepak et al. 2015). Suggested English. Small-eared dragon Holotype. BNHS 1436, an adult female collected from Kalakkad Mundanthurai Tiger Reserve, Tamil Nadu, India; by N. M. Ishwar in 1997. Referred specimens. CESL 104, an adult female collected from a branch in the canopy of a shola forest tree near Chemunji peak, Peppara Wildlife Sanctuary, Kerala, India; by SPP, SPV, MVP, VTR and ADR in 18th August 2010. Taxonomic comments. Microauris aurantolabium comb. nov. was described as Calotes aurantolabium in 2008 based on a single specimen (Krishnan 2008). Prior to this, the specimen was wrongly identified and reported as the rediscovery of Calotes andamanensis. (Ishwar and Das, 1998). During our fieldwork in the Agasthyamalai hills of Kerala in August 2010, we found a single female specimen sleeping on a branch of a tree in a shola forest. There have been no other reports of this species thereafter and thus all the known specimens are females. There is a clear gap in the knowledge of the morphology of this rare lizard considering that male lizards are known to be better representatives for morphological characterization because of the presence of secondary sexual characters. In spite of this, the two specimens share some common characters, which are unique to this lizard. Based on the presence of unique morphological characters along with the phylogenetic position of this species in the subfamily Draconinae, we designate this species as a new monotypic genus. Diagnosis. A medium sized light green agamid lizard with a distinct orange streak from above the lip scales till behind the jaw; a moderately broad head with a pointed snout; very small tympanum relative to the orbit diameter (TymD/OrbD = 0.14–0.19); acutely keeled scales over the body and throat; scales on head small, sub-triangular (vs. uniform shield like in members of genus Calotes); 3rd and 4th toe almost equal in length; dorsal and lateral body scales oriented backwards and downwards; nuchal crest indistinct, poorly developed; supratympanic and postorbital spines absent and a long and slender tail. Description of the Holotype. BNHS 1436; a medium sized agamid, adult female (SVL- 68.5 mm) Morphometric and meristic data are summarised in Appendix 2 & 3. General habitus moderately compressed. Head moderate (HL/SVL ratio 0.28), broad (HW/HL ratio 0.56), maximum height less than maximum width; snout pointed; rostral broader than high; nostrils in single nasal shield, which is separated from rostral by a single scale; mental shield almost as wide as the rostral; two postmentals; first pair touching each other at the base; genials partially keeled; gular sac small, composed of partially keeled scales, slightly smaller than genials; scales on the snout smooth, unkeeled; scales on top of head heterogenous, keeled, small, subtriangular; supraorbital scales keeled; orbit diameter 95% of distance between anterior border of orbit and snout tip; tympanum very small, exposed, its greatest diameter 11% of horizontal diameter of orbit; slightly keeled scales between tympanum and orbit; posterior region of jaws partially swollen; supralabials 10/10; infralabials 11/11. Nuchal crest poorly developed, composed of 13 small conical spines; the remaining vertebral scales slightly enlarged relative to adjacent rows and possess a more pronounced median keel; 54 longitudinal scale rows around midbody; scales on dorsum keeled; lateral scales smaller than dorsal, keeled, oriented postero-ventrally; ventrals slightly larger then dorsals, genials and gular scales strongly keeled. Limbs slender and covered with strongly keeled scales, larger than laterals; scales under thighs keeled; length of hindlimb ca. 64% SVL; relative lengths of toes 4=3>5>2>1; fourth toe and third toe subequal; 20 subdigital lamellae under fourth finger; 21 subdigital lamellae under fourth toe; tail slender, long; scales on dorsal and ventral surface of tail with sharp keels, mucronate, slightly larger than laterals; tail length 117 mm. Colouration. In life (CESL 104): dorsum and head uniform, light green overall with a distinct reddish orange streak from above the third lip scale covering 2–3 scale rows below the tympanum, ending just at the shoulder. A distinct pale whitish grey band, edged with black speckles from the base of tail till underside of knee. Mid-dorsal scales edged anteriorly with black, which is visible when the body is inflated; gular scales lighter, yellowish green; ventrally brighter, uniform green with a few rows of pale whitish scales towards the lateral side. This lizard was observed to quickly change its body color to dark blackish-brown on disturbance but the orange streak and band on thigh remained unchanged. In preservative: dorsum and head uniform, overall pale blue with brownish patches above the eyes and neck continuing on the mid-dorsal line, broader towards the tail; tail pale brown; orange lip streak paler turning whitish towards the neck; laterally pale blue with anteriorly black edged scales; ventrally pale whitish grey overall; limbs edged with brown blotches, broader towards the tips. Distribution. Currently, this lizard is known only from two sites in the high elevation tropical evergreen forests of Agasthyamalai hills. The second locality near Chemunji peak in Peppara wildlife sanctuary is approximately 50 kms northeast of the type locality near Kakachi in KMTR (See Appendix 1 for details). Both these sites are separated by almost contiguous shola grassland mosaic on undulating hills. Ecology and natural history. Nothing much is known about the ecology and natural history of this species. Ishwar and Das (1998) reported sightings of 3 individuals, all gravid females in the month of August. Two of these lizards laid 4 elliptical eggs each. This suggests that monsoon might be a breeding season for this lizard. Ishwar and Das (1998) also mentioned that this is a canopy dwelling species. The fact that it was only found again 12 years after its discovery and that too from a fairly well explored habitat suggests that this might be a rare lizard or it may occur high in the canopy of rain forests and thus escape detection.

Published

2018

118. Calotes Cuvier 1817

Author

Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi, and Deepak, V.

Subjects

Reptilia, Squamata, Calotes, Animalia, Biodiversity, Chordata, Agamidae, Taxonomy

Abstract

Calotes Cuvier, 1817 The genus Calotes Cuvier, 1817 with the type species Lacerta calotes Linnaeus, 1758 belongs to the subfamily Draconinae of the family Agamidae, containing 26 species. The geographical distribution of this genus is largely restricted to South Asia and Indo-china, except for one isolated species Calotes nigriplicatus Hallermann, 2000 found in Ambon Island in Indonesia. The greatest diversity of the genus is in the Western Ghats and Sri Lanka. Four species of Calotes (C. grandisquamis, C. nemoricola, Calotes cf. versicolor , Calotes calotes) are known from the Western Ghats of which two are endemic to this region. Diagnosis. Medium to large sized agamids with a relatively broader head; dorsal and lateral scales uniform, arranged in rows of backwardly pointed scales; dorsal and nuchal crest more or less developed; groups or rows of spines from eye to above tympanum; often an antehumeral skin fold or pit present covered with small scales; gular sac usually present; tympanum naked; tail long and slender, usually swollen and rounded at the base in males; no preanal or femoral pores. Distribution. Lizards belonging to the Genus Calotes are widely distributed across Iran, Afghanistan, Bhutan, Bangladesh, Maldives, Nepal, India, Pakistan and Sri Lanka as well as southern China; parts of Myanmar, Thailand, Laos, Cambodia, Vietnam, Peninsular Malaysia and parts of Indonesia. Moreover, Calotes versicolor has been introduced into Kenya, Borneo, Sulawesi, Seychelles, Mauritius, Oman and Florida (USA) (Das et al. 2008; Manthey, 2008; Uetz and Ho��ek, 2016). Taxonomic groups. Smith (1935) separated members of the genus Calotes into four distinct groups, I. C. cristatella group, II. C. microlepis group, III. C. versicolor group, and IV. C. liocephalus group, each composed of multiple species and another group composed of two dwarf species based on their morphological similarities. Later, Moody (1980) separated the genus into four different genera, namely Bronchocela Kaup, 1827 (group I of Smith), Dendragama Doria, 1888, Pseudocalotes Fitzinger, 1843 (group II of Smith) and Calotes (group III, IV and the two dwarf species of Smith). Most of the Calotes species occurring in the Western Ghats belong to the Calotes versicolor group of Smith (1935) except Calotes rouxii and Calotes ellioti, which belong to the dwarf group. Here, we transfer these two species to the new genus Monilesaurus gen. nov. In the present study, we follow Smith���s species groups for taxonomic accounts and morphological comparisons. Since Smith, there have been various new additions to the genus Calotes and to the Calotes versicolor group. In this study, we compare each individual species only with members of their own group. Calotes versicolor group. Members of the C. versicolor group are characterized by a medium to large adult body size; body more or less compressed, dorsal and lateral scales large, uniform, smooth or feebly keeled and oriented postero-dorsally; antehumeral fold absent; dorsal scales larger than the ventrals except in C. calotes where it is equal to or slightly smaller than the ventrals; nuchal and dorsal crest well developed, continuous, at least till behind the shoulders; postorbital spine absent except in C. emma Gray, 1845; supratympanic spines in form of paired patches or as a single longitudinal series of spines (Fig. 4 & 5). For taxonomic comparisons, we add the recently designated C. minor to Smith���s C. versicolor group (See Deepak et al. 2015). Content. Calotes bachae Hartmann, Geissler, Poyarkov, Ihlow, Galoyan, R��dder & B��hme, 2013; C. bhutanensis Biswas, 1975; C. calotes; C. ceylonensis M��ller, 1887; C. chincollium Vindum, 2003; C. desilvai Bahir & Maduwage, 2005; C. emma; C. grandisquamis, C. hutunwini Zug & Vindum, 2006; C. irawadi Zug, Grown, Schulte & Vindum, 2006; C. jerdoni G��nther, 1870; C. liocephalus G��nther, 1872; C. liolepis Boulenger, 1885; C. versicolor, C. manamendrai Amarasinghe & Karunarathna, 2014; C. maria Gray, 1845; C. medgoensis Zhao & Li, 1984; C. minor, C. mystaceus Dum��ril & Bibron, 1837; C. nemoricola, C. nigrilabris Peters, 1860; C. nigriplicatus Hallermann, 2000 and C. pethiyagodai Amarasinghe, Karunarathna, Hallermann, Fujinuma, Grillitsch & Campbell, 2014. Diagnosis. All the species belonging to this group can be differentiated from the other groups of Calotes based on the combination of the following characters: From members of the genus Monilesaurus gen.nov., they can be easily distinguished morphologically based on a larger adult size (vs. smaller); dorsal and lateral scales rows directed posterodorsally, much larger in size (vs. posteroventrally, smaller in size); dorsal and lateral scales larger than ventrals, except in C. calotes (vs. not larger than ventrals) (Fig. 4���5 vs 6���7) and absence of antehumeral fold (vs. presence of a well developed antehumeral fold) (Fig. 10). From members of the genus Psammophilus, group they can be distinguished by the presence of compressed body shape (vs. depressed) (Fig. 4���5 vs 8a); absence of an antehumeral fold (vs. antehumeral fold present) (Fig. 10f vs 10g); lateral scales much larger (vs. smaller); presence of well developed nuchal crest (vs. reduced) and lesser number of midbody scale rows, less than 60 (vs. scale rows higher in number, more than 80). From Microauris gen. nov. by having a relatively large tympanum (Fig. 9a vs 9b); scales on head large uniform shield like (vs. small, sub-triangular) (Fig. 10b vs 10d)., Published as part of Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi & Deepak, V., 2018, A systematic revision of Calotes Cuvier, 1817 (Squamata: Agamidae) from the Western Ghats adds two genera and reveals two new species, pp. 401-450 in Zootaxa 4482 (3) on pages 414-418, DOI: 10.11646/zootaxa.4482.3.1, http://zenodo.org/record/1440674, {"references":["Manthey, U. (2008) Agamid Lizards of Southern Asia, Draconinae 1. Edition Chimaira, Frankfurt, 160 pp.","Uetz, P. & Hosek, J. (2016) The Reptile Database. Available from: http: // reptile-database. reptarium. cz (accessed 6 May 2016)","Smith, M. A. (1935) The Fauna of British India, Including Ceylon and Burma; Reptilia and Amphibia. Fol. II. Sauria. Taylor and Francis, London, 440 pp.","Moody, S. M. (1980) Phylogenetic and historical biogeographical relationships of the genera in the family Agamidae (Reptilia; Lacertilia). Unpublished thesis, The University of Michigan, Ann Arbor, Michigan, 373 pp.","Gray, E. (1845) Catalogue of the specimens of lizards in the collection British museum. Trustees of die British Museum / Edward Newman, London, 289 pp.","Deepak, V., Vyas, R., Giri, V. B. & Karanth, K. P. (2015) A taxonomic mystery for more than 180 years: the identity and systematic position of Brachysaura minor (Hardwicke & Gray, 1827) Fertebrate Zoology, 65 (3), 371 - 381.","Hartmann, T., Geissler, P., Nikolay, A. J., Ihlow, P. F., Galoyan, E. A., Rodder, D. & Bohme, W. (2013) A new species of the genus Calotes Cuvier, 1817 (Squamata: Agamidae) from southern Vietnam. Zootaxa, 3599 (3), 246 - 260. https: // doi. org / 10.11646 / zootaxa. 3599.3.3","Biswas, S. (1975) Reptilia from Bhutan with description of a new species of Calotes Rafinesque. Journal of Bombay Natural History Society, 72, 774 - 777.","Vindum, J. V., Win, H., Thin, T., Lwin, K. S., Shein, A. K. & Tun, H. (2003) A new Calotes (Squamata: Agamidae) from the Indo-Burman range of western Myanmar (Burma). Proceedings of the California Academy of Science, 54 (1), 1 - 16.","Bahir, M. M. & Silva, A. (2005) Otocryptis nigristigma, a new species of agamid lizard from Sri Lanka. In: Yeo, C. J., Ng, P. K. L. & Pethiyagoda, R. (Eds.), Contributions to biodiversity exploration and research in Sri Lanka. The Raffles Bulletin of Zoology, 12 (Supplement), 393 - 406.","Zug, G. R., Brown, H. H., Schulte, J. A. & Vindum, J. V. (2006) Systematics of the Garden Lizards, Calotes versicolor Group (Reptilia, Squamata, Agamidae), in Myanmar: Central Dry Zone Populations. Proceedings of the California Academy of Sciences, 57 (2), 35 - 68.","Gunther, A. (1870) Descriptions of a new Indian lizard of the genus Calotes. Proceedings of the Zoological Society of London, 778 - 779.","Gunther, A. (1872) Descriptions of some Ceylonese Reptiles and Batrachians. Annals Magazine of natural History, 4, 85 - 88. https: // doi. org / 10.1080 / 002229372011951778","Boulenger, G. A. (1885) Catalogue of lizards in the British museum. Fol. 1. Geckonidae, Eublepharidae, Uroplatidae, Pygopodidae, Agamidae, Second edition. British Museum (Natural History), London, 436 pp.","Zhao, E. & Li, S. (1984) A new species of Calotes (Lacertilia: Agamidae) from Xizang (Tibet) [in Chinese]. Acta Herpetologica Sinica, 3 (4), 77 - 78.","Dumril, A. M. C. & Bibron, G. (1837) Erpetologie Generale ou Histoire Naturelle Complete des Reptiles. Fol. 4. Librairie Encyclopedique Roret, Paris, 570 pp.","Amarasinghe, A. A. T., Karunarathna, D. M. S. S., Hallermann, J., Fujinuma, J., Grillitsch, H. & Campbell, P. D. (2014 b) A new species of the genus Calotes (Squamata: Agamidae) from high elevations of the Knuckles Massif of Sri Lanka. Zootaxa, 3785 (1), 059 - 078. http: // doi. org / 10.11646 / zootaxa. 3785.1.5"]}

Published

2018

119. Psammophilus Fitzinger 1843

Author

Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi, and Deepak, V.

Subjects

Reptilia, Psammophilus, Squamata, Animalia, Biodiversity, Chordata, Agamidae, Taxonomy

Abstract

Psammophilus Fitzinger, 1843 Type species: Agama dorsalis (Gray, 1845) Content: Psammophilus dorsalis, Psammophilus blanfordanus (Stoliczka, 1871) Etymology: None provided but probably from Latin “Psammo” meaning sand and “Philus” meaning loving. Diagnosis. The genus Psammophilus can be distinguished from the genera Cophotis, Ceratophora, Lyriocephalus, Ptyctolaemus, Phoxophrys, Japalura otai Mahony 2009, J. planidorsata Jerdon, 1870, J. sagittifera Smith, 1940 and Otocryptis by the presence of an external tympanum (Boulenger, 1885; Smith, 1935; Inger, 1960; Pethiyagoda & Manamendra-Arachchi 1998; Schulte II et al. 2004; Bahir & Silva 2005; Manamendra-Arachchi et al. 2006; Samarawickrama et al. 2006); from other members of genus Japalura by the absence of heterogenous dorsal scales and short and thick nuchal scales. The genus Psammophilus can be diagnosed from all other species of draconinae lizards from the Indian subcontinent except Calotes minor, in having a dorso-ventrally compressed body. Psammophilus differs from Calotes minor in having small body scales and higher number of around the body scales 80–150 (vs 48–60). Psammophilus are characterized by a medium to large adult body size (SVL mm to mm); body dorso-ventrally compressed; presence of an antehumeral fold; supratympanic spines present, reduced in size; dorsal and lateral scales rows slightly irregular; nuchal and dorsal crest small, reduced; dorsal and lateral scales small, keeled, scale rows directed postero-dorsally. Psammophilus can be distinguished from its sister genus Monilesaurus gen. nov. and Calotes in having a dorso-ventrally compressed body (vs dorso-laterally compressed) and higher number of scales on the mid-body scales (more than 80 vs less than 65) and reduced nuchal crest (vs. well developed); and from Microauris gen. nov. by having a relatively large tympanum (Fig. 9d vs 9b). Scales on head large uniform shield like (vs small, sub-triangular) (Fig. 10c vs 10d). Supratympanic spines are present, in the form of two separated spines vs clusters in Calotes. Psammophilus are sexually dimorphic, adult males are larger than females and have enlarged cheeks. Psammophilus are also sexually dichromatic; during breeding season males acquire bright yellow and orange colors on the dorsum while females remain dull to dark brown with or without orange/ yellow spots. Taxonomic comments. The two species Psammophilus dorsalis and Psammophilus blanfordanus were earlier placed in the genus Agama (Daudin, 1802) and the now obsolete genus Charasia (Gray, 1845). Smith (1935) transferred the two species Charasia dorsalis and Charasia blanfordanus to the genus Psammophilus. Most likely due to their dorso-ventrally compressed body, Psammophilus was placed among the Agaminae but molecular data suggest that they are nested well within the subfamily Draconinae. Both P. dorsalis and P. blanfordanus have been recorded in the Western Ghats (Smith, 1935). Stoliczka (1871) provided a brief description of P. blanfordanus without mentioning a type locality and later provided a detailed description (Stoliczka, 1872) based on a large number of samples collected from central India (Udaypore west of Chotanagpur, West of Raipore, West of Ranchi) which are currently recognized as syntypes in ZSI with additional syntypes in NMW and ZMB (Das et al. 1998). Stoliczka (1872) also mentions that P. blanfordanus is not uncommon in Parisnath (Parasnath) hill. Psammophilus dorsalis was described by Gray (1831). The key character to diagnose this species is number of scales around the body, which overlap with each other (Boulenger, 1885; Smith, 1935). Boulenger (1885) used a combination of specimens from Southern India (Nilgiris, Malabar, Madras and a few specimens with locality “ India ”) to describe P. dorsalis. To describe P. blanfordanus, Boulenger (1885) used specimens from Godavari valley and “Jeypore” (Northern Andhra) and Ranchi (now in Jharkhand state). One single specimen collected from Parasnath, Jharkhand that is relatively close to the type locality (Central India) of P. blanfordanus had 1–3% genetic divergence in the 16S gene from P. dorsalis samples used in this study. We were unable to find P. blanfordanus from the Western Ghats during our fieldwork. Given the amount of morphological variation among the observed individuals and wide distribution of this group, we would suggest a thorough evaluation of this species group from the entire peninsula with detailed sampling. In the present work, we only describe P. dorsalis as we were unable to confirm the presence of P. blanfordanus in the Western Ghats. Members. Psammophilus dorsalis and Psammophilus blanfordanus., Published as part of Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi & Deepak, V., 2018, A systematic revision of Calotes Cuvier, 1817 (Squamata: Agamidae) from the Western Ghats adds two genera and reveals two new species, pp. 401-450 in Zootaxa 4482 (3) on pages 437-438, DOI: 10.11646/zootaxa.4482.3.1, http://zenodo.org/record/1440674, {"references":["Gray, E. (1845) Catalogue of the specimens of lizards in the collection British museum. Trustees of die British Museum / Edward Newman, London, 289 pp.","Stoliczka, F. (1871) Notes on new or little known Indian lizards. Proceedings of the Asiatic Society of Bengal, 9, 192 - 195.","Boulenger, G. A. (1885) Catalogue of lizards in the British museum. Fol. 1. Geckonidae, Eublepharidae, Uroplatidae, Pygopodidae, Agamidae, Second edition. British Museum (Natural History), London, 436 pp.","Smith, M. A. (1935) The Fauna of British India, Including Ceylon and Burma; Reptilia and Amphibia. Fol. II. Sauria. Taylor and Francis, London, 440 pp.","Inger, R. F. (1960) A review of the agamid lizards of the genus Phoxophrys Hubrecht. Copeia, 3, 221 - 225. https: // doi. org / 10.2307 / 1439661","Pethiyagoda, R. & Manamendra-Arachchi, K. (1998) A revision of the endemic Sri Lankan agamid lizard genus Ceratophora Gray, 1835, with description of two new species. Journal of South Asian natural History, 3 (1), 1 - 50.","Schulte II, J. A., Vindum, J. V., Win, H., Thin, T., Lwin, K. S. & Shein, A. K. (2004) Phylogenetic relationships of the genus Ptyctolaemus (Squamata: Agamidae), with a description of a new species from Chin Hills of Western Myanmar. Proceedings of the California Academy of Sciences, 55, 222 - 247.","Bahir, M. M. & Silva, A. (2005) Otocryptis nigristigma, a new species of agamid lizard from Sri Lanka. In: Yeo, C. J., Ng, P. K. L. & Pethiyagoda, R. (Eds.), Contributions to biodiversity exploration and research in Sri Lanka. The Raffles Bulletin of Zoology, 12 (Supplement), 393 - 406.","Manamendra-Arachchi, K., de Silva, A. & Amarasinghe, T. (2006) Description of a second species of Cophotis (Reptilia: Agamidae) from the highlands of Sri Lanka. Lyriocephalus, 6, 1 - 8.","Samarawickrama, V. A. M. P. K., Ranawana, K. B., Rajapaksha, D. R. N. S., Ananjeva, N. B., Orlov, N. L., Ranasinghe, J. M. A. S. & Samarawickrama, V. A. P. (2006) A new species of the genus Cophotis (Squamata: Agamidae) from Sri Lanka. Russian Journal of Herpetology, 13, 207 - 214.","Stoliczka, F. (1872) Notes on various new or little known Indian lizards. Proceedings of the Asiatic Society of Bengal, 41, 86 - 135."]}

Published

2018

120. Monilesaurus ellioti Pal & Vijayakumar & Shanker & Jayarajan & Deepak 2018, comb. nov

Author

Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi, and Deepak, V.

Subjects

Reptilia, Monilesaurus, Squamata, Animalia, Biodiversity, Chordata, Agamidae, Taxonomy, Monilesaurus ellioti

Abstract

Monilesaurus ellioti (Günther, 1864) comb. nov. Calotes rouxii— (not of Dum. & Bibr., 1837), Jerdon, 1853. J. Asiat. Soc. Beng. (2) xxii, 1853: 471 Calotes ellioti — Günther, 1864. Rept. Brit. Ind. 1864: 142. Bronchocela indica —Theobald, 1876. Cat. Rept. Brit. Ind. 1876: 105. Calotes elliotti — Smith, 1935. Fauna of British India, ii, 1935: 207. Original description. Günther, A. 1864. The Reptiles of British India. London (Taylor & Francis), xxvii, 452 pp. Taxonomic comments. Monilesaurus ellioti was described, based on Jerdon’s observation of C. rouxii like animals from “Malabar” in his list of Reptiles of Southern India, 1853 and a collection of drawings of this species in the possession of W. Elliot. Historically, southern Karnataka and northern Kerala have been referred to as Malabar. Boulenger (1885) gave a short description of this species based on the collections made by Col. R.H. Beddome from Anamalai hills, Sivagiri Ghat, Tirunelveli and Malabar. As there are no type specimens associated with this species, we hereby designate a neotype for this species. The selection of the neotype is roughly congruent with the original type locality of this species “Malabar” as mentioned by Jerdon (1853). Murthy (1978) described a subspecies Calotes ellioti amarambalamensis the type locality of which is Amarambalam, Nilambur. The holotype of this species is now at ZSI Madras (ZSI Madras 159) (Das et al. 1998). We were unable to trace the specimen in ZSI collections despite repeated attempts. For now, the specimen may be considered as lost. Hence, we compare another specimen collected from the same locality (BNHS 1033), a female individual whose characters match well with other M. ellioti and the description provided by Murthy. Also, the locality is within the distribution range of M. ellioti and contiguous with the type locality. Therefore, we consider Calotes ellioti amarambalamensis as a junior synonym of M. ellioti (Günther, 1864). ZSI Madras 159 is wrongly mentioned as a type specimen of Calotes ellioti (Uetz & Hošek, 2016). Neotype. CESL 0 45, adult male collected from Chembra reserve forest, Kerala by SPP, MVP and SPV on 10th June 2010. Other material examined. ZSI 4325 gravid female & ZSI 4328 male collected from Southern India; CESL 0 42 adult male collected from Manikunjamalai, Wayanad reserve forest, Kerala; CESL 0 45 adult male collected from Chembra reserve forest, Kerala; CESL 0 47 adult female collected from Vaithiri, Wayanad reserve forest, Kerala; CESL 0 57, CESL 0 59 and CESL 0 61 adult females and CESL 0 58 and CESL 0 60 adult males collected from Vallerimala, Wayanad reserve forest, Kerala; CESL 0 77, adult female collected from Arlam Wildlife Sanctuary, Kerala; CESL 0 33 adult male collected from Bonacord, Peppara Wildlife Sanctuary, Kerala; CESL 162, adult male collected from Sholyar, Vazhachal reserve forest, Kerala; CESL 204, adult female collected from Pamba, Periyar tiger reserve, Kerala and CESL 369 adult male collected from Peppara, Cardemom hills, Kerala and BNHS 1033, adult female collected from Nilambur reserve forest, Kerala. Details of collection locality, specimen voucher and GenBank accession number in Appendix 1. Diagnosis and comparison. A small sized Monilesaurus (SVL up to 73.8 mm) characterized by the posteroventral orientation of lateral scales; antehumeral fold well developed, extending across the throat; 52–58 midbody scale rows; nuchal crest composed of 3–4 long, well developed spines; two separated supratympanic spines; a long, distinct isolated postorbital spine; dorsal and lateral scales keeled, ventral scales strongly keeled; paired postmentals, first pair separated by a single scale; 24–28 subdigital lamellae under fourth finger, 26–34 subdigital lamellae under fourth toe; 9–10 supralabials and 8–9 infralabials; olive brown above with angular darker cross bars on dorsum, a white spot below the eye. Morphologically M. ellioti is superficially similar to M. montanus gen. et sp. nov., M. rouxii comb. nov.; and M. acanthocephalus gen. et sp. nov., but can be distinguished by a combination of the following characters: 52–58 midbody scale rows (vs. 46–52 in M. montanus gen. et sp. nov., 62–64 in M. acanthocephalus gen. et sp. nov., and 52–56 in M. rouxii) presence of a long, distinct isolated spine in the posterior corner of orbit (vs. absent in M. rouxii; very small, indistinct tubercle like in M. montanus gen. et sp. nov., and much longer in M. acanthocephalus gen. et sp. nov.); 3–4 long nuchal spines (vs. 3–6 small nuchal spines in M. montanus gen. et sp. nov., 6 much longer nuchal spines in M. acanthocephalus gen. et sp. nov., 7–8 smaller nuchal spines in C. rouxii); longer, prominent isolated spine on the back of head and above tympanum (vs. much smaller in M. montanus gen. et sp. nov., and M. rouxii) and presence of a white spot below the eye (vs. absent in M. rouxii; in the form of a band in M. montanus gen. et sp. nov.) and smaller body size: adult SVL 59.4–73.8 mm, n=9 (vs. C. montanus gen. et sp. nov., adult SVL 61–83.4 mm, n=8; and M. acanthocephalus gen. et sp. nov. adult SVL 68.9–72.6 mm, n=3). Description. Based on CESL 0 45. A medium sized adult male (SVL- 63.7 mm), Morphometric and meristic data are summarised in Appendix 2 & 3. General habitus moderately compressed. Head moderately large (HL/SVL ratio 0.29), elongate (HW/HL ratio 0.63), maximum height less than maximum width; snout pointed; rostral broader than high; nostrils in single nasal shield, which is separated from rostral by a single scale; mental shield narrower than rostral; two postmentals, first pair in contact with each other; genials keeled; gular scales strongly keeled, slightly smaller than genials; scales on top of snout smooth except median row, which is keeled; scales on top of head heterogenous in size and shape, keeled; supraorbital scales keeled; canthus-rostralis and supraciliary edge sharp; a spine at the posterior corner of the orbit; two separated long spines on posterior end of head, the anterior slightly longer, midway between nuchal crest and tympanum, posterior above tympanum; orbit diameter 70% of distance between anterior border of orbit and snout tip; tympanum exposed, its greatest diameter 54% horizontal diameter of orbit; enlarged keeled scale between tympanum and orbit; posterior region of jaws swollen; supralabials 10/10; infralabials 9/9. Nuchal crest well developed, composed of four primary, long conical spines, the first being the smallest and the third longest; the remaining vertebral scales slightly enlarged relative to adjacent rows and possess a more pronounced median keel forming a serrated ridge like the dorsal crest which continues till the tail base; 54 longitudinal scale rows around midbody; scales on dorsum keeled, oriented postero-dorsally, while lateral ones oriented postero-ventrally; lateral scales smaller than dorsal, keeled; ventrals strongly keeled, irregular, slightly smaller than dorsals but of similar size as laterals, genials and gular scales; a strong, oblique antehumeral fold, nearly extending across the throat. Limbs slender and covered with strongly keeled scales, larger than laterals, forming parallel longitudinal rows; scales under thighs weakly keeled; length of hindlimb ca. 87% SVL; relative length of fingers 4>3>2>5>1; relative lengths of toes 4>3>5>2>1; fourth toe longer than fifth finger; 23 subdigital lamellae under fourth finger; 27 subdigital lamellae under fourth toe; subdigital lamellae with sharp keels, bicarinate; tail slender, swollen at the base; scales on dorsal and ventral surface of tail with sharp keels, larger than laterals; tail length 172 mm. Colouration. In life: dorsum and head blackish-brown with irregular lighter patches on the back; a light brown band from above the shoulder till the dorsal crest forming a ‘v’ shape; head laterally dark blackish with a white spot below the posterior end of eye; stripe from above nostril to anterior margin of orbit extending till the tympanum from the posterior margin of orbit in the form of a black band; tympanum pale grey, lip scales white; a blackish triangular patch behind the tympanum continuing to the antehumeral fold; ventral uniformly lighter, pale grey; gular pouch with a reddish stripe extending beyond the throat; tail with alternating dark and light blotches forming irregular bands towards the end. Representative image showing live colouration (Fig. 6b). In preservative: colouration pattern mostly similar to that in life, except overall paler; bands on the head dull greyish brown. Variation and secondary sexual characteristics. The other specimens examined agree with the CESL 0 45 in general morphology and scalation except for some differences that are summarised in Appendix 2 & 3. All the examined female specimens (CESL 0 47, CESL 0 58 and CESL 061) have much smaller nuchal spines compared to the males, reduced postero-orbital spine; lack a dorsal crest and gular sac; overall colouration olive-brown, lighter head and vertebral region, a dark band along the side of the head to the neck and presence of a black antehumeral fold. Genetic distance. M. ellioti comb. nov. shows 1–2% intraspecific genetic divergence in the 16S gene; 4–7% interspecific genetic divergence from M. rouxii comb. nov.; 5–7% interspecific genetic divergence from M. acanthocephalus gen. et sp. nov and 4–8% interspecific genetic divergence from M. montanus gen. et sp. nov. (Appendix 5). Distribution. Monilesaurus ellioti comb. nov. is endemic to the Western Ghats and is distributed across the low and medium elevation forests (up to 1000 m asl) of southern parts of central Western Ghats (Coorg plateau and south) and the southern Western Ghats. This is one of the most common evergreen forest dwelling agamid lizards in this region. During this study, M. ellioti comb.nov. was recorded in various sites in the central and southern Western Ghats (See Fig. 3 & Appendix 1 for details). Ecology and natural history. Monilesaurus ellioti is a diurnal lizard, semi-arboreal to arboreal in habit, and so far, has been recorded mostly in semi-evergreen and evergreen forests. Individuals were mostly seen perching on shrubs, branches and actively moving on tree trunks. In some instances, it has also been observed in coffee plantations surrounded by evergreen forests. In some sites like Parambikulam, Vazhachal reserve forest and Brahmagiri hills, it was observed to occur syntopically in the same habitat as M. rouxii comb. nov., but more abundant within dense forests, while M. rouxii comb. nov. is generally restricted to forest edges. In some instances, gravid females were recorded during pre-and mid monsoon (June–August), which hints that monsoon might be a breeding season for this species.

Published

2018

121. Monilesaurus rouxii Pal & Vijayakumar & Shanker & Jayarajan & Deepak 2018, comb.nov

Author

Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi, and Deepak, V.

Subjects

Monilesaurus rouxii, Reptilia, Monilesaurus, Squamata, Animalia, Biodiversity, Chordata, Agamidae, Taxonomy

Abstract

Monilesaurus rouxii (Dum��ril & Bibron, 1837) comb.nov. Calotes rouxii ���Dum��ril & Bibron, 1837. Erp. Gen, iv, 1837: 407. Calotes ellioti ���(not of G��nther) Stoliczka, 1872. J. Asiat. Soc. Beng. (2) xli, 1872: 113. Calotes rouxii ��� Smith, 1935. Fauna of British India, ii, 1935: 206. Syntypes. MNHN���MNHN-RA-0.6894 & MNHN-RA-1994.1857 collected from ��� Indes Orientales ��� and deposited in the National Museum of Natural History (France). Original description. Dum��ril, A. M. C. and G. Bibron. 1837. Erp��tologie G��n��rale ou Histoire Naturelle Complete des Reptiles. Vol. 4. Libr. Encyclop��dique Roret, Paris, 570 pp. Taxonomic comments. The exact type locality of M. rouxii comb.nov. is unknown, as the localities for the syntypes in MNHN and in the original publication are given as ���Indes Orientales��� or India. The only precise locality of a specimen in the catalogue of British Museum is given as ���Matheran, Bombay Presidency��� (Boulenger 1885, 1890); Smith (1935) gives the range of M. rouxii comb. nov. as ���Bombay Presidency (Matheran, Khandala, Kanara, Jog); Travancore���. Of these, other than ���Travencore��� all the other localities are from the northern and central Western Ghats. Material examined. CESL 129, adult male collected from Matheran, Maharashtra; CESL 523, adult male collected from Brahmagiri Wildlife Sanctuary, Karnataka; CESL 554, adult male collected from Pushpagiri Wildlife Sanctuary, Karnataka; CESL 669, adult female collected from Bondla Wildlife Sanctuary, Goa; CESL 834, adult female collected from Narsimparvata, Kudremukh National Park, Karnataka, CESL 678, adult male collected from Madhei wildlife sanctuary, Goa; CESL 875, juvenile collected from Radhanagri, Maharashtra; CESL 0 95, juvenile, collected from Agumbe, Karnataka; 0 72, adult male collected from Wayanad wildlife sanctuary, Kerala; CESL 123 and CESL 153 adult males collected from Vazhachal, Kerala; CESL 215, adult male collected from near Parambikulam wildlife sanctuary, Kerala and CESL 581, adult male collected from near Pooyamkutty, Kerala. MNHN-RA-0.6894 (photographs only). Details of collection locality, specimen voucher and GenBank accession number in Appendix 1. Diagnosis and comparisons. A small sized Monilesaurus (SVL up to 74.8 mm) characterized by the posteroventral orientation of lateral scales; antehumeral fold small, triangular spines; two separated small supratympanic spines; dorsal and lateral scales keeled, ventral scales strongly keeled; paired postmentals, first pair in contact or separated by a single scale; 18���21 subdigital lamellae under fourth finger, 24���29 subdigital lamellae under fourth toe; 9���10 supralabials and 8���9 infralabials; olive-brown to above, antehumeral fold black, top of head often darker than dorsum, body often speckled with dark and light blotches, prominent in juveniles and sub-adults. Morphologically, M. rouxii comb.nov. is superficially similar to M. montanus gen. et sp. nov., M. ellioti comb. nov.; and M. acanthocephalus gen. et sp. nov., but can be distinguished by a combination of the following characters: 52���56 midbody scale rows (vs. 46���52 in M. montanus gen. et sp. nov., 62���64 in M. acanthocephalus gen. et sp. nov., and 52���58 in M. ellioti comb. nov.) spine in the posterior corner of orbit absent (vs. very small, indistinct tubercle like in M. montanus gen. et sp. nov., long, distinct in M. ellioti comb.nov. and much longer in M. acanthocephalus gen. et sp. nov.); 7���8 small nuchal spines (vs. 3���6 small nuchal spines in M. montanus gen. et sp. nov., 6 much longer nuchal spines in C. acanthocephalus gen. et sp. nov., 3���4 long nuchal spines in M. ellioti comb.nov.); small isolated spines on the back of head and above tympanum (vs. longer, prominent spines in M. ellioti comb. nov. and M. acanthocephalus gen. et sp. nov.) white spot below the eye absent (vs. present in M. ellioti comb.nov. and M. acanthocephalus gen. et sp. nov.; in the form of a band in M. montanus gen. et sp. nov.) and smaller body size: adult SVL 51.4���74.8 mm, n=9 (vs. C. montanus gen. et sp. nov., adult SVL 61���83.4 mm, n=8; and M. acanthocephalus gen. et sp. nov. adult SVL 68.9���72.6 mm, n=3). Description. Based on CESL 129. A medium sized adult male (SVL- 74.79 mm). Morphometric and meristic data are summarised in Appendix 2 & 3. General habitus moderately compressed. Head moderately large (HL/SVL ratio 0.29), elongate (HW/HL ratio 0.73), maximum height less than maximum width; snout pointed; rostral broader than high; nostrils in single nasal shield, which is separated from rostral by a single scale; mental shield narrower than rostral; two postmentals; first pair in contact with each other; genials keeled; gular scales strongly keeled, slightly smaller than genials; scales on top of snout smooth except median row, which is keeled; scales on top of head heterogenous in size and shape, keeled; supraorbital scales keeled; canthus-rostralis and supraciliary edge sharp; two separated spines on posterior end of head, the anterior slightly longer, midway between nuchal crest and tympanum, posterior above tympanum; orbit diameter 75% of distance between anterior border of orbit and snout tip; tympanum exposed, its greatest diameter 58% horizontal diameter of orbit; enlarged keeled scale between tympanum and orbit; posterior region of jaws swollen; supralabials 10/10; infralabials 9/9. Nuchal crest well developed, composed of eight primary, broadly conical spines, the first and last smaller than the rest; the remaining vertebral scales slightly enlarged relative to adjacent rows and possessing a more pronounced median keel forming a serrated ridge like the dorsal crest which continues till the tail base; 56 longitudinal scale rows around midbody; scales on dorsum keeled, oriented postero-dorsally, while lateral ones oriented postero-ventrally; lateral scales smaller than dorsal, keeled; ventrals strongly keeled, irregular, slightly smaller than dorsals but of similar size as laterals, genials and gular scales; a strong, oblique antehumeral fold, nearly extending across the throat. Limbs slender and covered with strongly keeled scales, larger than laterals, forming parallel longitudinal rows; scales under thighs weakly keeled; length of hindlimb ca. 82% SVL; relative length of fingers 4>3>2>5>1; relative lengths of toes 4>3>5>2>1; fourth toe longer than fifth finger; 20 subdigital lamellae under fourth finger; 24 subdigital lamellae under fourth toe; subdigital lamellae with sharp keels, bicarinate; tail slender, swollen at the base; scales on dorsal and ventral surface of tail with sharp keels, mucronate, slightly larger than laterals; tail length 118 mm (tail incomplete, broken at the tip). Colouration. In life: dorsum uniform blackish-brown; head bright reddish-orange, from snout tip to slightly behind mid vertebral; laterally a blackish-brown stripe from above nostril to anterior margin of orbit extending till the tympanum from the posterior margin of orbit in the form of black band; a bright reddish-orange stripe from snout covering labials till the anterior margin of tympanum, continuing backwards from posterior margin and ending abruptly in the antehumeral fold; tympanum pale grey; ventral uniformly black; gular pouch with a small orange stripe in the median row. Representative image showing live colouration (Fig. 6a). In preservative: colouration pattern mostly similar to that in life, except overall paler; bands on the head dull greyish brown. Variation and secondary sexual characteristics. The other specimens examined agree with CESL 129 in general morphology and scalation except for some differences that are summarised in Appendix 2 & 3. Both the examined female specimens (CESL 669 and CESL 834) have much smaller nuchal spines and lack a dorsal crest and gular sac; overall colouration olive-brown, lighter head and vertebral region, a dark band along the side of the head to the neck and the presence of a black antehumeral fold. Genetic distance. M. rouxii comb. nov. shows 1% intraspecific genetic divergence in the 16S gene; 4���7% interspecific genetic divergence from M. ellioti comb. nov.; 6% genetic divergence from M. acanthocephalus gen. et sp. nov. and 7���8% interspecific genetic divergence from M. montanus gen. et sp. nov. (Appendix. 5). Distribution. Monilesaurus rouxii comb. nov. is distributed across the low and medium elevation forests (up to 1000 m asl) of the Western Ghats and has also been reported from parts of the southern Eastern Ghats (Daniels & Ishwar 1994). This is one of the most common forest dwelling agamid lizards in the northern and central Western Ghats. During this study, M. rouxii comb. nov. was recorded in various sites across the Western Ghats (See Fig. 3 & Appendix 1 for details). Ecology and natural history. Monilesaurus rouxii is a diurnal lizard, semi-arboreal to arboreal in habit, and has so far been recorded mostly in deciduous, secondary and semi-evergreen forests. Individuals were mostly seen perching on branches and actively moving on tree trunks. In some instances, it has also been observed in forest fragments and plantations. In some sites, they occur syntopically in the same habitat as C. versicolor, but tend to prefer higher and thicker perches than C. versicolor, and were found to be more abundant than C. versicolor inside forests. In many instances, gravid females were recorded during pre and mid monsoon (June���August), which suggests that monsoon might be a breeding season for this species., Published as part of Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi & Deepak, V., 2018, A systematic revision of Calotes Cuvier, 1817 (Squamata: Agamidae) from the Western Ghats adds two genera and reveals two new species, pp. 401-450 in Zootaxa 4482 (3) on pages 427-429, DOI: 10.11646/zootaxa.4482.3.1, http://zenodo.org/record/1440674, {"references":["Dumril, A. M. C. & Bibron, G. (1837) Erpetologie Generale ou Histoire Naturelle Complete des Reptiles. Fol. 4. Librairie Encyclopedique Roret, Paris, 570 pp.","Gunther, A. (1872) Descriptions of some Ceylonese Reptiles and Batrachians. Annals Magazine of natural History, 4, 85 - 88. https: // doi. org / 10.1080 / 002229372011951778","Smith, M. A. (1935) The Fauna of British India, Including Ceylon and Burma; Reptilia and Amphibia. Fol. II. Sauria. Taylor and Francis, London, 440 pp.","Boulenger, G. A. (1885) Catalogue of lizards in the British museum. Fol. 1. Geckonidae, Eublepharidae, Uroplatidae, Pygopodidae, Agamidae, Second edition. British Museum (Natural History), London, 436 pp.","Boulenger, G. A. (1890) The Fauna of British India, including Ceylon and Burma: Reptilia and Batrachia. Taylor and Francis, London, 541 pp.","Daniels, R. J. R. & Ishwar, N. M. (1994) Rarity and the herpetofauna of the Southern Eastern Ghats, India. Cobra, 16, 2 - 14."]}

Published

2018

122. Calotes versicolor

Author

Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi, and Deepak, V.

Subjects

Reptilia, Calotes versicolor, Squamata, Calotes, Animalia, Biodiversity, Chordata, Agamidae, Taxonomy

Abstract

Calotes versicolor (Daudin, 1802) Original description. Daudin, 1802. Hist. Nat., Rept. iii, 1802: 395, xliv. Taxonomic comments. Calotes versicolor was described in 1802 by Daudin, based on specimens at MNHN. There is no mention of a precise locality or even a type specimen. Later Smith (Smith 1935) and other workers designated the type-locality to populations from Pondicherry on the east coast of India, Chennai (Madras), and Kolkata (Calcutta) (Zug et al. 2006). The specimen MNHN 2548, collected from Pondicherry by Leschenault, cannot be a syntype of C. versicolor Daudin 1802, because Leschenault visited Pondicherry only after 1816 (Amarasinghe et al. 2009). Amarasinghe et al (2009) clarified that MNHN 2548 collected from Pondicherry by Leschenault is the syntype of Agama tiedemanni Kuhl, 1820. Gowande et al (2016) synonymized Calotes tiedemanni and designated a neotype from Pondicherry without any comparison with the syntype of Calotes tiedemanni. This neotype designation was recently invalidated (Chaitanya et al. 2017). Currently, Calotes versicolor is the most widely distributed species of the genus Calotes. Many researchers have mentioned the high level of morphological variation in this species across different populations and some have even considered it to be a species complex (Zug et al. 2006). Recently two new species were described from dry zone populations of C. versicolor from Myanmar based on DNA sequence and morphological analysis (Zug et al. 2006). In our phylogenetic analyses, the southern Western Ghats population forms a distant cluster within the C. versicolor clade (Fig. 1). The studied specimens also show 0–5% genetic divergence across their distribution. This shows that the Indian population might also be a species complex (see Gowande, 2016). A phylogeographic study with thorough sampling across its range and a rigorous comparison of the available type materials for the existing species and subspecies is necessary to resolve the complexity in this species. Since we did not study any historical type materials of Calotes versicolor or the synonyms, we consider the populations in this study as Calotes cf. versicolor. The diagnosis is based on specimens collected from the Southern Western Ghats only and used to separate Calotes cf. versicolor from other distinct species. Diagnosis and comparison. A medium to large sized Calotes (SVL up to 99.4 mm) characterized by the posterodorsal orientation of lateral scales; antehumeral fold absent; 38-44 midbody scale rows; nuchal and dorsal crest well developed, continuous, extending till the start of tail in males; two well separated supratympanic spines; dorsal and lateral scales large, more or less distinctly keeled, ventral scales strongly keeled, mucronate; paired postmentals, first pair separated by 1–2 median scales; 15–22 subdigital lamellae under fourth finger, 21–25 subdigital lamellae under fourth toe; 10–12 supralabials and 9–11 infralabials; uniform, light brown or greyish above, juveniles and females with darker cross bars or blotches on lateral side, often with paired lighter dorsolateral stripes, gular pouch brick red and overall body reddish in breeding males. From other members of Smith’s C. versicolor group (C. nemoricola, C. grandisquamis, C. calotes, C. minor, C. maria, C. jerdoni, C. emma and C. mystaceus) C. cf. versicolor can be distinguished by a combination of the following characters: smaller body size: adult SVL 73.8–99.4 mm, n=9 (vs. C. nemoricola, adult SVL 112–134.8 mm, n=7, n=5; and C. grandisquamis, adult SVL 110.0– 136.5 mm, n=5); 38–44 midbody scale rows (vs. 27–35 in C. grandisquamis; 30–35 in C. calotes, n=3; 36–43 in C. nemoricola; 58–63 in C. maria; 45–57 in C. jerdoni; 49– 65 in C. emma; 48–58 in C. mystaceus and 48–60 in C. minor); crescent-shaped patch of granular scales in front of the shoulder absent (vs. present in C. nemoricola, C. grandisquamis, C. emma, C. mystaceus and C. jerdoni); nuchal and dorsal crest well developed, composed of almost equal spines (vs. nuchal spines much longer, dorsal crest reduced in C. nemoricola and C. maria; nuchal spines much longer than dorsal spines in C. grandisquamis, C. calotes and C. emma); two well separated supratympanic spines (vs. row of 3–4 compressed supratympanic spines in C. nemoricola and C. grandisquamis; 8–9 compressed spines in C. calotes; two parallel rows of compressed supratympanic scales in C. maria and C. jerdoni; single well developed postorbital spine in C. emma). Calotes cf. versicolor can be distinguished from its other Sri Lankan congeners based on posterodorsal orientation of lateral scales and absence of oblique fold or pit in front of the shoulder. Description. Based on specimen CESL 182. A large sized adult male (SVL 99.4 mm), morphometric and meristic data are summarised in Appendix 2 & 3. General habitus moderately compressed. Head moderate (HL/ SVL ratio 0.22), slightly elongate (HW/HL ratio 0.95), maximum height slightly less than maximum width; snout pointed; rostral broader than high; nostrils in single nasal shield which is separated from rostral by two scales; mental shield narrower than rostral; two postmentals, first pair separated from each other by two small scales; genials keeled; gular sac small, composed of strongly keeled scales, slightly smaller than genials; scales on top of snout smooth except median row, which is keeled; scales on top of head heterogenous in size and shape, keeled; supraorbital scales keeled; canthus-rostralis and supraciliary edge sharp; two separated spines on posterior end of head, the anterior much longer, closer to the nuchal crest, posterior above tympanum; orbit diameter 87% of distance between anterior border of orbit and snout tip; tympanum exposed, its greatest diameter 42% of horizontal diameter of orbit; slightly keeled, scales between tympanum and orbit smooth, slightly enlarged; posterior region of jaws swollen; supralabials 11/10; infralabials 10/10. Nuchal and dorsal crest well developed, continuous; nuchal crest composed of 11 long, conical spines, the first being the smallest; dorsal crest composed of 33 curved spines till above the vent, slightly smaller than the nuchal spines; 36 longitudinal scale rows around midbody; dorsal and lateral scales sub-triangular, keeled, oriented postero-dorsally; ventrals strongly keeled, mucronate, smaller than dorsal and lateral scales. Limbs slender and covered with strongly keeled scales, similar to laterals, forming parallel longitudinal rows; scales under thighs weakly keeled; length of hindlimb ca. 75 % SVL; relative length of fingers 4>3>2>5>1, third and fourth finger almost equal; relative lengths of toes 4>3>5>2>1; fourth toe much longer than fifth finger; 21 subdigital lamellae under fourth finger; 25 subdigital lamellae under fourth toe; subdigital lamellae with sharp keels, bicarinate; slender, swollen at the base; dorsal and ventral tail scales mucronate, strongly keeled; tail broken, incomplete; tail length 90 mm. Colouration. In life: dorsum and head uniform, greyish-brown with irregular darker patches towards the flank; each lateral scale with a darker blackish spot towards the base, followed by lighter grey edges; head laterally paler, whitish towards the cheeks; a small, thin darker stripe from posterior corner of the eye till end of orbit; legs with irregular dark crossbars; a black coloured patch above the shoulder, near throat; tympanum pale grey with many small black spots, ventral uniformly lighter, pale grey; tail with alternating dark and light bands. Representative image showing live colouration (Fig. 4b). In preservative: colouration mostly similar to that in life, except overall paler. Variation and secondary sexual characteristics. Meristic and morphometric data of four adult male and four adult female specimens are given in Appendix 2 & 3. The examined specimens agree with each other in general morphology and scalation. All the examined female specimens (CESL 0 48, CESL 163, CESL 306 and BNHM 374) have much smaller nuchal and dorsal spines compared to the males and lack a gular sac. Distribution. Calotes cf. versicolor is common in the Western Ghats at elevations between 70 m to 1250 m M.S.L. (See Appendix 1 for details). Ecology and natural history. Calotes cf. versicolor is a diurnal lizard, semi-arboreal to arboreal in habit, and so far, has been recorded mostly in scrub, deciduous forests and plantations. Individuals were mostly seen perching on shrubs, hedges, gardens and along compound walls of houses in villages along forests. C. cf. versicolor has often been found within plantations and prefers open patches to forested areas. During this study, it was never recorded from primary evergreen forests. In some sites, they might occur syntopically in the same habitat as M. rouxii comb. nov. but tend to be restricted to forest edges., Published as part of Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi & Deepak, V., 2018, A systematic revision of Calotes Cuvier, 1817 (Squamata: Agamidae) from the Western Ghats adds two genera and reveals two new species, pp. 401-450 in Zootaxa 4482 (3) on pages 421-423, DOI: 10.11646/zootaxa.4482.3.1, http://zenodo.org/record/1440674, {"references":["Smith, M. A. (1935) The Fauna of British India, Including Ceylon and Burma; Reptilia and Amphibia. Fol. II. Sauria. Taylor and Francis, London, 440 pp.","Zug, G. R., Brown, H. H., Schulte, J. A. & Vindum, J. V. (2006) Systematics of the Garden Lizards, Calotes versicolor Group (Reptilia, Squamata, Agamidae), in Myanmar: Central Dry Zone Populations. Proceedings of the California Academy of Sciences, 57 (2), 35 - 68.","Amarasinghe, A. A. T., Manthey, U., Stockli, E., Ineich, I., Kullander, S. O., Tiedemann, F., McCarthy, C. & Gabadage, D. E. (2009) The original descriptions and figures of Sri Lankan Agamid lizards (Squamata: Agamidae) of the 18 th and 19 th centuries. Taprobanica, 1 (1), 2 - 15. https: // doi. org / 10.4038 / tapro. v 1 i 1.2771","Chaitanya, R., Giri, V. B. & Deepak, V. (2017) On the recent designation of a neotype for the taxon Calotes versicolor (Daudin, 1802) (Reptilia: Agamidae). Zootaxa, 4317 (3), 585 - 587. https: // doi. org / 10.11646 / zootaxa. 4317.3.10"]}

Published

2018

123. Calotes nemoricola , Jerdon 1853

Author

Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi, and Deepak, V.

Subjects

Calotes nemoricola, Reptilia, Squamata, Calotes, Animalia, Biodiversity, Chordata, Agamidae, Taxonomy

Abstract

Calotes nemoricola Jerdon, 1853 Calotes nemoricola��� Jerdon, 1853. J. Asiat. Soc. Beng. xxii, 1853: 471. Original description. Jerdon, 1853. Journal of the Asiatic Society of Bengal, xxii, 1853: 471. Taxonomic comments. Calotes nemoricola was described based on specimens collected from ���Foot of ���Coonoor Ghat, Nilgherries��� (���Coonoor���, Nilgiri hills, Tamil Nadu, India). The type collected by Jerdon is a much mutilated male specimen (Smith 1935) and is housed in the collection of ZSIK (Das et al. 1998). Another male topotype is housed in the collection of BNHS (BNHS 373) (Smith 1935). Holotype: ZSI 6560. The specimen is in poor condition; the posterior part of the body along with the hindlimbs and tail is broken. Material examined. CESL 0 38 adult male collected from Bonaccord, Peppara Wildlife Sanctuary, Kerala; CESL 406 adult male collected from Kanyakumari Wildlife Sanctuary, Tamil Nadu; CESL 545 adult male collected from Makuta, Brahmagiri Wildlife Sanctuary, Karnataka; CESL 555 adult male collected from Bidahalli, Pushpagiri Wildlife Sanctuary, Karnataka; BNHS 1778 adult male collected from Kudremukh National Park, Karnataka; BNHS 373 adult male collected from ��� Coonoor ��� Ghat, Nilgiri hills, Tamil Nadu; BMNH 74.4.29.224 male, 74.4.29.225 female both collected from Malabar and ZSI 6560 male collected from the foothills of ��� Coonoor Ghat. Details of collection locality, specimen voucher and GenBank accession number in Appendix 1. Diagnosis and comparison. A large sized Calotes (SVL up to 134.8 mm) characterized by the posterodorsal orientation of lateral scales; antehumeral fold absent; 36���43 midbody scale rows; nuchal crest well developed composed of long spines, dorsal crest reduced, almost indistinct behind the midbody; row of 3���4 compressed supratympanic spines; postorbital spine absent; a crescent-shaped patch of granular scales in front of the shoulder present; dorsal and lateral scales large, mostly smooth, weakly keeled towards the flanks, ventral scales strongly keeled, mucronate; paired postmentals, first pair separated by 1���2 median scales; 21���23 subdigital lamellae under fourth finger, 25���31 subdigital lamellae under fourth toe; 10���12 supralabials and 10���11 infralabials; green to brownish above, uniform, often with a dark streak from eye to above tympanum, ventral white to pale grey. C. nemoricola can be distinguished from members of Smith���s C. versicolor group by a combination of the following characters: larger body size: mean adult SVL 125.8 mm, n=7 (vs. C. versicolor, adult SVL 73.8���99.4 mm, n=9 and C. calotes, adult SVL 73.6���96.8 mm, n=3); 36���43 midbody scale rows (30���35 in C. calotes, n=3, 38��� 44 in C. versicolor; 58���63 in C. maria; 45���57 in C. jerdoni; 49���65 in C. emma; 48���58 in C. mystaceus and 48���60 in C. minor); nuchal crest well developed with longer spines, dorsal crest reduced (vs. nuchal and dorsal crest well developed, composed of almost equal spines in C. versicolor and C. mystaceus); row of 3���4 compressed supratympanic spines (vs. two well separated supratympanic spines in C. versicolor, 8���9 compressed spines in C. calotes, two parallel rows of compressed supratympanic scales in C. maria and C. jerdoni; single well developed postorbital spine in C. emma); presence of a crescent-shaped patch of granular scales in front of the shoulder (vs. absent in C. versicolor, C. calotes and C. maria) and lateral scales much larger than ventrals (vs. almost equal to the ventrals in C. calotes). Morphologically, it is mostly similar to the closely related C. grandisquamis but can be distinguished based on higher number of midbody scale rows (36���43 vs. 27���35); smaller scales between eye and tympanum, much smaller than tympanum (vs. much larger scales, almost equal to the tympanum); scales on the cheek smaller, weakly keeled (vs. larger, smooth); gular scales keeled, smaller than mental (vs. gular scales smooth, equal to or slightly larger than the mental) and dorsal crest reduced, not extending beyond mid body (dorsal crest well developed, till above the base of tail). Even though these two large bodied species show the above-mentioned morphological differences, there has been some confusion in their correct identification in the recent past. To clarify this, a detailed comparison to distinguish these two species was provided by Ganesh & Chandramouli (2013). Description. Based on specimen CESL 555. A large sized adult male (SVL- 120.4 mm), morphometric and meristic data are summarised in Appendix 2 & 3. General habitus compressed. Head moderate (HL/SVL ratio 0.25), elongate (HW/HL ratio 0.75), maximum height slightly less than maximum width; snout pointed; rostral broader than high; nostrils in single nasal shield which is separated from rostral by two scales; mental shield narrower than rostral; two postmentals, first pair separated from each other by two small scales; genials keeled; gular sac small, composed of keeled scales, strongly keeled towards the medial row, slightly smaller than genials; scales on top of snout smooth except median row, which is keeled; scales on top of head heterogenous in shape and size, keeled towards the edges; supraorbital scales keeled; canthus-rostralis and supraciliary edge sharp; 4 supratympanic spines in a row, compressed; orbit diameter 69% of distance between anterior border of orbit and snout tip; tympanum exposed, its greatest diameter 46% of horizontal diameter of orbit; partially keeled, scales between tympanum and orbit smooth, not enlarged; posterior region of jaws distinctly swollen; supralabials 11/11; infralabials 11/11. Nuchal crest well developed, continuous with the much reduced dorsal crest; dorsal crest reaching slightly behind midbody; nuchal crest composed of 16 long, conical spines, the first being the smallest and fourth the longest; longest nuchal spine 65% of the orbit; dorsal spines less than half the nuchal spines in length; 41 longitudinal scale rows around midbody; dorsal and lateral scales sub-triangular, smooth, oriented posterodorsally; a crescent-shaped patch of small, granular scales present in front of the shoulder. Limbs moderate and covered with weakly keeled scales, stronger towards the end forming parallel longitudinal rows; scales under thighs weakly keeled; length of hindlimb ca. 71 % SVL; relative length of fingers 4>3>2>5>1, third and fourth finger almost equal; relative lengths of toes 4>3>5>2>1; fourth toe much longer than fifth finger; 21 subdigital lamellae under fourth finger; 27 subdigital lamellae under fourth toe; subdigital lamellae keeled, bicarinate; slender, swollen at the base; scales on dorsal and ventral surface of tail keeled, ventral tail scales mucronate; tail length 268 mm. Colouration. In life: dorsum and head uniform, light green above with slightly brownish lateral scales; a thick milky white band from behind the head till end of nuchal crest extending across the neck; head laterally brighter green, whitish below the cheeks; pupil black surrounded by a brick red iris; lip scales green; legs uniform darker shade of green; tympanum pale bluish green; ventral uniformly white; tail greenish at the start turning dull brownish towards the end. This individual changed colour at the slightest disturbance and turned dark brown overall with a dark olive head and a prominent white band behind the head. Representative image showing live colouration (Fig. 5b). In preservative: colouration mostly similar to that in life, except overall paler. Variation and secondary sexual characteristics. Meristic and morphometric data of the examined specimens are given in Appendix 2 & 3. The examined specimens agree with each other in general morphology and scalation. The only female specimen we examined (BMNH 74.4.29.255) had no cheek pouches or a swollen tail base. Distribution. Calotes nemoricola is endemic to the Western Ghats and is distributed in the low to mid elevation evergreen forests of the southern part of central Western Ghats (Agumbe and south) and the southern Western Ghats (Inger et al. 1984; Naniwadekar & Deepak 2008). During the present study, this species was recorded from various sites in the hills of central and southern Western Ghats (See Appendix 1 for details). Ecology and natural history. Calotes nemoricola is a diurnal lizard, mostly arboreal in habit, and so far, has been recorded mostly from primary evergreen forests. Individuals were mostly seen perched on high branches and actively moving on tree trunks inside forests. In a few instances, it was also found sleeping on lower branches at night. This species has mostly been recorded from low elevations (up to 600 m msl) in the southern Western Ghats but has sometimes been recorded from high elevation evergreen forests in the central Western Ghats (around 1000 m msl). It might overlap in distribution with the other large green agamid C. grandisquamis at its higher elevation range extremes given their preference of similar microhabitat. During this study, they were not recorded to be syntopic at any site., Published as part of Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi & Deepak, V., 2018, A systematic revision of Calotes Cuvier, 1817 (Squamata: Agamidae) from the Western Ghats adds two genera and reveals two new species, pp. 401-450 in Zootaxa 4482 (3) on pages 425-426, DOI: 10.11646/zootaxa.4482.3.1, http://zenodo.org/record/1440674, {"references":["Smith, M. A. (1935) The Fauna of British India, Including Ceylon and Burma; Reptilia and Amphibia. Fol. II. Sauria. Taylor and Francis, London, 440 pp.","Ganesh, S. R. & Chandramouli, S. R. (2013) Identification of two similar Indian Agamid lizards Calotes nemoricola Jerdon, 1853 and C. grandisquamis Gunther, 1875. Russian Journal of Herpetology, 20, 33 - 35.","Inger, R. F., Shaffer, H. B, Koshy, M. & Bakde, R. (1984) A report on a collection of amphibians and reptiles from the Ponmudi, Kerala, South India. Journal of Bombay Natural History Society, 81, 551 - 570.","Naniwadekar, R. & Deepak, V. (2008) New distribution record for Calotes nemoricola Jerdon, 1853 from the Kudremukh hills, Karnataka, India. Journal of Bombay Natural History Society, 105 (1), 99."]}

Published

2018

124. Monilesaurus acanthocephalus Pal & Vijayakumar & Shanker & Jayarajan & Deepak 2018

Author

Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi, and Deepak, V.

Subjects

Reptilia, Monilesaurus, Squamata, Animalia, Biodiversity, Chordata, Agamidae, Monilesaurus acanthocephalus, Taxonomy

Abstract

Monilesaurus acanthocephalus gen. et. sp. nov. (Fig. 7a) Etymology. The species epithet is derived by combining the Greek word ‘acanthos’, meaning spine or thorn, and ‘kephale’ latinized as ‘cephalus’ meaning head; referring to the long posterorbital and supratympanic spines. Holotype. BNHS 2409, an adult male (Fig. 11) collected from a disturbed habitat, adjoining evergreen forest—tea garden edge in Upper Manalar (Fig. 12), Periyar tiger reserve, Megamalai (934'35. 81"N, 7720'11. 43"E; 1562 m a.s.l) by SPV on 8th April 2009. Paratypes. CESL 0 0 1 adult male and CESL 112 juvenile male collected by SPV on 8th April 2009; BNHS 2410 adult male collected by SPP on 4th September 2011 from Upper Manalar, Periyar tiger reserve, Megamalai (9°34'18. 25"N, 77°20'5. 02"E, 1547 m). Diagnosis and comparison. A medium sized agamid (SVL = 72.6 mm) characterized by backward and downward orientation of lateral body scales; antehumeral fold present, throat fold present; 62–64 midbody scale rows; nuchal crest composed of 6 long, well developed spines; dorsal crest developed, in the form of a serrated ridge; two long, separated supratympanic spines; a long, well developed postorbital spine; dorsal and lateral scales keeled, ventral scales strongly keeled; paired postmentals, first pair separated by a 1 or 2 scales; 22–24 subdigital lamellae under fourth finger, 27–31 subdigital lamellae under fourth toe; 9 supralabials and 8 infralabials; reddish brown above with alternating dark and light crossbars on the dorsum, two white spots below the eye. Monilesaurus acanthocephalus gen. et sp. nov. can be can be distinguished from its congeners by a combination of the following characters: 62–64 midbody scale rows (vs. 46–52 in M. montanus gen. et sp. nov., 52–58 in M. ellioti and 52–56 in M. rouxii); presence of much longer, distinct isolated spine in the posterior corner of orbit (vs. absent in M. rouxii; very small, indistinct tubercle like in M. montanus gen. et sp. nov., and smaller in M. ellioti); 6 very long nuchal spines (vs. 3–6 small nuchal spines in M. montanus gen. et sp. nov., 3–4 long nuchal spines in M. ellioti, 7–8 smaller nuchal spines in C. rouxii); longer, prominent isolated spine on the back of head and above tympanum (vs. much smaller in M. montanus gen. et sp. nov., and M. rouxii) and presence of a white spot below the eye (vs. absent in M. rouxii; in the form of a band in M. montanus gen. et sp. nov.). Description of holotype. BNHS 2409, a medium sized adult male (SVL: 72.6 mm), morphometric and meristic data are summarised in Appendix 2 & 3. General habitus moderately compressed. Head moderately large (HL/SVL ratio: 0.29), broad (HW/HL ratio: 0.65), maximum height less than maximum width; snout pointed; rostral broader than high; nostrils in single nasal shield, which is separated from rostral by a single scale; mental shield narrower than rostral; two postmentals; first pair in contact with each other; genials keeled; gular scales strongly keeled, slightly smaller than genials; scales on top of snout smooth except median row, which is keeled; scales on top of head heterogenous in size and shape, keeled; supraorbital scales keeled; canthus-rostralis and supraciliary edge sharp; a long, well developed, thick spine at the posterior corner of the orbit, ca. 54% the orbit in length; two separated spines on posterior end of head, the anterior much longer, between the nuchal crest and tympanum, posterior above tympanum; orbit diameter 56% of distance between anterior border of orbit and snout tip; tympanum exposed, its greatest diameter 49% horizontal diameter of orbit; enlarged keeled scale between tympanum and orbit; posterior region of jaws swollen; supralabials 9/8; infralabials 8/8. Nuchal crest well developed, composed of six primary, long conical spines, the first being the smallest and the fourth longest; the remaining vertebral scales subtriangular, pointed, much larger than adjacent rows of scales, and possessing a strong, median keel forming an elevated, serrated ridge like the dorsal crest which continues till the tail base; 62 longitudinal scale rows around midbody; scales on dorsum keeled, oriented postero-dorsally, while lateral ones oriented postero-ventrally; lateral scales smaller than dorsal, keeled; ventrals strongly keeled, irregular, slightly smaller than dorsals but of similar size as laterals, genials and gular scales; a strong, oblique antehumeral fold, extending across the throat. Limbs long, slender and covered with strongly keeled scales, larger than laterals, forming parallel longitudinal rows; scales under thighs keeled; length of hindlimb ca. 79 % SVL; relative length of fingers 4>3>5>2>1; relative lengths of toes 4>3>5>2>1; fourth toe longer than fifth finger; 22 subdigital lamellae under fourth finger; 27 subdigital lamellae under fourth toe; subdigital lamellae with sharp keels, bicarinate; tail slender, swollen at the base; scales on dorsal and ventral surface of tail with sharply keeled, mucronate, larger than laterals; tail length 215 mm. Colouration. In life: dorsum olive red with a light brown head, irregular alternating red and black blotches on the mid dorsum, the black blotches extend to the lateral side in the form of alternate ‘v’ shaped bands; 4–5 light green blotches on the lateral side followed by thin whitish stripes from behind shoulder till start of tail; two light broken dorsolateral stripes present; head laterally light olive with three dark black bands from posterior part of eye till tympanum and two white spots below the eye; tympanum off-white with light green edge, lip scales light grey; a large blackish triangular patch behind the tympanum continuing to the antehumeral fold; ventral uniformly white; gular pouch light reddish; tail with alternating spaced dark blotches forming irregular bands towards the end. In preservative: dorsum and head uniform light brown, back banded with five ‘U’ shaped black bands from neck to start of tail; the black bands extend midway laterally forming an alternating pale brown and black pattern; tail banded with alternating thick brown and grey blotches; head laterally pale brown with yellowish white lip scales, tympanum pale grey; ventrally uniform pale whitish yellow with darker blotches below the limbs. Variation and secondary sexual characteristics. Morphometric and meristic data for the type specimens is presented in Appendix 2 & 3. The adult paratypes are all males and range from 68.9–72 mm in SVL. The paratypes agree with the holotype (CESL 002) in general morphology and scalation except for the following characters: 62– 64 longitudinal scale rows around midbody; 22–24 subdigital lamellae under fourth finger, 27–31 subdigital lamellae under fourth toe; infralabials 9 on the left in CESL 0 0 1 and 9 on the right in CESL 410; 1 st pair separated by a single scale in CESL 410. Dorsal and nuchal crest, spines above the orbit and tympanum not developed in the juvenile paratype CESL 112. Genetic distance. M. acanthocephalus gen. et sp. nov. shows 4–6% interspecific genetic divergence in the 16S gene from M. rouxii comb. nov.; 5–6 % interspecific genetic divergence from M. ellioti comb. nov. and 2–3 % interspecific genetic divergence from M. montanus gen. et sp. nov. (Appendix 5). Distribution. Monilesaurus acanthocephalus gen. et sp. nov. is currently known only from high elevations (above 1500 m asl) of Megamalai hills of southern Western Ghats (See Fig. 3 & Appendix 1 for details). Ecology and natural history. Monilesaurus acanthocephalus gen. et sp. nov. is a diurnal lizard, semiarboreal to arboreal in habit, and has, so far, been recorded from high elevation evergreen forests and along foresttea garden edges (Fig. 12). Individuals were seen perching on shrubs, branches and on tree trunks. One of the type specimens (CESL 410) was found sleeping on a tree branch in a forest patch.

Published

2018

125. Psammophilus dorsalis

Author

Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi, and Deepak, V.

Subjects

Reptilia, Psammophilus, Squamata, Animalia, Biodiversity, Chordata, Agamidae, Psammophilus dorsalis, Taxonomy

Abstract

Psammophilus dorsalis (Gray, 1831) (Fig. 8a) Agama dorsalis –Gray, 1831. In Griffith, E & E. Pidgeon’s Anim. King. ix, 1851: 56 Charasia dorsalis – Gray, 1845. Cat. Liz. Brit. Mus. 1845: 246. Charasia dorsalis — Boulenger, 1885. Cat. Liz. Brit. Mus. 1845: 450. Psammophilus dorsalis — Smith, 1935. Fauna of British India, ii, 1935: 209. Original description. Gray, J. E. 1831. A synopsis of the species of Class Reptilia. In: Griffith, E & E. Pidgeon: The animal kingdom arranged in conformity with its organisation by the Baron Cuvier with additional descriptions of all the species hither named, and of many before noticed [V Whittaker, Treacher and Co., London: 481 + 110 pp. [1830] Taxonomic comments. Gray (1831) failed to mention which specimens he used to describe P. dorsalis. Currently, there are 20 specimens labelled as P. dorsalis at the Natural History Museum. Boulenger (1885) used eight specimens at NHM to describe Charasia dorsalis collected from Madras, Nilgiris, Malabar and India and labelled these collections as being from Southern India. There was no precise type locality given in the original description but most of the localities mentioned in older publications suggest collections from different parts of southern India, especially hilly regions (Boulenger 1890; Smith 1935). The chronological collections of the specimens from NHM need to be verified to choose a lectotype from the specimens at NHM. Since there is very little genetic variation (1–2% in 16S mtDNA) in the samples collected from the Western Ghats of Peninsular India, we provide an expanded description of this species based on the largest male collected during this study and compare with other specimens collected during the study. Topotypic material. CESL 273, adult male collected from a boulder in grassland in Kotavasal, Achankovil reserve forest, Kerala by SPP and MVP on 28th May 2011. Other material examined. CESL 326 adult male collected from Kolakumbai, Nilgiri hills, Tamil Nadu; CESL 0 64 adult female collected from sunrise valley, Wayanad reserve forest, Kerala and CESL 181 adult female collected from near Rishi Valley school, Andhra Pradesh; details of collection locality, specimen voucher and GenBank accession number in Appendix 1. Diagnosis and comparison. A medium to large sized Psammophilus characterized by the posterodorsal orientation of lateral scales; antehumeral fold well developed; 94–148 midbody scale rows (vs 115–140 in Boulenger, 1885; 115–150 Smith, 1935); ventral scales 112–152; nuchal crest reduced, composed of 15–18 very small, triangular spines, continuous with almost equal to or even smaller dorsal crest which appears like slightly raised denticulation; dorsal crest absent in females and juveniles; two separated, very small supratympanic spines; dorsal and lateral scales keeled, ventral scales strongly keeled; paired postmentals, first pair separated by 1–2 scales; 24–28 subdigital lamellae under fourth finger, 26–34 subdigital lamellae under fourth toe; 11–13 supralabials and 10–12 infralabials; adult males with uniform greyish brown to black body, dorsum lighter; indistinct lighter blotches on the sides, lip scales lighter grey or off-white; females and juveniles with a pair of dorsolateral stripes from neck to above tail, dorsum and lateral speckled with lighter spots. Morphologically, P. dorsalis is similar to P. blanfordanus, the only other species known from this group, but can be distinguished by a combination of the following characters: 100–140 midbody scale rows (vs 80–100); three samples collected from eastern India close to the type locality of P. blanfordanus also had lower number 84–94 (80–100 Boulenger 1885 & Smith, 1935). Midbody scales row counts clearly overlap with P. dorsalis. Furthermore, all the meristic characters we checked for few specimens overlap (Appendix 3). There is, therefore a need for more thorough examination of morphological and morphometric characters with a larger sample size to diagnose P. dorsalis from P. blanfordanus. Description. Based on CESL 273, a large sized adult male (SVL- 107.7 mm), morphometric and meristic data are summarised in Appendix 2 & 3. General habitus moderately depressed. Head moderately large (HL/SVL 0.25), not elongated (HW/HL 1.10), maximum width much more than maximum height; snout rounded; rostral broader than high; nostrils in single nasal shield, which is separated from the rostral by two scales; mental shield broader than rostral; two postmentals, first pair separated by two small scales; genials smooth; gular scales keeled, smaller than genials; scales on top of snout feebly keeled towards the edges; scales on top of head heterogenous in size and shape, keeled; supraorbital scales keeled; canthus-rostralis and supraciliary edge sharp; two separated small, triangular spines on posterior end of head, the anterior midway between nuchal crest and tympanum, posterior above tympanum; orbit diameter 65% of distance between anterior border of orbit and snout tip; tympanum exposed, its greatest diameter 39% horizontal diameter of orbit; few slightly enlarged, smooth scales between tympanum and orbit; posterior region of jaws swollen; supralabials 13/13; infralabials 12/12. Nuchal crest developed, composed of 15 primary, small, triangular spines, the first being the smallest and the eight longest; nuchal crest continuous with a reduced dorsal crest present in the form of elevated serrated ridge, composed of vertebral scales with a more pronounced median keel continuing till above the vent, on the tail in the form of enlarged strongly keeled median scale; 104 longitudinal scale rows around midbody; dorsal and lateral scales keeled, oriented postero-dorsally; ventrals smooth, irregular, as large as the dorsals, slightly larger than the genial and gular scales; an oblique antehumeral fold present, not extending across the throat. Limbs strong, robust, covered with uniform keeled scales, slightly larger than laterals forming parallel longitudinal rows; scales under thighs weakly keeled; length of hindlimb 71% SVL; relative length of fingers 4>3>2>5>1; relative lengths of toes 4>3>5>2>1; fourth toe slightly smaller than fifth finger; 15 subdigital lamellae under fourth finger; 19 subdigital lamellae under fourth toe; subdigital lamellae with sharp keels, bicarinate; tail thick, gradually tapering, swollen at the base; scales on dorsal and ventral surface of tail with sharp keels, larger than laterals; median scales on the dorsal surface of tail enlarged, with a pronounced median keel; tail length 147 mm (incomplete, broken at the tip). Colouration. In life: head and body dull blackish-grey with irregular lighter patches near the flank; a longitudinal thick, lighter buff band from behind the head till above the tail; head laterally darker with indistinct reddish brown speckles behind the orbit, a broken reddish stripe from above the nostril till behind the posterior part of orbit covering the supraorbital region; another pale reddish stipe from the nostril till behind the cheek covering the lip scales and lower margin of tympanum; tympanum pale grey; ventral uniformly lighter, pale grey; gular and genial scales lighter, dirty white; tail with a thick lighter band just at the start, then uniform dark grey followed by indistinct lighter bands, bands more prominent towards the tip. In preservative: colouration pattern mostly similar to that in life, except overall paler; bands on lateral side of head distinct. Variation and secondary sexual characteristics. The other specimens examined agree with the CESL 273 in general morphology and scalation except for some differences that are summarised in Appendix 2 & 3. The examined female specimen (CESL 064) has slightly smaller nuchal spines compared to the males, dorsal crest almost nonexistent; dorsal and lateral scales feebly keeled; tail base not swollen; overall colouration olive-brown, speckled with irregular lighter blotches, 3–4 triangular darker patches on the mid dorsum from neck to the start of tail and series of whitish spots forming broken parallel dorso-lateral stripes. Distribution. Psammophilus dorsalis is distributed all across the low and medium elevation rocky habitats of central and southern Western Ghats. This species has often been observed on huge rock boulders and sheath rocks in and around forests but seem to be more common in open, drier habitats. During this study, P. dorsalis was recorded in various sites from the southern Western Ghats (See Appendix 1 for details). It is also known from drier habitats throughout peninsular India. Ecology and natural history. Psammophilus dorsalis is a diurnal lizard, chiefly rupicolous in habit, and so far, has been recorded exclusively in and around rocky habitats. Individuals were mostly observed basking on boulders and rock cliffs in the mornings. In some instances, it has also been observed on isolated rocks inside tea estates and plantations. It is a very shy and active species and escapes inside the gaps and crevices among boulders at the slightest hint of an approaching threat. In the breeding season, the adult males of this species develop a thick bright red to vermilion coloured band from the head extending till behind the lower back and the entire remaining body turns black. Adult males have been observed only during summer and pre-monsoon while gravid females were found in the early monsoon seasons., Published as part of Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi & Deepak, V., 2018, A systematic revision of Calotes Cuvier, 1817 (Squamata: Agamidae) from the Western Ghats adds two genera and reveals two new species, pp. 401-450 in Zootaxa 4482 (3) on pages 438-440, DOI: 10.11646/zootaxa.4482.3.1, http://zenodo.org/record/1440674, {"references":["Gray, E. (1845) Catalogue of the specimens of lizards in the collection British museum. Trustees of die British Museum / Edward Newman, London, 289 pp.","Boulenger, G. A. (1885) Catalogue of lizards in the British museum. Fol. 1. Geckonidae, Eublepharidae, Uroplatidae, Pygopodidae, Agamidae, Second edition. British Museum (Natural History), London, 436 pp.","Smith, M. A. (1935) The Fauna of British India, Including Ceylon and Burma; Reptilia and Amphibia. Fol. II. Sauria. Taylor and Francis, London, 440 pp.","Boulenger, G. A. (1890) The Fauna of British India, including Ceylon and Burma: Reptilia and Batrachia. Taylor and Francis, London, 541 pp."]}

Published

2018

126. Calotes calotes calotes (Linnaeus 1758

Author

Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi, and Deepak, V.

Subjects

Reptilia, Squamata, Calotes, Animalia, Biodiversity, Chordata, Agamidae, Calotes calotes, Taxonomy

Abstract

Calotes calotes (Linnaeus, 1758) Lacerta calotes ���Linnaeus, 1758. Syst. Nat. 10th ed. 1758: 207. Iguana calotes ���Laurenti 1768. Syn. Rept. 1768: 49. Agama calotes ���Daudin 1802. Hist. Nat. Rept. iii.1802: 361. Calotes calotes ���L��nnberg 1896. Bih. Svensk. Vet. Akad. Stockholm, xxii. 1896:15. Original description. Linnaeus, C. 1758. Systema naturae per regna tria naturae, secundum classes, ordines, genera, species, cum characteribus, differentiis, synonymis, locis. Tomus I. Editio decima, reformata. Laurentii Salvii, Holmiae. 10th Edition, 1758: 207. Taxonomic comments. Calotes calotes was described based on specimens collected from ���Zeylona��� (Sri Lanka). This species is currently known to commonly occur in the wet zones of Sri Lanka and dry zones of southern India. Smith (1935) reported this species from the Nicobar Islands but this was not included in later works (Harikrishnan et al. 2010). The original description by Linnaeus was a two-line description, which was translated by Amarasinghe et al. (2009). Our analysis shows 1% genetic variance (in the 16S gene) between the Sri Lankan and the Peninsular Indian population of Calotes calotes. This suggests that these species moved between the dry zones in Peninsular India and Sri Lanka. Material examined. CESL 0 37 adult female collected from Peppara Wildlife Sanctuary, Kerala; CESL 374 adult male collected from Marayoor, Kerala and BNHS 378 adult male collected Chatikulam, Sri Lanka. Details of collection locality, specimen voucher and GenBank accession number in Appendix 1. Diagnosis and comparison. A medium to large sized Calotes characterized by the posterodorsal orientation of lateral scales; antehumeral pit indistinct; 30���35 midbody scale rows; nuchal and dorsal crest continuous, nuchal crest composed of long lanceolate spines; dorsal spines smaller, gradually diminishing in size, extending beyond the midbody; a row of 8���9 compressed supratympanic spines, divided into two groups; dorsal and lateral scales large, smooth or feebly keeled, ventral scales strongly keeled, mucronate, equal to or slightly larger than laterals; paired postmentals, first pair separated by 1 to 2 median scales; 21���24 subdigital lamellae under fourth finger, 27��� 29 subdigital lamellae under fourth toe; 10���12 supralabials and 9���11 infralabials; uniform, bright green above, with 5���6 thin white transverse stripes, often continuing on the tail as indistinct bands; a bright red horizontal stripe across the orbit; posterior part of the tail dull brown; ventrally pale green; juveniles bright green, white transverse stripes indistinct. From other members of Smith���s C. versicolor group (C. versicolor, C. nemoricola, C. grandisquamis, C. minor, C. maria, C. jerdoni, C. emma and C. mystaceus) C. calotes can be distinguished by a combination of the following characters: smaller body size: adult SVL 73.6���96.8 mm, n=3 (vs. C. nemoricola, adult SVL 112���134.8 mm, n=7; and C. grandisquamis, adult SVL 110.0��� 136.5 mm, n=5); 30���35 midbody scale rows (vs. 38���45 in C. versicolor, n=9, 36��� 43 in C. nemoricola; 58���63 in C. maria; 45���57 in C. jerdoni; 49���65 in C. emma; 48���58 in C. mystaceus and 48���60 in C. minor); ventral scales equal to or slightly larger than laterals (vs. ventral scales smaller than laterals in C. nemoricola, C. grandisquamis, C. versicolor, C. minor, C. maria, C. jerdoni, C. emma and C. mystaceus); crescent-shaped patch of granular scales in front of the shoulder absent (vs. present in C. nemoricola, C. grandisquamis, C. jerdoni, C. emma and C. mystaceus); and a row of 8���9 compressed supratympanic spines (vs. row of 3���4 compressed supratympanic spines in C. nemoricola and C. grandisquamis; two well separated supratympanic spines in C. versicolor; two parallel rows of compressed supratympanic scales in C. maria and C. jerdoni; single well developed postorbital spine in C. emma). Description. Based on specimen CESL 374. A large sized adult male (SVL- 84.7 mm) collected from a shrub along the road near Marayoor, Kerala. Morphometric and meristic data are summarised in Appendix 2 & 3. General habitus moderately compressed. Head moderate (HL/SVL ratio 0.23), elongate (HW/HL ratio 0.73), maximum height slightly less than maximum width; snout pointed; rostral broader than high; nostrils in single nasal shield which is separated from rostral by three scales; mental shield broader than rostral; two postmentals, first pair separated from each other by two small scales; genials smooth; gular sac small, indistinct, composed of strongly keeled scales, slightly smaller than genials; scales on top of snout smooth; scales on top of head heterogenous in size and shape, smooth; canthus-rostralis and supraciliary edge sharp; a row of 8 compressed, spines divided into two groups above the tympanum, the one closer to the nuchal crest longer; orbit diameter 86% of distance between anterior border of orbit and snout tip; tympanum exposed, its greatest diameter 49% of horizontal diameter of orbit; partially keeled, scales between tympanum and orbit smooth, some enlarged, a few with partially keeled edges; posterior region of jaws swollen; supralabials 10/11; infralabials 10/10. Nuchal crest well developed, dorsal crest slightly reduced, continuous; nuchal crest composed of 12 long, conical spines, the first being the smallest; dorsal crest composed of much smaller spines reaching slightly behind midbody; 30 longitudinal scale rows around midbody; dorsal and lateral scales sub-triangular, smooth, ones on the lower back feebly keeled, oriented postero-dorsally; ventrals strongly keeled, mucronate, almost equal to the dorsal and lateral scales. Limbs slender and covered with keeled scales forming parallel longitudinal rows; scales under thighs weakly keeled; length of hindlimb ca. 101 % SVL; relative length of fingers 4>3>5>2>1, second and fifth finger almost equal; relative lengths of toes 4>3>5>2>1; fourth toe much longer than fifth finger; 21 subdigital lamellae under fourth finger; 27 subdigital lamellae under fourth toe; subdigital lamellae with sharp keels, bicarinate; slender, swollen at the base; dorsal and ventral tail scales keeled, ventral tail scales mucronate, strongly keeled; tail length 268 mm. Colouration. In life: dorsum and head uniform, bright green with 5 thin, white transverse stripes, continuing on the tail as indistinct bands; head bright green laterally, lighter towards the cheeks; nuchal spines brownish, a brick red horizontal stripe from posterior corner of the eye till end of orbit, darker behind the eye; few blackish scales below the eye; gular scales lighter, yellowish green; posterior half of the tail dull greyish brown with alternating white bands; tympanum pale grey with greenish edge, ventrally lighter, uniform pale green. Representative image showing live colouration (Fig. 4a). In preservative: colouration mostly similar to that in life, except overall paler. Variation and secondary sexual characteristics. Meristic and morphometric data of two adult males and one adult female are given in Appendix 2 & 3. The examined specimens agree with each other in general morphology and scalation. The examined female specimen (CESL 037) is slightly larger in size and has much smaller nuchal spines, compared to the males, almost equal to the dorsal spines. Distribution. Calotes calotes is distributed in the low and medium elevation dry forests (up to 1000 m asl) of the southern Western Ghats, Eastern Ghats and across Sri Lanka. In the present study, C. calotes was recorded from various sites in the low to mid elevation dry and deciduous forests of the southern Western Ghats (See Appendix 1 for details). This species is common in and around open scrub, secondary and degraded forest patches. Ecology and natural history. Calotes calotes is a diurnal lizard, semi-arboreal to arboreal in habit, and so far, has been recorded mostly in scrub, secondary deciduous forests and plantations. Individuals were mostly seen perching on shrubs, bushes and on trees near edges of forests. In some instances, it has also been observed near villages and within plantations. During this study, it was never recorded from primary evergreen forests. In some sites, they might occur syntopically in the same habitat as C. versicolor., Published as part of Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi & Deepak, V., 2018, A systematic revision of Calotes Cuvier, 1817 (Squamata: Agamidae) from the Western Ghats adds two genera and reveals two new species, pp. 401-450 in Zootaxa 4482 (3) on pages 419-421, DOI: 10.11646/zootaxa.4482.3.1, http://zenodo.org/record/1440674, {"references":["Smith, M. A. (1935) The Fauna of British India, Including Ceylon and Burma; Reptilia and Amphibia. Fol. II. Sauria. Taylor and Francis, London, 440 pp.","Harikrishnan, S., Vasudevan, K. & Choudhury, B. C. (2010) A review of herpetofaunal descriptions and studies from Andaman and Nicobar Islands, with an updated checklist. In: Ramakrishna, Raghunathan, C. & Sivaperuman, C. (Eds.), Recent Trends in Biodiversity of Andaman and Nicobar Islands. Zoological Survey of India, Kolkata, pp 387 - 398.","Amarasinghe, A. A. T., Manthey, U., Stockli, E., Ineich, I., Kullander, S. O., Tiedemann, F., McCarthy, C. & Gabadage, D. E. (2009) The original descriptions and figures of Sri Lankan Agamid lizards (Squamata: Agamidae) of the 18 th and 19 th centuries. Taprobanica, 1 (1), 2 - 15. https: // doi. org / 10.4038 / tapro. v 1 i 1.2771"]}

Published

2018

127. Monilesaurus montanus Pal & Vijayakumar & Shanker & Jayarajan & Deepak 2018

Author

Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi, and Deepak, V.

Subjects

Reptilia, Monilesaurus, Monilesaurus montanus, Squamata, Animalia, Biodiversity, Chordata, Agamidae, Taxonomy

Abstract

Monilesaurus montanus gen. et. sp. nov. (Fig. 7b) Etymology. The species epithet is derived from the word ���montane��� referring to the restricted distribution of this species to high elevation forests (> 1500 m a.s.l). Holotype. BNHS 2411, adult male (Fig. 13), collected at Kudremukh National Park (Fig. 14), Karnataka (1307'54" N, 07516'39" E; 1534.9 m a.s.l); by SPP, SPV and KPD on 28th September 2011. Paratypes: BNHS 2412, adult male and BNHS 2413, adult female collected from Kudremukh National Park, Karnataka by SPV and ADR on 21st August 2009; CESL 131, adult female collected from Siruvani reserve forest, Kerala by SPP and MPV on 0 6th July 2010; CESL 133, adult female collected from Walakkad, Silent Valley National Park, Kerala by SPP and MPV on 23rd November 2010; CESL 330 adult female and CESL 331 an adult male collected from Naduvattam, Tamil Nadu by SPP on 23rd June 2011 and CESL 529 adult male collected from Narimala, Brahmagiri Wildlife Sanctuary, Karnataka by SPP and SRC on 0 9th March 2012. Diagnosis and comparison. A medium sized Monilesaurus with a maximum SVL of 83.4 mm, arboreal species characterized by the backward and downward orientation of lateral body scales; presence of antehumeral fold, throat fold not prominent as the antehumeral fold; 46���52 midbody scale rows; nuchal crest composed of 3���6 small spines; two small separated supratympanic spines; a very small tubercle like postorbital spine barely distinguishable from the surrounding head scales; dorsal and lateral scales feebly keeled, stronger towards ventrals, ventral scales strongly keeled; scales on ventral thigh region feebly keeled; paired postmentals, first pair separated by a single scale; 21���24 subdigital lamellae under fourth finger, 25���30 subdigital lamellae under fourth toe; 9���10 supralabials and 8���9 infralabials; greenish brown above with darker dorsum, a white band below the eye extending till end of jaw. Monilesaurus montanus gen. et sp. nov. can be distinguished from its sister species based on the combination of following characters: larger body size: adult SVL 61���83.4 mm, n=8 (vs. M. ellioti comb. nov. adult SVL 59.4��� 73.8 mm, n=9; M. rouxii comb. nov. adult SVL 51.4���74.8 mm, n=9); lower number of midbody scale rows 46���52 (vs. 62���64 in Monilesaurus acanthocephalus gen. et sp. nov., 52���58 in M. ellioti comb. nov., 52���56 in M. rouxii comb. nov.), presence of a very small, indistinct tubercle like, isolated spine in the posterior corner of orbit (vs. absent in M. rouxii comb. nov., long, distinct isolated spine in M. ellioti comb. nov. and M. acanthocephalus gen. et sp. nov.), 3���6 small nuchal spines (vs. 7���8 small nuchal spines in M. rouxii comb. nov., 6 much longer nuchal spines in C. acanthocephalus gen. et sp. nov., 3���4 long nuchal spines in M. ellioti comb. nov.); small isolated spine on the back of head and above tympanum (vs. longer, prominent spines in M. ellioti comb. nov. and M. acanthocephalus gen. et sp. nov.) presence of white band below the eye (vs. none in M. rouxii comb. nov.; in the form of a spot in M. ellioti comb. nov. and M. acanthocephalus gen. et sp. nov.). Description of holotype. BNHS 2411, a medium sized agamid, adult male (SVL- 78.2 mm). Morphometric and meristic data are summarised in Appendix 2 & 3. General habitus moderately compressed. Head moderately large (HL/SVL ratio 0.31), broad (HW/HL ratio 0.64), maximum height less than maximum width; snout pointed; rostral broader than high; nostrils in single nasal shield, which is separated from rostral by a single scale; mental shield narrower than rostral; two postmentals; first pair separated from each other by a single, small scale; genials keeled; gular sac small, composed of strongly keeled scales, slightly smaller than genials; scales on top of snout smooth except median row, which is keeled; scales on top of head heterogenous in size and shape, keeled; supraorbital scales keeled; canthus-rostralis and supraciliary edge sharp; a very small tubercle like spine at the posterior corner of the orbit; two separated small spines on posterior end of head, the anterior slightly longer, midway between nuchal crest and tympanum, posterior above tympanum; orbit diameter 59% of distance between anterior border of orbit and snout tip; tympanum exposed, its greatest diameter 48% of horizontal diameter of orbit; slightly keeled, enlarged scales between tympanum and orbit; posterior region of jaws swollen; supralabials 9/9; infralabials 8/8. Nuchal crest well developed, composed of three primary, conical spines, the first being the shortest, the third longest; the remaining vertebral scales slightly enlarged relative to adjacent rows and possess a median keel forming a slightly elevated ridge like dorsal crest which continues till the tail base; 50 longitudinal scale rows around midbody; 40 scales on the mid dorsum; scales on dorsum feebly keeled, oriented backwards, lateral scales smaller than dorsal, keeled, oriented backwards and downwards; ventrals strongly keeled, irregular, slightly smaller than dorsals but of similar size as laterals, genials and gular scales; an oblique antehumeral fold present, weakly developed, feebly extending into a throat fold which is not prominent. Limbs slender and covered with strongly keeled scales, larger than laterals, forming parallel longitudinal rows; scales under thighs weakly keeled; length of hindlimb ca. 71% SVL; relative length of fingers 4>3>2>5>1; relative lengths of toes 4>3>5>2>1; fourth toe much longer than fifth finger; 23 subdigital lamellae under fourth finger; 28 subdigital lamellae under fourth toe; subdigital lamellae with sharp keels, bicarinate; slender, swollen at the base; scales on dorsal and ventral surface of tail with sharp keels, mucronate; tail length 190 mm. Colouration. In life: dorsum and head yellowish-green with irregular, alternating light and dark brown patches on the back; a dark brownish band from above the shoulder till the dorsal crest forming a ���v��� shape; head laterally greenish with a whitish band below the posterior end of eye to end of jaw; broken dark striations from above nostril to anterior margin of orbit extending till the tympanum from the posterior margin of orbit in the form of black band; tympanum pale green, lip scales white; thick blackish triangular patch behind the tympanum continuing to the antehumeral fold; an indistinct thin stripe above the labials from the nostril, ending into a black spot anterior to the tympanum; ventral uniformly lighter, pale grey; gular pouch white, irregular dark striations on the sides; tail with alternating dark and light blotches forming irregular bands towards the end. In preservative: dorsum and head buff to light brown with irregular, alternating grey and darker brown patches on the back; tail banded with alternating thick brown and grey blotches; laterally paler with darker brown blotches extending down from the dorsum; lead laterally speckled with grey and brown with a whitish yellow below the posterior end of eye to end of jaw; tympanum pale white, lip scales whitish yellow; ventrally uniform pale grey, lighter below the limbs. Variation and secondary sexual characteristics. Morphometric and meristic data for the type specimens is presented in Appendix 2 & 3. Adult male paratypes range from 61���78.8mm in SVL, whereas adult female paratypes range from 68.4���83.4mm in SVL. The paratypes agree with the holotype (BNHS 2411) in general morphology and scalation except for the following characters: 46���52 longitudinal scale rows around midbody; 21��� 24 subdigital lamellae under fourth finger, 25���30 subdigital lamellae under fourth toe. Supralabials 8 on the right in CESL 124; infralabials 8 on the right in CESL 133 and 8 on the left in CESL 529. All the examined female paratypes (CESL 126, CESL 131, CESL 133 and CESL 331) have slightly smaller nuchal spines compared to the males; lack a dorsal crest and gular sac. Genetic distance. M. montanus gen. et sp. nov. shows 0���1% intraspecific genetic divergence in the 16S gene; 7���8% interspecific genetic divergence from M. rouxii comb. nov.; 4���8% interspecific genetic divergence from M. ellioti comb. nov. and 2���3 % interspecific genetic divergence from M. acanthocephalus gen. et sp. nov. (Appendix 5). Distribution. Monilesaurus montanus gen. et sp. nov., is endemic to the Western Ghats and distributed across the high elevation evergreen forests (above 1250 m asl) of central Western Ghats. During this study, M. montanus gen. et sp. nov. was recorded from montane forests of the following hill ranges: Kudremukh, Brahmagiri, Nilgiri and Elivalmalai (See Fig. 3 & Appendix 1 for details). Ecology and natural history. Monilesaurus montanus gen. et sp. nov., is a diurnal lizard, semi-arboreal to arboreal in habit and so far, has been recorded from montane shola forests (Fig. 14). Individuals were mostly found at night, sleeping on branches of stunted trees within sholas or actively moving on tree trunks. Only in one instance, a female specimen (CESL 133) was found in evergreen forest at a slightly lower elevation (ca. 1250 m asl). In some sites, the lower elevational limits of their distributional range might overlap with the range of M. ellioti comb. nov., but these two species were not observed to be syntopic in any of the sites. A gravid female was recorded in the month of July in Siruvani reserve forest, which hints that pre-monsoon might be a breeding season for this species. No other congeners were found to be syntopically distributed with M. montanus gen. et sp. nov., Published as part of Pal, Saunak, Vijayakumar, S. P., Shanker, Kartik, Jayarajan, Aditi & Deepak, V., 2018, A systematic revision of Calotes Cuvier, 1817 (Squamata: Agamidae) from the Western Ghats adds two genera and reveals two new species, pp. 401-450 in Zootaxa 4482 (3) on pages 435-437, DOI: 10.11646/zootaxa.4482.3.1, http://zenodo.org/record/1440674

Published

2018

128. Discovery of a deeply divergent new lineage of vine snake (Colubridae: Ahaetuliinae: Proahaetulla gen. nov.) from the southern Western Ghats of Peninsular India with a revised key for Ahaetuliinae

Author

Mallik, Ashok Kumar, primary, Achyuthan, N. Srikanthan, additional, Ganesh, Sumaithangi R., additional, Pal, Saunak P., additional, Vijayakumar, S. P., additional, and Shanker, Kartik, additional

Published

2019

129. Erythropoietin in Neonates with Perinatal Asphyxia Undergoing Therapeutic Hypothermia—A Prospective Cohort Study

Author

Charki, Siddu, Patil, S. V., Vijayakumar, S., and Kolkar, Yalagurswamy

Abstract

Aims:To assess the safety and feasibility of erythropoietin (EPO) in asphyxiated neonates undergoing therapeutic hypothermia (TH).Subjects and methods:This study enrolled 60 neonates with HIE undergoing TH. 30 neonates were divided into EPO with TH group, where neonates received EPO (dose), at a dose rate of 1000 IU/kg/48 hours, for four doses and the remaining 30 neonates undergoing TH were into control group. Magnetic resonance imaging brain was undertaken between 10 and 14 days of life in surviving neonates. The Bayley Scales of Infant (BSI) Development IV was performed at regular intervals up to the age of 12 months.Results:Amplitude-integrated electroencephalogram (aEEG) showed burst suppression (19% vs. 11%), low voltage (10% vs. 4%), and flat trace (7% vs. 3%) in control group in comparison with EPO concurrent with TH group which was statistically significant. Brain magnetic-resonance imaging (MRI) done at 12 days (±2 days) showed significant brain injury patterns such as severe brain injury (4% vs. 9% P = .05) and regional specific HIE (7% vs. 13%, P = .03) in control group of only TH neonates. At 12 months, neurodevelopment outcomes in EPO with TH group neonates showed a favorable outcome.Conclusion:rhEPO concurrent with TH in HIE neonates resulted in significantly less severe brain injuries in MRI brain in HIE neonates. aEEG changes were less statistically significant in EPO with TH group with favorable neurodevelopmental outcomes at 12 months of age.

Published

2024

130. Fejervarya

Author

Dinesh, K. P., Vijayakumar, S. P., Channakeshavamurthy, B. H., Torsekar, Varun R., Kulkarni, Nirmal U., and Shanker, Kartik

Subjects

Amphibia, Fejervarya, Animalia, Biodiversity, Anura, Chordata, Dicroglossidae, Taxonomy

Abstract

Phylogeny of Fejervarya The phylogeny recovered a well supported clade consisting of all Fejervarya from South and South East Asia (Fig 2). We also recovered two sister clades within Fejervarya. The geographical ranges of the two clades broadly overlap around the Northeast Indian regions and Thailand (Fig 2). The Fejervarya clade was recovered as sister to Sphaerotheca. The unidentified individuals in our collection formed a monophyletic group and showed a sister relationship with Minervarya sahyadris (Fig 2). The clade consisting of the unidentified individuals and Minervarya sahyadris was deeply nested within the larger Fejervarya clade. Based on this, we synonymize Minervarya Dubois, Ohler and Biju, 2001 under Fejervarya Bolkay, 1915 (see discussion below) and provide a diagnosis and describe the unidentified individuals in our collection as Fejervarya gomantaki sp. nov. Generic allocation. There is considerable confusion in generic level taxonomy and systematics within dicroglossid frogs, specifically the distinction between Fejervarya, Minervarya and Zakerana (see discussion below). Apart from the strong phylogenetic support (Fig 2), the individuals are assignable to the genus Fejervarya based on the diagnosable generic morphological characters assigned by Dubois et al. (2001) for the then genus Minervarya Dubois, Ohler and Biju, 2001 and Fejervarya Bolkay, 1915; namely to the group of small sized frogs having snout not greatly pointed or slightly rounded; relatively small tympanum; small rounded or laterally compressed internal metatarsal tubercles; rudimentary webbing on feet and small tibia; presence of rictal glands, fejervaryan lines, and horizontal band on the upper lip. Within Fejervarya, presence of a rictal gland is a derived character unique to the clade composed of Fejervarya sahyadris, Fejervarya gomantaki sp. nov. and a north eastern species Fejervarya chilapata.

Published

2015

131. Systematic status of Fejervarya (( Amphibia, Anura, Dicroglossidae) from South and SE Asia with the description of a new species from the Western Ghats of Peninsular India

Author

Dinesh, K. P., Vijayakumar, S. P., Channakeshavamurthy, B. H., Torsekar, Varun R., Kulkarni, Nirmal U., and Shanker, Kartik

Subjects

Amphibia, Animalia, Biodiversity, Anura, Chordata, Dicroglossidae, Taxonomy

Abstract

Dinesh, K. P., Vijayakumar, S. P., Channakeshavamurthy, B. H., Torsekar, Varun R., Kulkarni, Nirmal U., Shanker, Kartik (2015): Systematic status of Fejervarya (( Amphibia, Anura, Dicroglossidae) from South and SE Asia with the description of a new species from the Western Ghats of Peninsular India. Zootaxa 3999 (1): 79-94, DOI: http://dx.doi.org/10.11646/zootaxa.3999.1.5

Published

2015

132. Evaluation on mechanical properties of randomly oriented Caryota fiber reinforced polymer composites

Author

Vijayakumar, S. and Palanikumar, K.

Abstract

Currently, the fibers made of synthetic materials are replaced by the natural fibers in composites, due to their environmental impact. So, this paper introduces a new natural fiber, the Caryota fiber, which is developed from the fishtail palm. In the present investigation, chopped randomly-oriented Caryota fiber is reinforced with the polyester resin to prepare a composite laminate. The compression molding machine is utilized to manufacture these composites. Further, the mechanical characteristics are evaluated by carrying out various tests such as tensile, impact, shear etc. In addition, the Scanning Electron Microscope (SEM) is used for observing interfacial properties such as cracks, voids, fiber pull out, etc. in the fractured surface. The analysis of the results indicates that, 40% of fiber content performs better than the other weight fractions. The research further suggests that, the Caryota fiber properties produce better results than the other natural fibers in the literature. Hence, this composite is utilized as a substitute material in the automobile and related industries.

Published

2020

133. Structural insights into the anti-cancer activity of quercetin on G-tetrad, mixed G-tetrad, and G-quadruplex DNA using quantum chemical and molecular dynamics simulations

Author

Vinnarasi, S., Radhika, R., Vijayakumar, S., and Shankar, R.

Abstract

AbstractHuman telomerase referred as ‘terminal transferase’ is a nucleoprotein enzyme which inhibits the disintegration of telomere length and act as a drug target for the anticancer therapy. The tandem repeating structure of telomere sequence forms the guanine-rich quadruplex structures that stabilize stacked tetrads. In our present work, we have investigated the interaction of quercetin with DNA tetrads using DFT. Geometrical analysis revealed that the influence of quercetin drug induces the structural changes into the DNA tetrads. Among DNA tetrads, the quercetin stacked with GCGC tetrad has the highest interaction energy of −88.08 kcal/mol. The binding mode and the structural stability are verified by the absorption spectroscopy method. The longer wavelength was found at 380 nm and it exhibits bathochromic shift. The findings help us to understand the binding nature of quercetin drug with DNA tetrads and it also inhibits the telomerase activity. Further, the quercetin drug interacted with G-quadruplex DNA by using molecular dynamics (MD) simulation studies for 100 ns simulation at different temperatures and different pH levels (T = 298 K, 320 K and pH = 7.4, 5.4). The structural stability of the quercetin with G-quadruplex structure is confirmed by RMSD. For the acidic condition (pH = 5.4), the binding affinity is higher toward G-quadruplex DNA, this result resembles that the quercetin drug is well interacted with G-quadruplex DNA at acidic condition (pH = 7.4) than the neutral condition. The obtained results show that quercetin drug stabilizes the G-quadruplex DNA, which regulates telomerase enzyme and it potentially acts as a novel anti-cancer agent.Communicated by Ramaswamy H. Sarma

Published

2020

134. Speckle Noise Reduction in SAR Images Using Fuzzy Inference System

Author

Santhi, V. and Vijayakumar, S

Abstract

In recent years, image processing has played a vital role in major research areas. In this article, a new approach using a fuzzy inference system is proposed for speckle reduction in SAR images. In general, SAR images are predominantly used to monitor coastal regions to detect oil spills, ship wake, sea shores and climate changes. In this article, a gamma distribution model is used in a fuzzy inference system to remove speckle noise from SAR images. The performance of the proposed model is tested using fuzzy inference systems, such as mamdani and sugeno. The experimental results proved the efficiency of the proposed system through objective metrics.

Published

2019

135. Raorchestes aureus Vijayakumar, Dinesh, Prabhu & Shanker, 2014, sp. nov

Author

Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V., and Shanker, Kartik

Subjects

Amphibia, Rhacophoridae, Raorchestes, Animalia, Biodiversity, Anura, Raorchestes aureus, Chordata, Taxonomy

Abstract

2. Raorchestes aureus sp. nov. (Figures 2, 3 & 5; Tables 2 & 3) Holotype: ZSI/ WGRC /V/A/ 867 (CESF 1165), an adult male (SVL 24.8 mm), collected by S.P. Vijayakumar and Mrugank V. Prabhu in July 2010 from a high elevation site (10.9452 N, 76.6446 E) in Elivalmalai Massif (Fig 1), Western Ghats, Peninsular India. Paratype: ZSI/ WGRC /V/A/ 868 (CESF 1164), an adult female (SVL 28.3), collected by S.P. Vijayakumar and Mrugank V. Prabhu in July 2010 from a high elevation site (10.9452 N, 76.6446 E) in Elivalmalai Massif (Fig 1), Western Ghats, Peninsular India. Lineage diagnosis. Raorchestes aureus sp. nov. can be diagnosed as a deeply divergent (16 S— 7.3 %) lineage nested within a larger clade N (Fig 3). The lineage is isolated on the high elevations of Elivalmalai Massif (Fig 1 & 2). Morphologically, it shows strong signatures of divergence from other similar relatives within clade N (see below). We use all the above criteria, genetic divergence, geographical range and morphology to diagnose this lineage. The relatives that potentially overlap in morphology and hence could be confused with this lineage within the clade N are discussed below. Field diagnosis. Morphology. Raorchestes aureus sp. nov. could be confused with R. chromasynchysi which occurs in sympatry (see remarks). However, the new species can be differentiated based on the shorter thigh length, TL/SVL= 0.45 (0.44–0.45, n= 4) (vs. TL/SVL= 0.52 (0.50–0.54, n= 3) in R. chromasynchysi); shorter tibia length, ShL/SVL= 0.46 (0.45–0.47, n= 4) (vs. ShL/SVL= 0.51 (0.50–0.51, n= 3) in R. chromasynchysi); in having a distinct golden iris (vs. silvery to light brown in R. chromasynchysi); dorsal coloration shades of brown (vs. very variable from shades of brown to green in R. chromasynchysi); anterior and posterior region of thigh (femur) characterized by distinct or faint cross bar with alternating darker and lighter shades of brown (vs. plain coloration on the posterior thigh and dark coloration with yellow blotches on the anterior thigh in R. chromasynchysi); lateral sides of irregular mottling of brown/yellow and green extending from groin to base of supratympanic fold (vs. distinct separation of dorsal and ventral coloration without any such mottling). Geography. Current data suggests a narrow restricted range to the high elevation of Elivalmalai Massif in the Western Ghats (see natural history and distribution for details). Description of holotype (all measurements in mm). A small sized bush frog (SVL = 24.8 mm), width of head broader than head length (HW = 10.3 mm; HL = 8.3 mm), flat dorsally; snout acutely pointed in total profile, slightly protruding beyond mouth. Snout length is sub equal to diameter of eye (SL = 3.4 mm, EL = 3.7 mm). Canthus rostralis angular, loreal region slightly concave. Interorbital space (IUE = 2.9 mm) flat and sub equal to upper eyelid (UEW = 2.6 mm). Interorbital space between posterior margins of the eyes 1.8 times that of anterior margins (IFE = 5.0, IBE = 9.1 mm). Nostrils oval, nearer to tip of snout. Weak symphysial knob. Pupil horizontal. Tympanum distinct, rounded, small, barely visible behind the eye. Tongue bifid, granular with a papilla. Supratympanic fold from behind eye to shoulder. Relative length of fingers I Hind limb long, heels overlap when folded at right angles to the body. Thigh/Femur (TL = 11.2 mm), sub equal to Shank/Tibia (ShL = 12.1 mm); longer than foot (FOL = 9.7 mm) and less than heel to tip of fourth toe (TFOL = 16.0 mm). Relative toe length I Color in life. Limbs faintly cross-barred, pattern extending towards the anterior and posterior parts of the thigh. Lateral sides characterized by irregular mottling of yellow and light green extending from groin to base of supratympanic fold. Ventral parts of head, body, hand and foot mottled, but more pronounced at the region of belly and throat. Iris distinct golden with brown edged coarse speckles around the pupil, visible even in the preserved specimens. Etymology. The species is named after the consistent golden iris coloration (Latin: aureus = golden). Natural history and distribution. All the individuals were collected from forest edges in a grassland site and all males located were found calling at the ground level. It appears to be a range restricted species, recorded from a single high elevation (1524 m) site in Elivalmalai Massif (Fig 1 & 2). The elevational range within Elivalmalai needs additional field sampling. Remarks. R. chromasynchysi was known only from the type locality (Biju and Bossuyt 2009) and a recent record from north of its type locality (Dinesh and Radhakrishnan, 2012). We have uncovered multiple potential lineages across various Massifs and hill ranges in the central Western Ghats (see above under sub-clade composition). For the above quantitative comparison, we have used individuals from a shallow divergent lineage that overlap with the range of Raorchestes aureus sp. nov.

Published

2014

136. Raorchestes echinatus Vijayakumar, Dinesh, Prabhu & Shanker, 2014, sp. nov

Author

Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V., and Shanker, Kartik

Subjects

Amphibia, Rhacophoridae, Raorchestes echinatus, Raorchestes, Animalia, Biodiversity, Anura, Chordata, Taxonomy

Abstract

4. Raorchestes echinatus sp. nov. (Figures 2, 3 & 7; Tables 2 & 3) Holotype: ZSI/ WGRC /V/A/ 871 (CESF 1412), an adult male (SVL 18.0 mm), collected by S.P. Vijayakumar and K.P. Dinesh in September 2011 from a grassland site (13.4228 N, 75.7695 E), Baba Budan Massif (Fig 1), Western Ghats, Peninsular India. Paratype: ZSI/ WGRC /V/A/ 872 (CESF 1414), an adult male (SVL 19.0), collected by collected by S.P. Vijayakumar and K.P. Dinesh in September 2011 from a grassland site (13.4228 N, 75.7695 E), Baba Budan Massif (Fig 1), Western Ghats, Peninsular India. Lineage diagnosis. This lineage belongs to the larger clade N (Fig 3), with an unresolved relationship status within this clade, but with very high levels (16 S��� 7.3 %) of divergence from all other lineages. It exhibits a number of unique morphological characteristics (Fig 7) (see field diagnosis) and shows strong affinity towards grasslands and is restricted geographically to the high elevations of Baba Budan Massif in the Western Ghats. We diagnose this lineage based on the deep genetic divergence, morphology, ecology and geography. Field diagnosis. Morphology. Raorchestes echinatus sp. nov. superficially resembles R. tuberohumerus in adult male size SVL 18.4 (18.0���19.0, n= 3) (vs. adult male size SVL 18.3 (17.7 ���19.0, n= 6) in R. tuberohumerus), however a number of divergent characters could be discerned; larger head width, HW/SVL= 0.40 (0.38���0.41, n= 3) (vs. HW/SVL= 0.35 (0.33���0.36, n= 6) in R. tuberohumerus); shorter head length, HL/SVL= 0.27 (0.24���0.29, n= 3) (vs. HL/SVL= 0.37 (0.36���0.40, n= 6) in R. tuberohumerus); shorter eye length, EL/SVL= 0.104 (0.099���0.108, n= 3) (vs. EL/SVL= 0.127 (0.111���0.137, n= 6) in R. tuberohumerus); shorter tibia, ShL/SVL= 0.36 (0.34���0.38, n= 3) (vs. ShL/SVL= 0.46 (0.41���0.49, n= 6) in R. tuberohumerus); shorter femur length, TL/SVL= 0.409 (0.39���0.43, n= 3) (vs. TL/SVL= 0.50 (0.46���0.52, n= 6) in R. tuberohumerus); skin, on the dorsum rough with minute horny ridges, more spinular and on the dorsal surface of limbs smooth; lateral and ventral sides granular (vs. sparsely granular dorsum in R. tuberohumerus); yellowish throat finely speckled in brown (vs. flesh coloured, speckled in black in R. tuberohumerus); ventral coloration, white mottlings on a dark background, the pattern extending into femur, tibia, tarsus (vs. anterior thigh region characterized by dark colouration with distinct yellow blotches in R. tuberohumerus). Additionally the new species, Raorchestes echinatus sp. nov., can be easily distinguished morphologically from known congeners in clade N, that potentially overlap with its geographical range, by its size, horny ridges on the dorsum, ventral and throat coloration. Ecology. A species of the open habitat and all individuals were observed in the grasslands. Geography. Distribution data suggests that it is restricted to the Baba Budan Massif (see natural history and distribution for details). Description of holotype (all measurements in mm). A small sized bush frog (SVL = 18.0 mm), width of head broader than head length (HW = 6.9 mm; HL = 4.8 mm), flat dorsally; snout short and pointed, slightly protruding beyond mouth. Snout length is sub equal to diameter of eye (SL = 2.2 mm, EL = 1.9 mm). Canthus rostralis angular, loreal region flat. Interorbital space (IUE = 2.2 mm) flat and sub equal to upper eyelid (UEW = 1.5 mm). Interorbital space between posterior margins of the eyes 1.6 times that of anterior margins (IFE = 3.7, IBE = 5.9 mm). Nostrils oval, nearer to tip of snout. Weak symphysial knob. Pupil horizontal. Tympanum indistinct, rounded, barely visible behind the eye. Tongue bifid, granular without a papilla. Supratympanic fold from behind eye to shoulder. Relative length of fingers IColor in life. Dorsum with olive patches on a brown background with rufous tinge, distinct spinular tubercles behind the head; a mid dorsal ridge coloured off-white from the snout tip to vent (Fig 7 a); ventrally a distinct mid ventral white line (Fig 7 d), belly predominantly white with black irregular interconnected patches. Ventral pattern extends to femur tibia and tarsus, throat yellow finely speckled with brown. Iris with irregular golden speckles with maroon edges and a distinct brown band on the lower half and brown towards anterior and posterior edges. Etymology. The species is named after the spinular projections on the dorsum (Latin: echino = spiny). Natural history and distribution. All individuals were observed in grasslands on grass blades (30.8 cm, n= 5). The species was observed only in the higher elevations (1464���1864 m, n= 6) of Baba Budan Massif (Fig 1 & 2). Further surveys are needed to verify the presence of either conspecifics or close relatives of this lineage in the adjoining Massifs of Kudremukh and Pushpagiri., Published as part of Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V. & Shanker, Kartik, 2014, Lineage delimitation and description of nine new species of bush frogs (Anura: Raorchestes, Rhacophoridae) from the Western Ghats Escarpment, pp. 451-488 in Zootaxa 3893 (4) on pages 468-470, DOI: 10.11646/zootaxa.3893.4.1, http://zenodo.org/record/287578

Published

2014

137. Raorchestes flaviocularis Vijayakumar, Dinesh, Prabhu & Shanker, 2014, sp. nov

Author

Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V., and Shanker, Kartik

Subjects

Amphibia, Rhacophoridae, Raorchestes, Animalia, Biodiversity, Raorchestes flaviocularis, Anura, Chordata, Taxonomy

Abstract

6. Raorchestes flaviocularis sp. nov. (Figures 2, 3, 9 & 10; Tables 2 & 3) Holotype: ZSI/ WGRC /V/A/ 875 (CESF 1406) (SVL 26.5 mm), collected by S.P. Vijayakumar and Varun R Torsekar in September 2011 from a disturbed forest fragment site (9.6064 N, 77.3033 E) located in a tea garden mosaic, Megamalai Massif (Fig 1), Peninsular India. Paratype: ZSI/ WGRC /V/A/ 876 (CESF 1251) (SVL 23.9), collected by S.P. Vijayakumar, Mrugank V. Prabhu and Mayavan in August 2010 from a disturbed forest fragment site (9.6064 N, 77.3033 E) located in a tea garden mosaic, Megamalai Massif (Fig 1), Peninsular India. Lineage diagnosis. Raorchestes flaviocularis sp. nov. can be diagnosed phylogenetically as a member of the Ochlandrae clade (Fig 3), showing sister relationship to Raorchestes chalazodes (Fig 10 a) (see discussion below). Though it exhibits shallow divergence (16 S— 1.2 %) with its allopatric sister, we diagnose this lineage and consider it for description based on its phylogenetic position (Ochlandrae clade), distinct morphology (coloration and skin pattern), geographical range and acoustic divergence (Fig 9, 10). Field diagnosis. Morphology. Raorchestes flaviocularis sp. nov. shows strong similarity with its sister lineage R. chalazodes in the morphometric variables considered. However, it exhibits very strong divergence in dorsum skin coloration and patterns (see Fig 9 a, 10 b). In Raorchestes flaviocularis sp. nov., the green dorsum coloration, with a lichen pattern, do not extend on to the hand and foot (vs. dorsal skin colour uniform green extending on to the hand and foot in R. chalazodes (Fig 10 a). It exhibits signatures of divergence in the limb length (shorter thigh/femur length (TL/SVL= 0.40, 0.40 – 0.40, n= 2) in Raorchestes flaviocularis sp. nov. in comparison to R. chalazodes (TL/SVL= 0.43, 0.40–0.45, n= 3) and shorter tibia/shank length (ShL/SVL= 0.42, 0.42–0.43, n= 2) in Raorchestes flaviocularis sp. nov. in comparison to R. chalazodes (ShL/SVL= 0.45, 0.44–0.45, n= 3). Additionally, the new species can be readily distinguished from all other close relatives by its iris pattern (characterized by very distinct small golden yellow patches on a dark background color) and also the dorsum coloration and skin pattern (Fig 9). Behaviour. Raorchestes flaviocularis sp. nov. shows divergence from its sister lineage in its shorter call length (0.59 ± 0.07 (N= 19) vs. 2.11 ± 0.42 (N= 43) in R. chalazodes), low number of pulses (4.95 ± 0.52 (N= 19) vs. 21.08 ± 3.47 (N= 24) in R. chalazodes, lower pulse rate (7.36 ± 0.62 (N= 19) vs. 9.99 ± 0.96 (N= 24) in R. chalazodes and greater dominant frequency (2675.82 ± 74.19 (N= 38) vs. 2523.78 ± 62.93 (N= 23) in R. chalazodes) (Fig 10). Considering the short overlap in the range of dominant frequency of the calls of the two lineages, we mainly use strong divergence in the temporal call characteristics as an additional evidence for recognizing and naming this lineage. Geography. Restricted to the Megamalai Massif (see natural history and distribution for details). Description of holotype (all measurements in mm). A small sized bush frog (SVL = 26.5 mm), width of head broader than head length (HW = 9.7 mm; HL = 6.7 mm), arched, flat dorsally; snout short and acuminate in total profile, slightly protruding beyond mouth. Snout length is sub equal to diameter of eye (SL = 2.6 mm, EL = 3.2 mm). Canthus rostralis rounded, loreal region slightly concave. Interorbital space (IUE = 2.7 mm) flat, slightly broader than upper eyelid (UEW = 1.7 mm). Interorbital space between posterior margins of the eyes 1.8 times that of anterior margins (IFE = 4.5, IBE = 8.2 mm). Nostrils oval, nearer to tip of snout. Weak symphysial knob. Pupil horizontal. Tympanum rather indistinct, rounded, barely visible behind the eye. Tongue bifid, granular with a distinct retractile papilla. Supratympanic fold from behind eye to shoulder. Relative length of fingersI Hind limb long, heels barely touch when folded at right angles to the body. Thigh/Femur (TL = 10.2 mm), sub equal to Shank/Tibia (ShL = 10.1 mm) and less than heel to tip of fourth toe (TFOL = 15.4 mm). Relative toe length I Color in life. Dorsum with a distinct lichen pattern with uniform green colouration (Fig 9 (a)), the pattern broken irregularly exposing the brown fleshy skin colouration; dorsal pattern extends to mid belly laterally and to dorsal surface of femur, tibia and lower tarsus. Canthus region fleshy brown with occasional green patches in few individuals. Dorsal parts of arms, fingers and disc colour similar to canthus region. Groin, anterior and posterior femur, tibia and tarsus flesh coloured. Iris dark brown with distinct irregular golden yellow patches. Etymology. The species is named after the ‘metallic yellow’ colour of the iris (Latin: flavin = yellow; oculus = eye). Natural history and distribution. A sub-canopy lineage (325 cm, n= 2), it is difficult to locate due to its ventriloquistic call and occurrence in the sub-canopy. Like other members of the Ochlandrae clade, it was also heard calling from Ochlandra grass patches. However, the two individuals whose descriptions are given were obtained from a highly disturbed forest fragment, on leaves of short trees (Ochlandra reeds, further observations are needed to verify the habitat association of this new lineage. It is a species of high elevations (1459–1569 m, n = 10), and restricted in distribution to the Upper Manalar Plateau, Megamalai Massif (Fig 1 & 2) in the southern Western Ghats. Based on our call recordings in the adjoining Anaimalai Massif (Fig 1), we anticipate a related lineage or an isolated population.

Published

2014

138. Raorchestes indigo Vijayakumar, Dinesh, Prabhu & Shanker, 2014, sp. nov

Author

Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V., and Shanker, Kartik

Subjects

Amphibia, Rhacophoridae, Raorchestes indigo, Raorchestes, Animalia, Biodiversity, Anura, Chordata, Taxonomy

Abstract

7. Raorchestes indigo sp. nov. (Figures 2, 3 & 11; Tables 2 & 3) Holotype: ZSI/ WGRC /V/A/ 877 (CESF 1437), a female (SVL 25.7 mm), collected by S.P. Vijayakumar and K.P. Dinesh in September 2011 from a stunted forest site (13.1333 N, 75.2704 E), Kudremukh Massif (Fig 1), Western Ghats, Peninsular India. Paratype: ZSI/ WGRC /V/A/ 878 (CESF 123), a female (SVL 24.4 mm), collected by S.P. Vijayakumar and M.S. Chaitra in October 2008 from a stunted forest site (13.1347 N, 75.2705 E) Kudremukh Massif (Fig 1), Western Ghats, Peninsular India. Lineage diagnosis. Raorchestes indigo sp. nov. could be readily diagnosed by its deep divergence (16 S��� 6.4 %) on the phylogenetic tree (Fig 3), with an unresolved relationship status within clade N. It is morphologically distinct (Fig 11) from all other members of the subclade N. It is geographically restricted to the high elevations of the Kudremukh Massif. The lineage is diagnosed based on four axes: phylogenetic position, genetic divergence, morphological distinctness and geographical distribution. Field diagnosis. Morphology. There are no close relatives (within the clade N) that could be confused with this lineage. All can be readily distinguished by a combination of the following characteristics. (1) Size (SVL 24.3���25.7 mm, n= 5); (2) Dorsum greenish with irregular black and yellow spots/blotches; (3) ventrally uniform bluish white (Fig 11 (d)) (4) indigo coloration of the groin, posterior arm pits, anterior and posterior femur, tibia and tarsus (unique among the species of Raorchestes, Fig 11 (d)); (5) iris silvery brown (Fig 11 (b)). Geography. Restricted in distribution to the high elevations of the Kudremukh Massif (see natural history and distribution for details). Description of holotype (all measurements in mm). A small sized bush frog (SVL = 25.7 mm), width of head broader than head length (HW = 10.1 mm; HL = 7.0 mm), flat dorsally; snout acutely pointed, slightly protruding beyond mouth. Snout length is sub equal to diameter of eye (SL = 3.2 mm, EL = 2.8 mm). Canthus rostralis angular, loreal region flat. Interorbital space (IUE = 3.2 mm) flat and broader than upper eyelid (UEW = 2.3 mm). Interorbital space between posterior margins of the eyes 1.7 times that of anterior margins (IFE = 5.2, IBE = 8.9 mm). Nostrils oval, nearer to tip of snout. Weak symphysial knob. Pupil horizontal. Tympanum indistinct, barely visible behind the eye. Tongue bifid, granular with a retractile papilla. Supratympanic fold from behind eye to shoulder. Relative length of fingers IColor in life. Dorsum, canthal region, lateral parts distinctly green with bluish tinge; posterior arm pits, groin, anterior and posterior femur, tibia and tarsus distinctly indigo varying in lighter to darker (at groin) shades. Dorsum with irregular fine black blotches, denser towards head region. Ventrally uniform bluish white (Fig 11 d), throat white with yellow at the lip margins. Iris with a distinct silvery background, coarsely speckled with shades of brown. Etymology. The species is named after the unique ���indigo��� colour of the groin and other under parts of the body. The specific epithet ��� indigo ��� is used as a noun in apposition to generic name. Natural history and distribution. A range restricted species, observed in the high elevation (> 1700 m) stunted forests around the highest peak in the Kudremukh Massif (Fig 1 & 2). All the individuals were observed on the forest floor on leaves (avg. 116 cm above ground level, n= 6). Further surveys are needed to locate populations in other high elevations zones within Kudremukh Massif and also to explore the presence of any allied lineages in the adjacent Pushpagiri Massif., Published as part of Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V. & Shanker, Kartik, 2014, Lineage delimitation and description of nine new species of bush frogs (Anura: Raorchestes, Rhacophoridae) from the Western Ghats Escarpment, pp. 451-488 in Zootaxa 3893 (4) on pages 475-477, DOI: 10.11646/zootaxa.3893.4.1, http://zenodo.org/record/287578

Published

2014

139. Raorchestes blandus Vijayakumar, Dinesh, Prabhu & Shanker, 2014, sp. nov

Author

Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V., and Shanker, Kartik

Subjects

Amphibia, Raorchestes blandus, Rhacophoridae, Raorchestes, Animalia, Biodiversity, Anura, Chordata, Taxonomy

Abstract

3. Raorchestes blandus sp. nov. (Figures 2, 3 & 6; Tables 2 & 3) Holotype: ZSI/ WGRC /V/A/ 869 (CESF 104), an adult male (SVL 18.4 mm), collected by S.P. Vijayakumar and Mayavan during August 2008, from a fragmented lowland wet evergreen forest site (10.1284 N, 76.7588 E) on the western side of the Anaimalai Massif (Fig 1), Western Ghats, Peninsular India. Paratype: ZSI/ WGRC /V/A/ 870 (CESF 329), an adult male (SVL 19.1 mm), collected by S.P. Vijayakumar and Mayavan in June 2009 from an evergreen forest site (8.6667 N, 77.1833 E) in the Parambikulam protected area, western slopes of Anaimalai Massif (Fig 1), Western Ghats, Peninsular India. Lineage diagnosis. Raorchestes blandus sp. nov. can be readily discerned on a phylogenetic tree (Fig 3), and is characterized by high genetic divergence (16 S��� 14.1 %) from its close relative R. chotta. Morphologically, it could be confused with R. chotta, but could be discerned using their morphological characteristics (See Field diagnosis). It is also very distinct on major aspects of morphology and coloration from Raorchestes archeos sp. nov (Fig 4, also see field diagnosis section of Raorchestes archeos sp. nov.). Field diagnosis. Morphology. Raorchestes blandus sp. nov. could be superficially confused with Raorchestes chotta. However Raorchestes blandus sp. nov. can be distinguished from R. chotta in the larger male adult size of SVL 18.5 (18.0��� 19.5, n= 4) (vs. 16.6 (16.0��� 17.2, n= 7) in R. chotta); shorter head length, HL/SVL= 0.30 (0.28���0.32, n= 4) (vs. HL/SVL= 0.38 (0.36���0.41, n= 7) in R. chotta); Head width (HW= 7.5, 7.2���7.7, n= 4) longer than head length (HL= 5.6, 5.1 ���6.0, n= 4) (vs. head width (HW= 6.5, 6.0��� 6.9, n= 7) equal to head length (HL= 6.4, 5.8���6.7, n= 7) in R. chotta); shorter snout length, SL/SVL= 0.14 (0.13���0.15, n= 4) (vs. SL/SVL= 0.17 (0.16���0.18, n= 7) in R. chotta). Presence of rufous irregular glandular patches on the dorsal surface of skin in the shoulder, posterior side of the body, and in the joints of arms (vs. absence of glandular patches in R. chotta (Biju and Bossuyt 2009)). Ecology. Restricted to the under-storey in wet evergreen forests. Geography. This species is restricted in distribution to the low and medium elevations of the western slopes of Anaimalai massif (see natural history and distribution for details). Description of holotype (all measurements in mm). A small sized bush frog (SVL = 18.4 mm), width of head broader than head length (HW = 7.7 mm; HL = 5.1 mm), flat dorsally; snout acutely pointed in total profile, slightly protruding beyond mouth. Snout length is sub equal to diameter of eye (SL = 2.4 mm, EL = 2.7 mm). Canthus rostralis angular, loreal region flat. Interorbital space (IUE = 2.0 mm) flat and equal to upper eyelid (UEW = 2.0 mm). Interorbital space between posterior margins of the eyes 1.8 times that of anterior margins (IFE = 3.6, IBE = 6.4 mm). Nostrils oval, nearer to tip of snout. Weak symphysial knob. Pupil horizontal. Tympanum minute, rounded, barely visible behind the eye. Tongue bifid, granular with papilla. Supratympanic fold from behind eye to shoulder. Relative length of fingers IColor in life. Dorsum rufous or brown with irregular dark brown blotches; small orange/rufous glandular patches on the head (Fig 6 a), shoulder, elbow, on the dorsum, posterior part of back and on the finger; throat finely speckled with brown; fore and hind arm barred. Skin on dorsum finely granular. Etymology. The species named after its pleasant (Latin: bland =pleasant) call notes. Common in the lowland wet forests of Anaimalai. Natural history and distribution. A forest dwelling lineage, it is usually observed calling from understory shrubs. The distribution ranges from low to mid elevations (45���806 m, n= 13) of Anaimalai Massif (Fig 1 & 2). Current data suggests that there is no overlap in the geographical range of Raorchestes blandus sp. nov. with its close relatives R. chotta and Raorchestes archeos sp. nov. An additional population that resembles this lineage was encountered in the medium and low elevations of Periyar Plateau. Considering a potential zone of overlap with the northern range R. chotta, we reserve the identity of this population for further verification., Published as part of Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V. & Shanker, Kartik, 2014, Lineage delimitation and description of nine new species of bush frogs (Anura: Raorchestes, Rhacophoridae) from the Western Ghats Escarpment, pp. 451-488 in Zootaxa 3893 (4) on pages 466-468, DOI: 10.11646/zootaxa.3893.4.1, http://zenodo.org/record/287578, {"references":["Biju, S. D & Bossuyt, F. (2009) Systematics and phylogeny of Philautus Gistel, 1848 (Anura, Rhacophoridae) in the Western Ghats of India, with descriptions of 12 new species. Zoological Journal of the Linnean Society, 155, 374 - 444. http: // dx. doi. org / 10.1111 / j. 1096 - 3642.2008.00466. x"]}

Published

2014

140. Raorchestes primarrumpfi Vijayakumar, Dinesh, Prabhu & Shanker, 2014, sp. nov

Author

Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V., and Shanker, Kartik

Subjects

Amphibia, Rhacophoridae, Raorchestes, Animalia, Biodiversity, Raorchestes primarrumpfi, Anura, Chordata, Taxonomy

Abstract

9. Raorchestes primarrumpfi sp. nov. (Figures 2, 3, 13, 14 & 15; Tables 2 & 3) Holotype: ZSI/ WGRC /V/A/ 881 (CESF 1276), a male (SVL 21.0 mm), collected by S.P. Vijayakumar and Mayavan June 2011 from a grassland site (11.2331 N, 76.5443 E), Nilgiri Massif (Fig 1), Western Ghats, Peninsular India. Paratype: ZSI/ WGRC /V/A/ 882 (CESF 441), a male (SVL 19.9 mm), collected by S.P. Vijayakumar, August 2009 from a grassland site (11.2331 N, 76.5443 E), Nilgiri Massif (Fig 1), Western Ghats, Peninsular India. Lineage diagnosis. Raorchestes primarrumpfi sp. nov. can be phylogenetically diagnosed as belonging to the Tinniens clade (Fig 3), showing a well supported sister relationship with an another unidentified lineage occurring in sympatry. Despite its shallow genetic divergence (1���2 % on 16 S gene) from its sympatric sister lineage, it exhibits high divergence in morphological characteristics both in the multivariate morphological space (Fig 14) as well in the dorsal and ventral coloration (Fig 13). Iris coloration and patterns (Fig 13 (b)) were also found to show distinct differences from its sister lineage. Field diagnosis. Raorchestes primarrumpfi sp. nov. can be distinguished from the related congeners by the following combination of characters. Morphology. Raorchestes primarrumpfi sp. nov. can be distinguished by its (1) shorter tibia length (ShL/ SVL= 0.32 (0.31���0.35, n= 5) (vs. ShL/SVL= 0.45 (0.43���46, n= 3) in the unidentified lineage and ShL/SVL= 0.41 (0.41���42, n= 3) in R. tinniens); (2) shorter thigh length (TL/SVL = 0.35, n= 5) (vs. TL/SVL= 0.45, n= 3 in the unidentified lineage and TL/SVL= 0.44, n= 3 in R. tinniens); (3) smaller size (males) (SVL= 20 (18.4 ���21.0, n= 5) (vs. 22 (21���22.8, n= 3) in the unidentified lineage); (4) shorter head length (HL/SVL= 0.26 (0.24���0.28, n= 5) (vs. 0.37 (0.35���0.38, n= 3) in R. tinniens; (5) shorter snout length (SL/SVL= 0.11 (0.10���0.13, n= 5) (vs. 0.15, n= 3) in the unidentified lineage); (6) unique iris coloration, lower part dark maroon and upper half speckled with iridescent golden and silvery colour (vs. uniform brown in the unidentified lineage and uniform brown with golden speckles in R. tinniens; (7) dorsum largely granular, dark olive and with a consistent pattern of three distinct maroon longitudinal discontinuous stripes (vs. highly variable dorsum coloration with no distinct pattern in the related lineages); (8) two distinct maroon blotches on the eyelids extending slightly into inter-orbital space (vs. absent in the other lineages) (9) ventral coloration is white with a bluish wash towards sides (vs. shades of yellow, areolate skin, semi-transparent with yellow blotches in some individuals and shades of yellow with black spots in R. tinniens (Biju and Bossuyt 2009)). Geography. Restricted in range to the very high elevations of the Nilgiri Massif (see natural history and distribution for details). Overlaps broadly in its geographical range with an unidentified lineage and R. signatus. Ecology. Observed to be restricted to grasslands and swamps. Description of holotype (all measurements in mm). A small sized squat bush frog (SVL = 21.0 mm), width of head broader than head length (HW = 7.5 mm; HL = 5.5 mm), arched, flat dorsally; snout rounded in total profile, slightly protruding beyond mouth. Snout length is equal to diameter of eye (SL = 2.5 mm, EL = 2.4 mm). Canthus rostralis rounded, loreal region slightly concave. Interorbital space (IUE = 2.2 mm) flat and sub equal to upper eyelid (UEW = 1.8 mm). Interorbital space between posterior margins of the eyes 1.9 times that of anterior margins (IFE = 3.5, IBE = 6.6 mm). Nostrils oval, nearer to tip of snout. Weak symphysial knob. Pupil horizontal. Tympanum indistinct. Tongue bifid, granular with a papilla. Supratympanic fold from behind eye to shoulder. Relative length of fingers IColor in life. Dorsum, background olive with a dark maroon longitudinal disconnected striped pattern, the pattern extending on to outer two fingers on the forelimb and femur, tibia, tarsus and outer toe on the hind limb. Canthus ridge darker extending to the tip of snout and flesh coloured, with olive patches, in a few individuals. Laterally, behind shoulders a distinct flesh coloured patch hidden in resting position; bluish white small blotches along the lateral sides and distinct blotches towards groin and anterior femur on a maroon background, this pattern is variable across individuals. Ventrally white, with a light bluish wash towards lateral edges. Ventral parts of tibia and tarsus with elongated white patches on a fleshy background. Iris, lower 1 / 3 rd dark maroon, upper half speckled with iridescent golden and silvery colour and outer posterior orbital ring blue. Etymology. Derived and modified from ��� Primarrumpf���, a German term used by geomorphologists to refer to remnant primitive surfaces of Gondwanaland. In the Western Ghats Escarpment, these surfaces occur in the Nilgiri and Anaimalai massifs. Natural history and distribution. All the calling males were observed amidst dense grass clumps and herbs in the montane grasslands and the detection of this species was higher in swampy grasslands (Fig 15). It exhibits a narrow geographical range and is restricted in distribution to the montane zone (2212���2359 m, n= 13) towards the western edge of the Nilgiri Massif (Fig 1 & 2). The higher elevations of the Camels Hump Massif, adjacent to the Nilgiri Massif, might hold a relative of this lineage and needs further exploration. Sl. No Species 1 Raorchestes agasthyaensis Zachariah, Dinesh, Kunhikrishnan, Das, Raju, Radhakrishnan, Palot and Kalesh, 2011 2 Raorchestes akroparallagi (Biju and Bossuyt, 2009) 3 Raorchestes anili (Biju and Bossuyt, 2006) 4 Raorchestes archaeos sp. nov. 5 Raorchestes aureus sp. nov. 6 Raorchestes beddomii (Gunther, 1876) 7 Raorchestes blandus sp. nov. 8 Raorchestes bobingeri (Biju and Bossuyt, 2005) 9 Raorchestes bombayensis (Annandale, 1919) 10 Raorchestes chalazodes (Gunther, 1876) 11 Raorchestes charius (Rao, 1937) 12 Raorchestes chlorosomma (Biju and Bossuyt, 2009) 13 Raorchestes chotta (Biju and Bossuyt, 2009) 14 Raorchestes chromasynchysi (Biju and Bossuyt, 2009) 15 Raorchestes coonoorensis (Biju and Bossuyt, 2009) 16 Raorchestes crustai Zachariah, Dinesh, Kunhikrishnan, Das, Raju, Radhakrishnan, Palot and Kalesh, 2011 17 Raorchestes dubois (Biju and Bossuyt, 2006) 18 Raorchestes echinatus sp. nov. 19 Raorchestes emeraldi sp. nov. 20 Raorchestes flaviventris (Boulenger, 1882) * 21 Raorchestes flaviocularis sp. nov. 22 Raorchestes ghatei Padhye, Sayyed, Jadhav and Dahanukar, 2013 23 Raorchestes glandulosus (Jerdon, 1853) 24 Raorchestes graminirupes (Biju and Bossuyt, 2005) 25 Raorchestes griet (Bossuyt, 2002) 26 Raorchestes hassanensis (Rao, 1937) # 27 Raorchestes indigo sp. nov. 28 Raorchestes jayarami (Biju and Bossuyt, 2009) 29 Raorchestes johnceei Zachariah, Dinesh, Kunhikrishnan, Das, Raju, Radhakrishnan, Palot and Kalesh, 2011 30 Raorchestes kadalarensis Zachariah, Dinesh, Kunhikrishnan, Das, Raju, Radhakrishnan, Palot and Kalesh, 2011 31 Raorchestes kaikatti (Biju and Bossuyt, 2009) 32 Raorchestes kakachi Seshadri, Gururaja and Aravind, 2012 33 Raorchestes leucolatus sp. nov. 34 Raorchestes luteolus (Kuramoto and Joshy, 2003) 35 Raorchestes manohari Zachariah, Dinesh, Kunhikrishnan, Das, Raju, Radhakrishnan, Palot and Kalesh, 2011 36 Raorchestes marki (Biju and Bossuyt, 2009) 37 Raorchestes montanus (Jerdon, 1875) # ......continued on the next page Sl. No Species 38 Raorchestes munnarensis (Biju and Bossuyt, 2009) 39 Raorchestes nerostagona (Biju and Bossuyt, 2005) 40 Raorchestes ochlandrae (Gururaja, Dinesh, Palot, Radhakrishnan and Ramachandra, 2007) 41 Raorchestes ponmudi (Biju and Bossuyt, 2005) 42 Raorchestes primarrumpfi sp. nov. 43 Raorchestes ravii Zachariah, Dinesh, Kunhikrishnan, Das, Raju, Radhakrishnan, Palot and Kalesh, 2011 44 Raorchestes resplendens Biju, Shouche, Dubois, Dutta and Bossuyt, 2010 45 Raorchestes signatus (Boulenger, 1882) 46 Raorchestes sushili (Biju and Bossuyt, 2009) 47 Raorchestes theuerkaufi Zachariah, Dinesh, Kunhikrishnan, Das, Raju, Radhakrishnan, Palot and Kalesh, 2011 48 Raorchestes thodai Zachariah, Dinesh, Kunhikrishnan, Das, Raju, Radhakrishnan, Palot and Kalesh, 2011 * 49 Raorchestes tinniens (Jerdon, 1853) 50 Raorchestes travancoricus (Boulenger, 1891) 51 Raorchestes tuberohumerus (Kuramoto and Joshy, 2003) 52 Raorchestes uthamani Zachariah, Dinesh, Kunhikrishnan, Das, Raju, Radhakrishnan, Palot and Kalesh, 2011 * species not included in the phylogenetic tree; # details of revalidation will be dealt elsewhere (under preparation), Published as part of Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V. & Shanker, Kartik, 2014, Lineage delimitation and description of nine new species of bush frogs (Anura: Raorchestes, Rhacophoridae) from the Western Ghats Escarpment, pp. 451-488 in Zootaxa 3893 (4) on pages 479-484, DOI: 10.11646/zootaxa.3893.4.1, http://zenodo.org/record/287578, {"references":["Biju, S. D & Bossuyt, F. (2009) Systematics and phylogeny of Philautus Gistel, 1848 (Anura, Rhacophoridae) in the Western Ghats of India, with descriptions of 12 new species. Zoological Journal of the Linnean Society, 155, 374 - 444. http: // dx. doi. org / 10.1111 / j. 1096 - 3642.2008.00466. x","Zachariah, A., Dinesh, K. P., Kunhikrishnan, E., Das, S., Raju, D., Radhakrishnan, C., Palot, M. J. & Kalesh, S. (2011) Nine new species of frogs of the genus Raorchestes (Amphibia: Anura: Rhacophoridae) from southern Western Ghats, India. BioSystematica, 5 (1), 25 - 48.","Biju, S. D. & Bossuyt, F. (2006) Two new species of Philautus (Anura, Ranidae, Rhacophorinae) from the Western Ghats, India. Amphibia-Reptilia, 27, 1 - 9. http: // dx. doi. org / 10.1163 / 156853806776051985","Annandale, N. (1919) The fauna of certain small streams in the Bombay Presidency: Some frogs from streams in the Bombay Presidency. Records of the Indian Museum, 16, 109 - 161.","Rao, C. R. N. (1937) On some new forms of Batrachia from South India. Proceedings of Indian Academy of Sciences, 6, 387 - 427.","Padhye, A., Sayyed, A., Jadhav, A. & Dahanukar, N. (2013) Raorchestes ghatei, a new species of shrub frog (Anura: Rhacophoridae) From the Western Ghats of Maharashtra, India. Journal of Threatened Taxa, 5, 4913 - 4931. http: // dx. doi. org / 10.11609 / jott. o 3702.4913 - 31","Seshadri, K., Gururaja, K. & Aravind, N. (2012) A new species of Raorchestes (Amphibia: Anura: Rhacophoridae) from midelevation evergreen forests of the southern Western Ghats, India. Zootaxa, 3410, 19 - 34.","Kuramoto, M. & Joshi, S. H. (2003) Two new species of the genus Philautus (Anura: Rhacophoridae) from the Western Ghats, Southwestern India. Current Herpetology, 22, 51 - 60. http: // dx. doi. org / 10.5358 / hsj. 22.51","Gururaja, K. V., Dinesh, K. P., Palot, M. J., Radhakrishnan, C. & Ramachandra, T. V. (2007) A new species of Philautus Gistel (Amphibia: Anura: Rhacophoridae) from southern Western Ghats, India. Zootaxa, 1621, 1 - 16.","Biju, S. D, Shouche, Y., Dubois, A., Dutta, S. & Bossuyt, F. (2010) A ground-dwelling rhacophorid frog from the highest mountain peak of the Western Ghats of India. Current Science, 98, 1119 - 1125.","Boulenger, G. (1891) Description of a new species of frog obtained by Mr. HS Ferguson in Travancore, South India. Journal of Bombay Natural History Society, 6, 450."]}

Published

2014

141. Raorchestes leucolatus Vijayakumar, Dinesh, Prabhu & Shanker, 2014, sp. nov

Author

Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V., and Shanker, Kartik

Subjects

Amphibia, Rhacophoridae, Raorchestes leucolatus, Raorchestes, Animalia, Biodiversity, Anura, Chordata, Taxonomy

Abstract

8. Raorchestes leucolatus sp. nov. (Figures 2, 3 & 12; Tables 2 & 3) Holotype: ZSI/ WGRC /V/A/ 879 (CESF 1146), an adult male (SVL 16.9 mm), collected by S.P. Vijayakumar, Mrugank V. Prabhu and and Mayavan in July 2010 from a wet evergreen forest site (10.9731 N, 76.6289 E), Elivalmalai Massif (Fig 1), Peninsular India. Paratype: ZSI/ WGRC /V/A/ 880 (CESF 1147), an adult male (SVL 17.1 mm), collected by S.P. Vijayakumar, Mrugank V. Prabhu and Mayavan in July 2010 from a wet evergreen forest site (10.9731 N, 76.6289 E), Elivalmalai Massif (Fig 1), Western Ghats, Peninsular India. Lineage diagnosis. Raorchestes leucolatus sp. nov. can be diagnosed by its phylogenetic position within the Bombayensis clade (Fig 3) and exhibits moderate levels (16 S��� 2.9 %) of divergence from its closest relative R. tuberohumerus. It also shows strong differences in morphology (Fig 12 a,d,e,f). The lineage is diagnosed based on its phylogenetic position, genetic divergence and morphological distinctness. Field diagnosis. Morphology. Raorchestes leucolatus sp. nov. could be morphologically confused with its close relative R. tuberohumerus. However, it can be distinguished from R. tuberohumerus on many aspects of morphology. Raorchestes leucolatus sp. nov. can be distinguished by its smaller size (males) 16.9 mm (16.2���17.1, n= 4) (vs. 18.4 mm (17.7 ���19.0, n= 6) in R. tuberohumerus); head width, HW/SVL= 0.38 (0.37���0.39, n= 4) greater than head length, HL/SVL= 0.29 (0.28���0.31, n= 4) (vs. HW/SVL= 0.35 (0.33���0.36, n= 6) almost equal to head length (HL/SVL= 0.37 (0.36���0.40, n= 6) in R. tuberohumerus); shorter thigh length, TL/SVL= 0.45 (0.43���0.46, n= 4) (vs. TL/SVL= 0.50 (0.46���0.52, n= 6) in R. tuberohumerus); shorter foot length, FOL/SVL= 0.36 (0.35���0.36, n= 4) (vs. FOL/SVL= 0.40 (0.37���0.43) in R. tuberohumerus); groin region with white blotches (vs. groin region with yellow blotches in R. tuberohumerus; disc colour orange (vs. disc colour grey to brown in R. tuberohumerus). Geography. Found to be restricted to the mid-elevations of Elivalmalai Massif (see natural history and distribution for details). Ecology. Found to be an understory forest species (n= 4) and was observed in short grasses and shrubs along the forest edges. Description of holotype (all measurements in mm). A small sized bush frog (SVL = 16.9 mm), width of head sub equal to head length (HW = 6.2 mm; HL = 5.2 mm), flat dorsally; snout acutely pointed in total profile, slightly protruding beyond mouth. Snout length is sub equal to diameter of eye (SL = 2.2 mm, EL = 2.3 mm). Canthus rostralis angular, loreal region flat. Interorbital space (IUE = 2.1 mm) flat and sub equal to upper eyelid (UEW = 1.5 mm). Interorbital space between posterior margins of the eyes 1.7 times that of anterior margins (IFE = 3.5, IBE = 5.8 mm). Nostrils oval, nearer to tip of snout. Weak symphysial knob. Eyes small, pupil horizontal. Tympanum indistinct, rounded, barely visible behind the eye. Tongue bifid, granular without papilla. Supratympanic fold from behind eye to shoulder. Relative length of fingers IColor in life. Dorsum maroon with a pair of distinct orange patch on the shoulder. An orange coloured horizontal broken band between the upper eyelids. Groin with distinct white blotches, ventrally varying shades of brown with irregular white spots on the belly. Throat darker towards lips, disks on finger and toes distinctly orange. Iris coarsely speckled with varying shades of golden brown, overlaid on an irregular brown markings. Distinct rufous edged speckles around the pupil (Fig 12 (b)). Etymology. The species is named after one of its distinct characteristics, the ���white patch��� on the groin (Greek: leukos = white). Natural history and distribution. The species was discovered in the mid elevations (894���958 m, n= 2) and was observed at forested sites in the Elivalmalai Massif (Fig 1 & 2) situated north of Palghat Gap. Currently there are no reports of any allied species from north of its range. The southern most range of R. tuberohumerus, its geographically closest relative, appears to be Wayanad plateau (Fig 1). Further surveys are needed to verify the occurrence of this species or any close relatives in the lower elevations of Nilgiri Massif., Published as part of Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V. & Shanker, Kartik, 2014, Lineage delimitation and description of nine new species of bush frogs (Anura: Raorchestes, Rhacophoridae) from the Western Ghats Escarpment, pp. 451-488 in Zootaxa 3893 (4) on pages 477-479, DOI: 10.11646/zootaxa.3893.4.1, http://zenodo.org/record/287578

Published

2014

142. Lineage delimitation and description of nine new species of bush frogs (Anura: Raorchestes, Rhacophoridae) from the Western Ghats Escarpment

Author

Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V., and Shanker, Kartik

Subjects

Amphibia, Rhacophoridae, Animalia, Biodiversity, Anura, Chordata, Taxonomy

Abstract

Vijayakumar, S. P., Dinesh, K. P., Prabhu, Mrugank V., Shanker, Kartik (2014): Lineage delimitation and description of nine new species of bush frogs (Anura: Raorchestes, Rhacophoridae) from the Western Ghats Escarpment. Zootaxa 3893 (4): 451-488, DOI: http://dx.doi.org/10.11646/zootaxa.3893.4.1

Published

2014

143. Eco-friendly synthesis of gold nanoparticles using fruit extracts and in vitro anticancer studies.

Author

Vijayakumar, S.

Abstract

Gold nanoparticles are biocompatible and are having several applications in biomedical Sciences and Engineering. Integration of nanoscience in medicine leads to the development of biomedical products that helps the Society in a faster and safer manner. In the present research work, bioreduction and biofunctionalization of gold nanoparticles are performed with fruit extracts of Aegle marmelos , Eugenia jambolana and soursop. The nanoparticles are characterized using UV–Vis spectroscopy, Transmission Electron Microscopy, Fourier Transform Infrared Spectroscopy and Zeta potentiometer. The qualitative phytochemical analysis of the fruit extracts shows the presence of alkaloids, amino acid, flavonoids, phenol, proteins, tannin, reducing sugars and total Sugars. The in vitro anticancer activity was confirmed by MTT assay on the human breast cancer cell line MCF-7 at different concentrations. The flavonoids present in the fruit extracts are potential reducing agent which is responsible for the formation of gold nanoparticles. Stabilization of gold nanoparticles are performed by the carboxylate group present in the proteins. Also, the nanoparticles are held apart from each other by the electrostatic repulsions that exist due to the presence of like charges surrounding the gold nanoparticles. This study proves that the fruit extracts can be used for the synthesis and stabilization of gold nanoparticles. Further, the engineered nanoparticles capped with bioactive compounds are potential anticancer agents against breast cancer cell line MCF-7. [ABSTRACT FROM AUTHOR]

Published

2019

144. Effect of side chain edge functionalization in pristine and defected graphene-DFT study.

Author

Anithaa, V.S. and Vijayakumar, S.

Subjects

ELECTRIC properties of graphene, SUBSTITUENTS (Chemistry), DENSITY functional theory, POLYACETYLENES, HYDROGEN atom

Abstract

The structural and electronic properties of edge-functionalized graphene sheets are systematically investigated utilizing Density Functional Theory (DFT). The functionalization includes alkyl, alkene, and seven different polyacetylene side chains as an alternative for a hydrogen atom in eight different kinds of graphene sheets. CH 3 and longer side chains functionalization have high stability and remains unaffected by increasing the size of the graphene sheet. The weak binding energy and large formation energy are observed for CH 2 , C 3 H 4 and C 5 H 6 functionalization in all eight different kinds of the graphene sheet. The high charge transfer from graphene to side chain having high σ bonds is interpreted by Voronoi deformation density (VDD) method. The delocalization of the graphene ring decreases in side chain functionalization and gets decreased further when the size of the graphene sheet is increased. The high alteration in aromaticity is illustrated by decrease in Para Delocalization Index (PDI) value with an increase in aromatic Fluctuation Index (FLU) value in weakly binded side chains. The decrease in Highest Occupied Molecular Orbital (HOMO) along with a decrease in band gap on the substitution of nine different side chains in both pristine and defected sheet is observed. Moreover, the decrease in electron accepting ability is observed for CH 3 , C 3 H 5 and C 5 H 7 functionalization in all kinds of graphene sheets, which is inferred from the decrease in Lowest Unoccupied Molecular Orbital (LUMO). [ABSTRACT FROM AUTHOR]

Published

2018

145. Scavenging ratio of black carbon in the Arctic and the Antarctic.

Author

Gogoi, Mukunda M., Babu, S. Suresh, Pandey, Santosh K., Nair, Vijayakumar S., Vaishya, Aditya, Girach, I.A., and Koushik, N.

Subjects

SOOT, CHEMICAL scavengers, ATMOSPHERIC aerosols & the environment, ENVIRONMENTAL monitoring, CRYOSPHERE

Abstract

Long-term monitoring of atmospheric aerosols and their interaction with radiation, cloud, and cryosphere over the Arctic and the Antarctic are very important for the global climate change related issues. In this regard, for conducting aerosol measurements, India has extended the concerted efforts to the Svalbard region of the Norwegian Arctic (Himadri, 78°55′N 11°56′E, 8 m a.s.l.) in the northern hemisphere and the Larsemann Hills of coastal Antarctic (Bharati, 69°24.4′S 76°11.7′E, 40 m a.s.l.) in the southern hemisphere. In the present study, we have examined the role of black carbon (BC) deposition in darkening the polar snow in different sunlit seasons and estimated the scavenging ratio of BC over both the poles from simultaneous measurements of atmospheric and snow deposited BC concentrations. The study reveals distinct spatio-temporal variability of BC in polar snow, even though the concentrations are, in general, low (<12 ppbw, parts per billion by weight). During local summer seasons, the BC in snow at the Arctic (median ∼ 7.98 ppbw) was higher than that at the Antarctica (median ∼ 1.70 ppbw). Concurrent with this, the scavenging ratio (SR) also showed large variability over both the poles. Relatively higher values of SR over the Antarctica (mean ∼ 119.54 ± 23.04; during southern hemispheric summer) in comparison to that over the Arctic (mean ∼ 69.48 ± 4.79; during northern hemispheric spring) clearly indicate the difference in removal mechanisms (aerosol mixing, aging and size distribution) of BC from the atmosphere over distinct polar environments. Measurement of spectral incoming and reflected radiances over the Arctic snow during the early spring season of 2017 indicated the values of surface broadband albedo varying between 0.64 and 0.79. The Snow, Ice and Aerosol Radiative (SNICAR) model simulated values of spectral albedo correlated well with the measured ones and indicated the role of dust absorption, in addition to that of BC, in changing the snow albedo. This information needs to be accurately incorporated in the radiative transfer models for the accurate estimation of snow albedo forcing over the Polar Regions. [ABSTRACT FROM AUTHOR]

Published

2018

146. Anti-diabetic activity of quercetin extracted from Phyllanthus emblica L. fruit: In silico and in vivo approaches.

Author

Srinivasan, Prabhu, Vijayakumar, S., Kothandaraman, Swaminathan, and Palani, Manogar

Subjects

PROTEIN-protein interactions, INTERMOLECULAR interactions, MOLECULAR docking, STREPTOZOTOCIN, MOLECULAR dynamics, PHYSIOLOGY

Abstract

In this study, molecular interactions of the ligands, quercetin, gallic acid, and metformin with various diabetes mellitus-related protein targets, such as glycogen phosphorylase and peroxisome proliferator-activated receptor gamma, were assessed. It was revealed that quercetin possesses good binding affinity to both targets. Quercetin is a major constituent of methanolic extracts of Phyllanthus emblica fruit. The antihyperglycemic effect of quercetin in streptozotocin (STZ)-induced diabetic rats was examined. The isolated quercetin administered at a dose of 75 mg/kg body weight produced a maximum decrease of 14.78% in blood glucose levels in the diabetic rats after 7 days of treatment. Furthermore, quercetin doses of 50 and 75 mg/kg were shown to significantly improve the profiles of triglycerides, high-density lipoprotein, very-low-density lipoprotein, low-density lipoprotein, and total cholesterol at the end of the study in STZ-induced diabetic rats. The administration of quercetin (25, 50, and 75 mg/kg body weight) daily for 28 days in STZ-induced diabetic rats resulted in a significant decrease in blood glucose and urine sugar levels, with a considerable rise in plasma insulin and hemoglobin levels. Therefore, quercetin is a potential drug with antidiabetic and antihyperglycemic action mediated by changes in the levels of glucose, cholesterol, and triglycerides as indicated by in silico and in vivo studies. [ABSTRACT FROM AUTHOR]

Published

2018

147. Structural exploration of viral matrix protein 40 interaction with the transition metal ions (Ag+and Cu2+)

Author

Saranya, V., Shankar, R., and Vijayakumar, S.

Abstract

AbstractHere, a theoretical and comprehensive study of the structural features and interaction properties of viral protein 40 is being briefed out to understand the mechanism of Ebola virus (EV) with structural and orbital analysis. In general, viral protein 40 is the key protein for the oligomerization, the N-terminal loop region in the viral protein 40 and it is essential for the viral replication in Ebola. The electronic structures of native N-terminal loop (His124-Asn134) and metalized (Mn+=Ag+and Cu2+) complexes are optimized at the M06-2X/LANL2DZ level of theory. Among Mn+-interacted N-loop complexes, Cu2+-interacted N-terminal loop complex has the highest interaction energy of –973.519 kcal/mol and also it has the stabilization energy in the range of 9.92 kcal/mol. The cation-π interactions between His124, Pro131 and Arg134 residues are the important factor, which enhances the interaction energy of viral protein 40. Due to the chelation behavior of metal ions, the backbone and the side chains of N-terminal loop regions are deviated from the planarity that results in the formation of classical hydrogen bonds between N-terminal loop regions. Molecular dynamics simulation studies also revealed that the structural transformations of Nloop into a stable α-helix and β-sheet folded conformations due to the interaction of Ag+and Cu2+ions in the N-terminal loop region. The hydrogen bond formation and hydrophobic interactions are responsible for the stability and structural changes in N-terminal loop region. Therefore, it is clear that interaction of metal ion with viral protein-40 reduces the replication of the disease by inducing the secondary structural changes.Communicated by Ramaswamy H. Sarma

Published

2019

148. A milestone in prediction of the coronary artery dimensions from the multiple linear regression equation

Author

Divia Paul, A., Ashraf, S.M., Ezhilan, J., Vijayakumar, S., and Kapadiya, Anuj

Abstract

Coronary artery imaging is one of the most commonly used diagnostic methods. We aimed to investigate whether there is a correlation between left main coronary artery (LMCA), left anterior descending artery (LAD) and left circumflex artery (LCx) artery dimensions in normal cases and a possibility to express the coronary dimensions by multiple linear equations.

Published

2019

149. Modeling of the Effects of Wintertime Aerosols on Boundary Layer Properties Over the Indo Gangetic Plain

Author

Bharali, Chandrakala, Nair, Vijayakumar S., Chutia, Lakhima, and Babu, S. Suresh

Abstract

Wintertime fog and severe aerosol loading in the boundary layer over South Asia, especially Indo Gangetic Plain (IGP), causes disruptions in the day‐to‐day life of millions of people living in the region, and these heavy pollution episodes result in relentless effects on human health. Weather Research Forecasting model coupled with aerosol chemistry is used to investigate the radiative effects and feedbacks of aerosols on the evolution and structure of the planetary boundary layer over the region. In general, aerosols lead to cooling at the surface, which decreases the nonradiative fluxes (latent and sensible heat fluxes), weakens the turbulent diffusion, and inhibits/delays the growth of convective boundary layer. The impact was maximum over IGP where aerosol‐induced solar dimming (60–80 W/m2) led to a cooling of −0.6 to −2 ° C at the surface, which decreases the noontime boundary layer height by ∼200 m. This effect overwhelms the diabatic heating due to absorbing aerosols in the atmosphere. The significant decrease in sensible (∼11–23 W/m2) and latent heat flux (5–14 W/m2) was observed over IGP and western India. Aerosol boundary layer interaction increases the aerosol loading near the surface (PM2.5) by 3 to 30 μg/m3, which further deteriorate the air quality and visibility over the region. The aerosol forcing increases the relative humidity in the lower boundary layer and amplifies the aerosol forcing. The fog events over the Indian regions identified using INSAT‐3D observations coincide with the regions where aerosol‐boundary layer interactions are very significant. The aerosol‐boundary layer interaction has significance in forecasting fog events and planning mitigation strategies for improving the air quality over the region. Aerosol‐boundary layer interaction is one of the major forcing mechanism affecting air quality over South Asia during winterAerosol forcing decreases the boundary layer height, heat fluxes, and surface temperature significantlyAerosol‐boundary layer interaction leads to the accumulation of pollutants and thus favors fog events

Published

2019

150. Microwave assisted green synthesis of Hydroxyapatite nanorods using Moringa oleiferaflower extract and its antimicrobial applications

Author

Kalaiselvi, V., Mathammal, R., Vijayakumar, S., and Vaseeharan, B.

Abstract

[Display omitted]

Published

2018