Your search keyword '"Jiménez Valverde, Alberto"' showing total 200 results

1. Differing sensitivity of species distribution modelling algorithms to climate data source

Author

Rodríguez-Rey, Marta and Jiménez-Valverde, Alberto

Published

2024

2. Sample size for the evaluation of presence-absence models

Author

Jiménez-Valverde, Alberto

Published

2020

3. Dispersal limitation shapes distance‐decay patterns of European spiders at the continental scale

Author

Martín‐Devasa, Ramiro, primary, Jiménez‐Valverde, Alberto, additional, Leprieur, Fabien, additional, Baselga, Andrés, additional, and Gómez‐Rodríguez, Carola, additional

Published

2024

4. Dispersal limitation shapes distance‐decay patterns of European spiders at the continental scale

Author

Martín‐devasa, Ramiro, Jiménez‐valverde, Alberto, Leprieur, Fabien, Baselga, Andrés, Gómez‐rodríguez, Carola, Martín‐devasa, Ramiro, Jiménez‐valverde, Alberto, Leprieur, Fabien, Baselga, Andrés, and Gómez‐rodríguez, Carola

Abstract

AimTo assess the relative relevance of dispersal limitation and species sorting as drivers of spatial turnover between spider faunas of European territories. LocationContinental Europe. Time periodPresent. Major taxa studiedSpiders (Order Araneae). MethodsWe analysed how distance‐decay patterns differ between northern and southern Europe (broadly, territories covered vs. not covered by ice sheets during the last glacial maximum, respectively) in 15 spider families, using standardized distances to allow a direct comparison between parameters (i.e. slope and intercept) of climatic and spatial distance‐decay models. Thus, we assessed North–South differences in parameters of spatial and, independently, climatic distance‐decay models, and whether those differences are explained by family‐specific traits related to dispersal ability. ResultsClimatic and spatial distance‐decay patterns are very similar in northern Europe, where climatic and spatial distances are highly correlated. In contrast, slopes are steeper in spatial than in climatic distance‐decay curves in southern Europe, where climatic and spatial distances are decoupled. Moreover, family traits related to dispersal ability explained the North–South difference in spatial distance‐decay slopes, as well as the amount of nestedness‐resultant dissimilarity between southern and northern spider faunas. Main conclusionsOur results suggest that differences in beta diversity patterns between northern and southern Europe reflect the strength of dispersal limitation in spiders, which varies across families and leads to different degrees of disequilibrium with current climatic conditions depending on the taxon. Moreover, in the South of Europe, where spatial and climatic distances are uncorrelated, spatial distance‐decay models are steeper and have larger explanatory power than climatic distance‐decay models, which suggests that dispersal limitation is the main factor shaping current beta diversity patterns of European spide

Published

2024

5. Dispersal limitation shapes distance‐decay patterns of European spiders at the continental scale

Author

Universidade de Santiago de Compostela. Departamento de Bioloxía Funcional, Universidade de Santiago de Compostela. Departamento de Zooloxía, Xenética e Antropoloxía Física, Universidade de Santiago de Compostela. Instituto Interdisciplinar de Tecnoloxías Ambientais (CRETUS), Martín Devasa, Ramiro María, Jiménez Valverde, Alberto, Leprieur, Fabien, Baselga Fraga, Andrés, Gómez Rodríguez, Carola, Universidade de Santiago de Compostela. Departamento de Bioloxía Funcional, Universidade de Santiago de Compostela. Departamento de Zooloxía, Xenética e Antropoloxía Física, Universidade de Santiago de Compostela. Instituto Interdisciplinar de Tecnoloxías Ambientais (CRETUS), Martín Devasa, Ramiro María, Jiménez Valverde, Alberto, Leprieur, Fabien, Baselga Fraga, Andrés, and Gómez Rodríguez, Carola

Abstract

Aim To assess the relative relevance of dispersal limitation and species sorting as drivers of spatial turnover between spider faunas of European territories. Location Continental Europe. Time period Present. Major taxa studied Spiders (Order Araneae). Methods We analysed how distance-decay patterns differ between northern and southern Europe (broadly, territories covered vs. not covered by ice sheets during the last glacial maximum, respectively) in 15 spider families, using standardized distances to allow a direct comparison between parameters (i.e. slope and intercept) of climatic and spatial distance-decay models. Thus, we assessed North–South differences in parameters of spatial and, independently, climatic distance-decay models, and whether those differences are explained by family-specific traits related to dispersal ability. Results Climatic and spatial distance-decay patterns are very similar in northern Europe, where climatic and spatial distances are highly correlated. In contrast, slopes are steeper in spatial than in climatic distance-decay curves in southern Europe, where climatic and spatial distances are decoupled. Moreover, family traits related to dispersal ability explained the North–South difference in spatial distance-decay slopes, as well as the amount of nestedness-resultant dissimilarity between southern and northern spider faunas. Main conclusions Our results suggest that differences in beta diversity patterns between northern and southern Europe reflect the strength of dispersal limitation in spiders, which varies across families and leads to different degrees of disequilibrium with current climatic conditions depending on the taxon. Moreover, in the South of Europe, where spatial and climatic distances are uncorrelated, spatial distance-decay models are steeper and have larger explanatory power than climatic distance-decay models, which suggests that dispersal limitation is the main factor shaping current beta diversity patterns of Europea

Published

2024

6. Niche segregation in Iberian Argiope species

Author

Pe˜na-Aguilera, Pablo, Burguillo-Madrid, Lidia, Barve, Vijay, Aragón, Pedro, and Jiménez-Valverde, Alberto

Published

2019

7. Differing sensitivity of species distribution modelling algorithms to climate data source

Author

Rodríguez-Rey, Marta, primary and Jiménez-Valverde, Alberto, additional

Published

2023

8. How Does the Knowledge about the Spatial Distribution of Iberian Dung Beetle Species Accumulate over Time?

Author

Lobo, Jorge M., Hortal, Joaquín, and Jiménez-Valverde, Alberto

Published

2007

9. Limitations of Biodiversity Databases: Case Study on Seed-Plant Diversity in Tenerife, Canary Islands

Author

Hortal, Joaquín, Lobo, Jorge M., and Jiménez-Valverde, Alberto

Published

2007

10. DETERMINING A COMBINED SAMPLING PROCEDURE FOR A RELIABLE ESTIMATION OF ARANEIDAE AND THOMISIDAE ASSEMBLAGES (ARACHNIDA, ARANEAE)

Author

Jiménez-Valverde, Alberto, Lobo, Jorge M, and BioStor

Published

2005

11. opinion: Relationship between local population density and environmental suitability estimated from occurrence data

Author

Jiménez‐Valverde, Alberto

Published

2011

12. Life in darkness: an overview of cave-adapted japygids (Hexapoda, Diplura)

Author

Sendra, Alberto, primary, Sánchez-García, Alba, additional, Hoch, Hannelore, additional, Jiménez-Valverde, Alberto, additional, Selfa, Jesús, additional, Moutaouakil, Soumia, additional, Du Preez, Gerhard, additional, Millar, Ian, additional, and Ferreira, Rodrigo Lopes, additional

Published

2023

13. Life in darkness: an overview of cave-adapted japygids (Hexapoda, Diplura)

Author

Sendra, Alberto, Sánchez-García, Alba, Hoch, Hannelore, Jiménez-Valverde, Alberto, Selfa, Jesús, Moutaouakil, Soumia, Du Preez, Gerhard, Millar, Ian, Ferreira, Rodrigo Lopes, Sendra, Alberto, Sánchez-García, Alba, Hoch, Hannelore, Jiménez-Valverde, Alberto, Selfa, Jesús, Moutaouakil, Soumia, Du Preez, Gerhard, Millar, Ian, and Ferreira, Rodrigo Lopes

Abstract

Few species of Japygidae (Diplura) have been discovered in cave ecosystems despite their importance as large predators. A small collection of rare specimens of this hexapod group has allowed to explore the taxonomy of japygids from caves in New Zealand, Morocco and South Africa, and to describe one new genus: Imazighenjapyx Sendra & Sánchez-García gen. nov., as well as four new species: Austrjapyx wynbergensis Sendra & Sánchez-García sp. nov., Imazighenjapyx marocanus Sendra & Sánchez-García gen. et sp. nov., Opisthjapyx naledi Sendra & Sánchez-García sp. nov. and Teljapyx aotearoa Sendra & Sánchez-García sp. nov. For each of the new taxa we give a comprehensive description of their habitats. These new findings resulted in a revision of the distribution and allowed to re-evaluate the morphological traits of the fifteen cave-adapted japygids species already known worldwide. The functional morphology of the remarkable abdominal pincers of Japygidae and their adaptation to predation are discussed, as well as their potential role in mating behaviour.

Published

2023

14. Environmental favourability as a cost-efficient tool to estimate carrying capacity

Author

Muñoz, Antonio-Román, Jiménez-Valverde, Alberto, Márquez, Ana Luz, Moleón, Marcos, and Real, Raimundo

Published

2015

15. Species distribution models predict range expansion better than chance but not better than a simple dispersal model

Author

Rodríguez-Rey, Marta, Jiménez-Valverde, Alberto, and Acevedo, Pelayo

Published

2013

16. Discrimination capacity in species distribution models depends on the representativeness of the environmental domain

Author

Jiménez-Valverde, Alberto, Acevedo, Pelayo, Barbosa, A. Márcia, Lobo, Jorge M., and Real, Raimundo

Published

2013

17. Insights into the area under the receiver operating characteristic curve (AUC) as a discrimination measure in species distribution modelling

Author

Jiménez-Valverde, Alberto

Published

2012

18. rangemap: An R Package to Explore Species' Geographic Ranges

Author

Cobos, Marlon E., primary, Barve, Vijay, additional, Barve, Narayani, additional, Jiménez-Valverde, Alberto, additional, and Nuñez-Penichet, Claudia, additional

Published

2022

19. Environmental suitability of new reported localities of the funnelweb spider Macrothele calpeiana: an assessment using potential distribution modelling with presence-only techniques

Author

Jiménez-Valverde, Alberto, Decae, Arthur E., and Arnedo, Miquel A.

Published

2011

20. Dominant climate influences on North American bird distributions

Author

Jiménez-Valverde, Alberto, Barve, Narayani, Lira-Noriega, Andrés, Maher, Sean P., Papeş, Monica, Soberón, Jorge, Sukumaran, Jeet, Peterson, A. Townsend, and Nakazawa, Yoshinori

Published

2011

21. Choleva (Choleva) cisteloides subsp. cisteloides cisteloides

Author

Ledesma, Enrique, Jiménez-Valverde, Alberto, Salgado, José María, and Ortuño, Vicente M.

Subjects

Coleoptera, Insecta, Arthropoda, Animalia, Choleva cisteloides, Biodiversity, Choleva (choleva) cisteloides cisteloides, Leiodidae, Taxonomy, Choleva

Abstract

Choleva (Choleva) cisteloides cisteloides (Fr��lich, 1799) (Fig. 5I) Luperus cisteloides Fr��lich, 1799: 25. Choleva oblonga Spence, 1815: 138. Choleva humeralis Brull��, 1832: 162. Catops castaneus Sturm, 1839: 9. Choleva tournieri Pic, 1922: 22. Choleva (Choleva) cisteloides ��� Reitter 1885: 42. TYPE LOCALITY. ��� No data. Probably Germany (Fr��lich 1799). DISTRIBUTION. ��� (EURP) Limited to Western Europe and Turkey. Known from various locations in the northern half of the Iberian Peninsula. MATERIAL COLLECTED. ��� 13 exx. Spain ��� 1 ex; SSD-1; 24. V.2016; coll. V. M. O. ��� 1 ex; SSD-22; 13. VI.2016; coll. V. M. O. ��� 4 exx; SSD-23; 13. VI.2016; coll. V. M. O. ��� 5 exx, same locality and date; MNHN ��� 2 exx; SSD-26; 8.VII.2016; coll. V. M. O. REMARK The captures of this study are the first records of this species in the Central System of the Iberian Peninsula, thus this is the first record for Madrid and Segovia provinces and Sierra de Guadarrama National Park. Previously reported in caves (see Fresneda & Salgado 2016), this is the first record in the MSS., Published as part of Ledesma, Enrique, Jim��nez-Valverde, Alberto, Salgado, Jos�� Mar��a & Ortu��o, Vicente M., 2022, Cholevinae (Coleoptera: Leiodidae) of the Sierra de Guadarrama National Park, Spain: occurrence in the MSS of a siliceous landscape, pp. 125-149 in Zoosystema 44 (4) on page 135, DOI: 10.5252/zoosystema2022v44a4, http://zenodo.org/record/6323123, {"references":["FROLICH J. A. 1799. - I. Einige neue Gattungen und Arten von Kafern. Der Naturforscher 28: 1 - 65.","SPENCE W. 1815. - A monograph of the British Species of the Genus Choleva. Transactions of the Linnean Society of London 11: 123 - 160.","BRULLE A. G. 1832. - Expedition scientifique de Moree. Section des sciences physiques. Tome 3, 1 ere partie, Zoologie, deuxieme section. Des animaux articules. Paris, 400 p. https: // gallica. bnf. fr / ark: / 12148 / btv 1 b 8626687 z","STURM J. 1839. - Deutschlands Fauna in Abbildung nach der Natur mit Beschreibungen, V. Abtheilung. Die Insecten. Vierzehutes Bandchen. Kafer. Deutschlands Insecten, XIV. Bandchen. Kafer. Nurnberg, 119 p., 16 illuminiterten Aupfertafeln. https: // doi. org / 10.5962 / t. 173057","PIC M. 1922. - Notes diverses, descriptions et diagnoses (Suite.). L'Echange 38 (408): 21 - 23. https: // www. biodiversitylibrary. org / page / 57924549","REITTER E. 1885. - Bestimmungs-Tabellen der europaischen Coleopteren, 12 Necrophaga. Verhandlungen des naturforschenden Vereines in Brunn 23 (1884): 3 - 122. https: // www. biodiversitylibrary. org / page / 16396320","FRESNEDA J. & SALGADO J. M. 2016. - Catalogo de los coleopteros Leiodidae Cholevinae Kirby, 1837 de la peninsula iberica e Islas Baleares. Monografies del Mueseu de Ciencies Naturals 7: 1 - 38."]}

Published

2022

22. Speonemadus vandalitiae

Author

Ledesma, Enrique, Jiménez-Valverde, Alberto, Salgado, José María, and Ortuño, Vicente M.

Subjects

Coleoptera, Insecta, Arthropoda, Speonemadus, Animalia, Biodiversity, Speonemadus vandalitiae, Leiodidae, Taxonomy

Abstract

Speonemadus vandalitiae (Heyden, 1870) (Fig. 5C) Catops vandalitiae Heyden, 1870: 97. Ptomaphagus vandalitiae ��� Heyden 1883: 368. Anemadus vandalitiae ��� Uhag��n 1890: 32. Hormosacus vandalitiae ��� Jeannel 1936: 214. Hormosacus vandalitiae pyrenaeus Jeannel, 1936: 214. Speonemadus vandalitiae ��� Giachino & Vailati 1993: 183. TYPE LOCALITY. ��� Spain: Andaluc��a, Ronda, Sierra de la Nieve (Heyden 1870). DISTRIBUTION. ��� (WMED) Present in French Atlantic Pyrenees, Sicily and North Africa. Wide distribution in the Iberian Peninsula and also present in the Balearic Islands. MATERIAL COLLECTED. ��� 286 exx. Spain ��� 1 ex; SSD-2 (0.5m); 21.IX.2016; coll. V. M. O. ��� 2 exx; SSD-1; 24. V.2016; coll. V. M. O. ��� 1 ex; same locality; 21.IX.2016; coll. V. M. O. ��� 1 ex; SSD-2; 21.IX.2016; coll. V. M. O. ��� 2 exx; SSD-3; 17.IX.2015; coll. V. M. O. ��� 1 ex; same locality; 26. V.2016; coll. V. M. O. ��� 2 exx; SSD-4; 17.IX.2015; coll. V. M. O. ��� 1 ex; same locality; 26. V.2016; coll. V. M. O. ��� 13 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 15 exx; SSD-6; 22.IX.2015; coll. V. M. O. ��� 4 exx; same locality; 24. V.2016; coll. V. M. O. ��� 25 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 1 ex; SSD-8; 28. VI.2016; coll. V. M. O. ��� 1 ex; SSD-11; 24. V.2016; coll. V. M. O. ��� 1 ex; same locality; 21.IX.2016; coll. V. M. O. ��� 1 ex; SSD-12; 26. V.2016; coll. V. M. O. ��� 12 exx; SSD-14; 2. VI.2016; coll. V. M. O. ��� 6 exx; SSD-15; 2. VI.2016; coll. V. M. O. ��� 14 exx; same locality; 28.IX.2016; coll. V. M. O. ��� 13 exx; SSD-16; 7.X.2015; MNHN ��� 2 exx; same locality; 2. VI.2016; MNHN. ��� 50 exx; same locality; 29.IX.2016; coll. V. M. O. ��� 1 ex; SSD-17; 7.X.2015; coll. V. M. O. ��� 4 exx; same locality; 2. VI.2016; coll. V. M. O. ��� 1 ex; SSD-18; 2. VI.2016; coll. V. M. O. ��� 1 ex; SSD-20; 29.IX.2016; coll. V. M. O. ��� 1 ex; SSD-22; 22.IX.2015; coll. V.M. O. ��� 1 ex; same locality; 13. VI.2016; coll. V. M. O. ��� 3 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 5 exx; SSD-23; 6.X.2015; coll. V. M. O. ��� 5 exx; same locality; 13. VI.2016; coll. V. M. O. ��� 2 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 2 exx; SSD-25; 22.X.2015; coll. V. M. O. ��� 6 exx; same locality; 9. VI.2016; MNHN ��� 24 exx; TSP-A; 22.IX.2016; coll. V. M. O. ��� 1 ex; TSP-C; 13. VI.2016; coll. V. M. O. ��� 24 exx; same locality; 6.X.2016; coll. V. M. O. ��� 2 exx; same locality; 5.IV.2017; coll. V. M. O. ��� 1 ex; TSP-D; 13. VI.2016; coll. V. M. O. ��� 7 exx; same locality; 6.X.2016; coll, V. M. O. REMARK Previously reported in caves (see Fresneda & Salgado 2016) and the MSS (Fresneda et al. 2007; S��ez Bola��o & Blanco Villero 2010)., Published as part of Ledesma, Enrique, Jim��nez-Valverde, Alberto, Salgado, Jos�� Mar��a & Ortu��o, Vicente M., 2022, Cholevinae (Coleoptera: Leiodidae) of the Sierra de Guadarrama National Park, Spain: occurrence in the MSS of a siliceous landscape, pp. 125-149 in Zoosystema 44 (4) on page 132, DOI: 10.5252/zoosystema2022v44a4, http://zenodo.org/record/6323123, {"references":["HEYDEN L. VON 1870. - Entomologische Reise nach dem sudlichen Spanien der Sierra Guadarrama und Sierra Morena, Portugal und den Cantabrischen Gebirgen. Berlin, 218 p. + 2 Tafeln","HEYDEN L. VON 1883. - Zwei neue Kafer von Creta. Deutsche entomologische Zeitschrift 27 (2): 368. https: // www. deutschedigitale-bibliothek. de / item / BJQKO 6 ASAPCDNU 3 ANVC 2 EDTJUT 7 KOFXY","UHAGON S. 1890. - Ensayo sobre las especies espanolas del grupo \" Cholevae \". Anales de la Sociedad espanola de Historia natural 19: 15 - 96.","JEANNEL R. 1936. - Monographie des Catopidae. (Memoires du Museum national d'Histoire naturelle - Nouvelle Serie (1935 - 1950): 1 - 433.","GIACHINO P. M. & VAILATI D. 1993. - Revisione degli Anemadinae. Museo Civico di Scienze Naturali di Brescia. Monografie di \" Natura Bresciana \" 18, Brescia, 314 p.","FRESNEDA J. & SALGADO J. M. 2016. - Catalogo de los coleopteros Leiodidae Cholevinae Kirby, 1837 de la peninsula iberica e Islas Baleares. Monografies del Mueseu de Ciencies Naturals 7: 1 - 38.","FRESNEDA J., CARDENAS A. M., CASTRO A., LENCINA J. L., LOPEZ- COLON J. I. & BAENA M. 2007. - Nuevos datos de los Cholevidae en la Peninsula Iberica (Coleoptera). Boletin de la Asociacion espanola de Entomologia 31 (3 - 4): 187 - 214.","SAEZ BOLANO J. & BLANCO VILLERO J. M. 2010. - Los colevidos epigeos (Coleoptera, Leiodidae, Cholevinae) de la Sierra de Tudia (Badajoz, Extremadura, Espana). Boletin de la Sociedad Entomologica Aragonesa 47: 357 - 361."]}

Published

2022

23. Choleva (Cholevopsis) punctata Brisout 1866

Author

Ledesma, Enrique, Jiménez-Valverde, Alberto, Salgado, José María, and Ortuño, Vicente M.

Subjects

Coleoptera, Insecta, Arthropoda, Animalia, Biodiversity, Choleva punctata, Leiodidae, Taxonomy, Choleva

Abstract

Choleva (Cholevopsis) punctata Brisout, 1866 (Fig. 5J) Choleva punctata Brisout, 1866: 364. Choleva (Cholevopsis) punctata ��� Jeannel 1923: 51. TYPE LOCALITY. ��� Spain: Cantabria, Reinosa (Brisout de Barneville 1866). DISTRIBUTION. ��� (IBER) Species known from France and from numerous localities in the northern half of the Iberian Peninsula. MATERIAL COLLECTED. ��� 212 exx (96 males and 116 females). Spain ��� 11 exx; SSD-6; 22.IX.2015; coll. V. M. O. ��� 13 exx; same locality and date; MNHN ��� 3 exx; same locality; 24. V.2016; coll. V. M. O. ��� 16 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 19 exx; same locality and date; MNHN ��� 101 exx; SSD-11; 17.IX.2015; coll. V. M. O. ��� 3 exx; same locality; 24. V.2016; coll. V. M. O. ��� 9 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 1 ex; SSD-15; 28.IX.2016; coll. V. M. O. ��� 16 exx; SSD-16; 7.X.2015; coll. V. M. O. ��� 6 exx; same locality; 2. VI.2016; coll. V. M. O. ��� 9 exx; same locality; 29.IX.2016; coll. V. M. O. ��� 2 exx; SSD-17; 29.IX.2016; coll. V. M. O. ��� 2 exx; SSD-25; 9. VI.2016; coll. V. M. O. ��� 1 ex; TSP-D; 6.X.2016; coll. V. M. O. REMARK First record for Segovia province. Previously reported in caves (see Fresneda & Salgado 2016), this is the first record in the MSS., Published as part of Ledesma, Enrique, Jim��nez-Valverde, Alberto, Salgado, Jos�� Mar��a & Ortu��o, Vicente M., 2022, Cholevinae (Coleoptera: Leiodidae) of the Sierra de Guadarrama National Park, Spain: occurrence in the MSS of a siliceous landscape, pp. 125-149 in Zoosystema 44 (4) on pages 135-137, DOI: 10.5252/zoosystema2022v44a4, http://zenodo.org/record/6323123, {"references":["BRISOUT DE BARNEVILLE C. 1866. - Coleopteres nouveaux trouves en Espagne pendant l'excursion de la Societe en 1865. Annales de la Societe entomologique de France, 4 e serie 6: 355 - 426.","JEANNEL R. 1923. - Revision des Choleva Latreille pour servir a l'histoire du peuplement de l'Europe. L'Abeille 32: 1 - 160.","FRESNEDA J. & SALGADO J. M. 2016. - Catalogo de los coleopteros Leiodidae Cholevinae Kirby, 1837 de la peninsula iberica e Islas Baleares. Monografies del Mueseu de Ciencies Naturals 7: 1 - 38."]}

Published

2022

24. Ptomaphagus (Ptomaphagus) tenuicornis subsp. tenuicornis tenuicornis (Rosenhauer 1856

Author

Ledesma, Enrique, Jiménez-Valverde, Alberto, Salgado, José María, and Ortuño, Vicente M.

Subjects

Coleoptera, Insecta, Arthropoda, Ptomaphagus, Ptomaphagus tenuicornis, Ptomaphagus (ptomaphagus) tenuicornis tenuicornis (rosenhauer, 1856), Animalia, Biodiversity, Leiodidae, Taxonomy

Abstract

Ptomaphagus (Ptomaphagus) tenuicornis tenuicornis (Rosenhauer, 1856) (Fig. 5L) Catops tenuicornis Rosenhauer, 1856: 61. Ptomaphagus (Ptomaphagus) tenuicornis ��� Jeannel 1936: 89. TYPE LOCALITY. ��� Spain: C��diz, Algeciras (Rosenhauer, 1856). DISTRIBUTION. ��� (SOER) Known from France. Species of wide Iberian distribution. MATERIAL COLLECTED. ��� 160 exx. Spain ��� 4 exx; SSD-1 (0.5m); 21.IX.2016; coll. V. M. O. ��� 1 ex; SSD-2 (0.5m); 21.IX.2016; coll. V. M. O. ��� 7 exx; SSD-4 (0.5m); 26. V.2016; coll. V. M. O. ��� 2 exx; SSD-1; 17.IX.2015; coll. V. M. O. ��� 2 exx; SSD-2; 21.IX.2016; coll. V. M. O. ��� 1 ex; SSD-3; 17.IX.2015; coll. V. M. O. ��� 4 exx; same locality; 26. V.2016; coll. V. M. O. ��� 6 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 5 exx; SSD-4; 17.IX.2015; MNHN. ��� 9 exx; same locality; 26. V.2016; coll. V. M. O. ��� 18 exx; same locality and date; MNHN ��� 11 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 1 ex; SSD-6; 22.IX.2015; coll. V. M. O. ��� 1 ex; same locality; 22.IX.2016; coll. V. M. O. ��� 19 exx; SSD-11; 17.IX.2015; coll. V. M. O. ��� 1 ex; same locality; 24. V.2016; coll. V. M. O. ��� 19 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 1 ex; SSD-15; 5.X.2015; coll. V. M. O. ��� 3 exx; same locality; 2. VI.2016; MNHN. ��� 1 ex; same locality; 28.IX.2016; coll. V. M. O. ��� 1 ex; SSD-16; 29.IX.2016; coll. V. M. O. ��� 1 ex; SSD-18; 29.IX.2016; coll. V. M. O. ��� 1 ex; SSD-26; 8.VII.2016; coll. V. M. O. ��� 1 ex; SSD-31; 8.VII.2016; coll. V. M. O. ��� 1 ex; TSP-A; 22.IX.2015; coll. V. M. O. ��� 7 exx; same locality; 13. VI.2016; coll. V. M. O. ��� 11 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 1 ex; TSP-C; 13. VI.2016; coll. V. M. O. ��� 11 exx; same locality; 6.X.2016; coll. V. M. O. ��� 9 exx; TSP-D; 6.X.2016; coll. V. M. O. REMARK Reported previously in caves (see Fresneda & Salgado 2016) and the MSS (Fresneda et al. 2007; S��ez Bola��o & Blanco Villero 2010)., Published as part of Ledesma, Enrique, Jim��nez-Valverde, Alberto, Salgado, Jos�� Mar��a & Ortu��o, Vicente M., 2022, Cholevinae (Coleoptera: Leiodidae) of the Sierra de Guadarrama National Park, Spain: occurrence in the MSS of a siliceous landscape, pp. 125-149 in Zoosystema 44 (4) on pages 139-140, DOI: 10.5252/zoosystema2022v44a4, http://zenodo.org/record/6323123, {"references":["ROSENHAUER W. G. 1856. - Die Thiere Andalusiens nach dem Resultate einer Reise zusammengestellt, nebst den Beschreibungen von 249 neuen oder bis jetzt noch umbeschriebenen GatTUNgen and Arten. Erlangen, viii + 429 p. https: // doi. org / 10.5962 / bhl. title. 66016","JEANNEL R. 1936. - Monographie des Catopidae. (Memoires du Museum national d'Histoire naturelle - Nouvelle Serie (1935 - 1950): 1 - 433.","FRESNEDA J. & SALGADO J. M. 2016. - Catalogo de los coleopteros Leiodidae Cholevinae Kirby, 1837 de la peninsula iberica e Islas Baleares. Monografies del Mueseu de Ciencies Naturals 7: 1 - 38.","FRESNEDA J., CARDENAS A. M., CASTRO A., LENCINA J. L., LOPEZ- COLON J. I. & BAENA M. 2007. - Nuevos datos de los Cholevidae en la Peninsula Iberica (Coleoptera). Boletin de la Asociacion espanola de Entomologia 31 (3 - 4): 187 - 214.","SAEZ BOLANO J. & BLANCO VILLERO J. M. 2010. - Los colevidos epigeos (Coleoptera, Leiodidae, Cholevinae) de la Sierra de Tudia (Badajoz, Extremadura, Espana). Boletin de la Sociedad Entomologica Aragonesa 47: 357 - 361."]}

Published

2022

25. Catopomorphus (Attiscurra) marqueti Fairmaire 1857

Author

Ledesma, Enrique, Jiménez-Valverde, Alberto, Salgado, José María, and Ortuño, Vicente M.

Subjects

Coleoptera, Catopsimorphus (attiscurra) marqueti fairmaire, 1857, Insecta, Arthropoda, Catopomorphus marqueti, Catopomorphus, Animalia, Biodiversity, Leiodidae, Taxonomy

Abstract

Catopsimorphus (Attiscurra) marqueti Fairmaire, 1857 (Fig. 5G) Catopsimorphus marqueti Fairmaire, 1857: 729. Catopomorphus bicolor Kraatz, 1870: 12. Catopomorphus marqueti ��� Reitter 1885: 48. Attiscurra marqueti ��� Des Gozis 1886: 17. Catopsimorphus bedeli Caillol, 1913: 8. Catopsimorphus (Attiscurra) marqueti ��� Jeannel 1936: 321. TYPE LOCALITY. ��� France: Probably from H��rault, B��ziers (Fairmaire 1857). DISTRIBUTION. ��� (WMED) Presence confirmed in the Iberian Peninsula with few and distant records, also present in southern France and Morocco. MATERIAL COLLECTED. ��� 2 exx. Spain ��� 1 ex; SSD���3; 26.V.2016; coll. V. M. O. ��� 1 ex; same locality; 21.IX.2016; coll. V. M. O. REMARK First record for Madrid and Segovia provinces, also first record in the hypogean environment., Published as part of Ledesma, Enrique, Jim��nez-Valverde, Alberto, Salgado, Jos�� Mar��a & Ortu��o, Vicente M., 2022, Cholevinae (Coleoptera: Leiodidae) of the Sierra de Guadarrama National Park, Spain: occurrence in the MSS of a siliceous landscape, pp. 125-149 in Zoosystema 44 (4) on page 135, DOI: 10.5252/zoosystema2022v44a4, http://zenodo.org/record/6323123, {"references":["FAIRMAIRE L. 1857. - Miscellanea entomologica. Deuxieme partie (1). Annales de la Societe entomologique de France, 3 e serie 5: 725 - 745.","KRAATZ G. 1870. - In HEYDEN L. VON. (ed.) Entomologische Reise nach dem sudlichen Spanien der Sierra Guadarrama und Sierra Morena, Portugal und den Cantabrischen Gebirgen. Berlin, 218 p. + 2 Tafeln.","REITTER E. 1885. - Bestimmungs-Tabellen der europaischen Coleopteren, 12 Necrophaga. Verhandlungen des naturforschenden Vereines in Brunn 23 (1884): 3 - 122. https: // www. biodiversitylibrary. org / page / 16396320","DES GOZIS M. 1886. - Recherche de l'espece typique de quelques anciens genres. Rectifications synonymiques et notes diverses. Imprimerie Herbin, Montlucon, 36 p. https: // www. biodiversitylibrary. org / page / 43206984","JEANNEL R. 1936. - Monographie des Catopidae. (Memoires du Museum national d'Histoire naturelle - Nouvelle Serie (1935 - 1950): 1 - 433."]}

Published

2022

26. Catopsimorphus (Weiratherella) rougeti Saulcy 1864

Author

Ledesma, Enrique, Jiménez-Valverde, Alberto, Salgado, José María, and Ortuño, Vicente M.

Subjects

Coleoptera, Catopsimorphus, Catopsimorphus rougeti, Insecta, Arthropoda, Animalia, Biodiversity, Leiodidae, Taxonomy

Abstract

Catopsimorphus (Weiratherella) rougeti Saulcy, 1864 (Fig. 5H) Catopsimorphus rougeti Saulcy, 1864: 653. Catopsimorphus (Weiratherella) rougeti ��� Jeannel 1936: 318. TYPE LOCALITY. ��� France: Pyr��n��es-Orientales, Collioure and Port-Vendres (Saulcy 1864). DISTRIBUTION. ��� (SOER) Known from France and Italy. Present in the southern half of the Iberian Peninsula, with two exclusive records close to the coast in Barcelona. MATERIAL COLLECTED. ��� 5 exx. Spain ��� 1 ex; SSD-23; 6.X.2015; coll. V. M. O. ��� 1 ex; same locality; 13. VI.2016; coll. V. M. O. ��� 2 exx; SSD-25; 9. VI.2016; MNHN ��� 1 ex; SSD-26; 8.VII.2016; coll. V. M. O. REMARK First record for Segovia province and Sierra de Guadarrama National Park. Reported previously in the MSS (Jim��nez- Valverde et al. 2015)., Published as part of Ledesma, Enrique, Jim��nez-Valverde, Alberto, Salgado, Jos�� Mar��a & Ortu��o, Vicente M., 2022, Cholevinae (Coleoptera: Leiodidae) of the Sierra de Guadarrama National Park, Spain: occurrence in the MSS of a siliceous landscape, pp. 125-149 in Zoosystema 44 (4) on page 135, DOI: 10.5252/zoosystema2022v44a4, http://zenodo.org/record/6323123, {"references":["SAULCY M. F. 1864. - Description de quatre nouvelles especes de Coleopteres propres a la faune francaise et remarques sur quelques autres especes. Annales de la Societe entomologique de France, 4 e serie 3 (1863): 653 - 658.","JEANNEL R. 1936. - Monographie des Catopidae. (Memoires du Museum national d'Histoire naturelle - Nouvelle Serie (1935 - 1950): 1 - 433.","JIMENEZ- VALVERDE A., GILGADO J. D., SENDRA A., PEREZ- SUAREZ G., HERRERO- BORGONON J. J. & ORTUNO V. M. 2015. - Exceptional Invertebrate Diversity in a Scree Slope in Eastern Spain. Journal of Insect Conservation 19 (4): 713 - 728. https: // doi. org / 10.1007 / s 10841 - 015 - 9794 - 1"]}

Published

2022

27. Speonemadus angusticollis

Author

Ledesma, Enrique, Jiménez-Valverde, Alberto, Salgado, José María, and Ortuño, Vicente M.

Subjects

Coleoptera, Insecta, Arthropoda, Speonemadus, Speonemadus angusticollis, Animalia, Biodiversity, Leiodidae, Taxonomy

Abstract

Speonemadus angusticollis (Kraatz, 1870) (Fig. 5A) Choleva angusticollis Kraatz, 1870: 90. Catops angusticollis ��� Marseul 1884: 69. Anemadus angusticollis ��� Reitter 1885: 60. Speonemadus angusticollis ��� Jeannel 1936: 220. TYPE LOCALITY. ��� Spain: C��rdoba (Kraatz 1870). DISTRIBUTION. ��� (IBER) Iberian endemism, distributed in the southern half of the Iberian Peninsula. MATERIAL COLLECTED. ��� 1814 exx. Spain ��� 65 exx; SSD-1; 17.IX.2015; coll. V. M. O. ��� 1 ex; same locality; 24. V.2016; coll. V. M. O. ��� 7 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 17 exx; SSD-3; 17.9.2015; coll. V. M. O. ��� 1 ex; same locality; 26. V.2016; coll. V. M. O. ��� 7 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 16 exx; SSD-4; 17.IX.2015; coll. V.M. O. ��� 7 exx; same locality; 26. V.2016; coll. V. M. O. ��� 11 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 57 exx; SSD-5; 22.IX.2015; coll. V. M. O. ��� 2 exx; same locality; 24. V.2016; coll. V. M. O. ��� 19 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 5 exx; SSD-6; 22.IX.2015; coll. V. M. O. ��� 4 exx; same locality; 24. V.2016; coll. V. M. O. ��� 4 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 29 exx; SSD-7; 17.IX.2015; coll. V. M. O. ��� 1 ex; same locality; 28. VI.2016; coll. V. M. O. ��� 10 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 11 exx; SSD-8; 17.IX.2015; coll. V. M. O. ��� 1 ex; same locality; 28. VI.2016; coll. V. M. O. ��� 12 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 11 exx; SSD-9; 5.X.2015; coll. V. M. O. ��� 20 exx; same locality; 22.IX.2016;; coll. V. M. O. ��� 11 exx; SSD-11; 17.IX.2015; coll. V. M. O. ��� 2 exx; SSD-13; 14.X.2016; coll. V. M. O. ��� 1 ex; SSD-14; 2. VI.2016; coll. V. M. O. ��� 3 exx; SSD-17; 29.IX.2016; coll. V. M. O. ��� 2 exx; SSD-19; 6.X.2015; coll. V. M. O. ��� 25 exx; SSD-20; 6.X.2015; coll. V. M. O. ��� 3 exx; same locality; 9. VI.2016; coll. V. M. O. ��� 43 exx; same locality; 29.IX.2016; coll. V. M. O. ��� 14 exx; SSD-21; 6.X.2015; coll. V. M. O. ��� 4 exx; same locality; 29.IX.2016; coll. V. M. O. ��� 161 exx; SSD-23; 6.X.2015; coll. V. M. O. ��� 7 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 320 exx; SSD-24; 22.X.2015; coll. V. M. O. ��� 4 exx; same locality; 9. VI.2016; coll. V. M. O. ��� 172 exx; same locality; 6.X.2016; coll. V. M. O. ��� 23 exx; SSD-30; 6.XI.2015; coll. V. M. O. ��� 48 exx; same locality; 13.VII.2016; coll. V. M. O. ��� 20 exx; same locality; 14.X.2016;; coll. V. M. O. ��� 1 ex; SSD-31; 22.X.2015; coll. V. M. O. ��� 1 ex; same locality; 8.VII.2016; coll. V. M. O. ��� 5 exx; same locality; 6.X.2016; coll. V. M. O. ��� 1 ex; SSD-32; 22.X.2015; coll. V. M. O. ��� 16 exx; SSD-33; 22.X.2015; coll. V. M. O. ��� 3 exx; same locality; 8.VII.2016; coll. V. M. O. ��� 1 ex; same locality; 28.IX.2016; coll. V. M. O. ��� 225 exx; TSP-A; 22.IX.2015; coll. V. M. O. ��� 20 exx; same locality and date; MNHN ��� 41 exx; same locality; 13. VI.2016; coll. V. M. O. ��� 329 exx; same locality; 22.IX.2016; coll. V. M. O. REMARK First record for Segovia province. Previously reported in caves (see Fresneda & Salgado 2016), this is the first record in the MSS., Published as part of Ledesma, Enrique, Jim��nez-Valverde, Alberto, Salgado, Jos�� Mar��a & Ortu��o, Vicente M., 2022, Cholevinae (Coleoptera: Leiodidae) of the Sierra de Guadarrama National Park, Spain: occurrence in the MSS of a siliceous landscape, pp. 125-149 in Zoosystema 44 (4) on pages 131-132, DOI: 10.5252/zoosystema2022v44a4, http://zenodo.org/record/6323123, {"references":["KRAATZ G. 1870. - In HEYDEN L. VON. (ed.) Entomologische Reise nach dem sudlichen Spanien der Sierra Guadarrama und Sierra Morena, Portugal und den Cantabrischen Gebirgen. Berlin, 218 p. + 2 Tafeln.","MARSEUL S. DE 1884. - Precis des genres et especes de la tribu des Silphales de l'ancien-monde. L'Abeille 22: 1 - 204.","REITTER E. 1885. - Bestimmungs-Tabellen der europaischen Coleopteren, 12 Necrophaga. Verhandlungen des naturforschenden Vereines in Brunn 23 (1884): 3 - 122. https: // www. biodiversitylibrary. org / page / 16396320","JEANNEL R. 1936. - Monographie des Catopidae. (Memoires du Museum national d'Histoire naturelle - Nouvelle Serie (1935 - 1950): 1 - 433.","FRESNEDA J. & SALGADO J. M. 2016. - Catalogo de los coleopteros Leiodidae Cholevinae Kirby, 1837 de la peninsula iberica e Islas Baleares. Monografies del Mueseu de Ciencies Naturals 7: 1 - 38."]}

Published

2022

28. Catops fuscus subsp. fuscus fuscus (Panzer 1794

Author

Ledesma, Enrique, Jiménez-Valverde, Alberto, Salgado, José María, and Ortuño, Vicente M.

Subjects

Coleoptera, Insecta, Arthropoda, Catops fuscus fuscus (panzer, 1794), Animalia, Biodiversity, Catops, Catops fuscus, Leiodidae, Taxonomy

Abstract

Catops fuscus fuscus (Panzer, 1794) (Fig. 5F) Helops fuscus Panzer, 1794: 1. Catops sericeus Paykull, 1798: 342. Catops rufescens Fabricius, 1801: 563. Choleva festinans Spence, 1815: 145. Choleva agilis Spence, 1815: 140. Catops fuscus ��� Erichson 1837: 235. TYPE LOCALITY. ��� Germany: Saxony, Dresden (Panzer 1794). DISTRIBUTION. ��� (EURP) Species widely distributed in Europe, and North Africa, also present in Afghanistan. The distribution in the Iberian Peninsula is wide, although the species is unknown from the western part. MATERIAL COLLECTED. ��� 1770 exx. Spain ��� 2 exx; SSD-2 (0.5m); 17.IX.2015; coll. V. M. O. ��� 1 ex; same locality; 24. V.2016; coll. V. M. O. ��� 17 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 1 ex; SSD-4 (0.5m); 26. V.2016; coll. V. M. O. ��� 1 ex; SSD-1; 17.IX.2015; coll. V. M. O. ��� 3 exx; 24. V.2016; same locality;; coll. V. M. O. ��� 58 exx; SSD-2; 17.IX.2015; coll. V. M. O. ��� 10 exx; same locality; 24. V.2016; coll. V. M. O. ��� 45 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 2 exx; SSD-3; 26. V.2016; coll. V. M. O. ��� 2 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 47 exx; SSD-5; 22.IX.2015 9 exx; same locality; 24. V.2016 45 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 12 exx; SSD-6; 22.IX.2015;; coll. V. M. O. ��� 5 exx; same locality; 24. V.2016;; coll. V. M. O. ��� 19 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 16 exx; SSD-7; 17.IX.2015;; coll. V. M. O. ��� 19 exx; same locality; 28. VI.2016; coll. V. M. O. ��� 9 exx; same locality; 21.IX.2016; coll. V. M. O. ��� 2 exx; SSD-8; 17.IX.2015; coll. V. M. O. ��� 2 exx; same locality; 28. VI.2016; coll. V. M. O. ��� 10 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 1 ex; SSD-9; 5.X.2015; coll. V. M. O. ��� 2 exx; same locality; 28. VI.2016; coll. V. M. O. ��� 1 ex; SSD-10; 5.X.2015; coll. V. M. O. ��� 1 ex; same locality; 28. VI.2016; coll. V. M. O. ��� 2 exx; SSD-11; 17.IX.2015; coll. V. M. O. ��� 3 exx; same locality; 24. V.2016; coll. V. M. O. ��� 2 exx; SSD-12; 14.X.2016; coll. V. M. O. ��� 1 ex; SSD-13; 26. V.2016; coll. V. M. O. ��� 4 exx; SSD-14; 2. VI.2016; coll. V. M. O. ��� 1 ex; SSD-15; 2. VI.2016; coll. V. M. O. ��� 40 exx; SSD-16; 7.X.2015; coll. V. M. O. ��� 14 exx; same locality; 2. VI.2016; coll. V. M. O. ��� 21 exx; same locality; 29.IX.2016; coll. V. M. O. ��� 47 exx; SSD-17; 7.X.2015; coll. V. M. O. ��� 18 exx; same locality; 2. VI.2016; coll. V. M. O. ��� 42 exx; same locality; 29.IX.2016; coll. V. M. O. ��� 76 exx; SSD-18; 7.X.2015; coll. V. M. O. ��� 31 exx; same locality; 2. VI.2016; coll. V. M. O. ��� 25 exx; same locality; 29.IX.2016; coll. V. M. O. ��� 40 exx; SSD-19; 6.X.2015; coll. V. M. O. ��� 21 exx; same locality; 9. VI.2016; coll. V. M. O. ��� 7 exx; same locality; 29.IX.2016; coll. V. M. O. ��� 129 exx; SSD-20; 6.X.2015; coll. V. M. O. ��� 23 exx; same locality; 9. VI.2016; coll. V. M. O. ��� 67 exx; same locality; 29.IX.2016; coll. V. M. O. ��� 378 exx; SSD-21; 6.X.2015; coll. V. M. O. ��� 20 exx; same locality and date; MNHN ��� 83 exx; same locality; 9. VI.2016; coll. V. M. O. ��� 118 exx; same locality; 29.IX.2016; coll. V. M. O. ��� 21 exx; SSD-22; 22.IX.2015; coll. V. M. O. ��� 14 exx; same locality; 13. VI.2016; coll. V. M. O. ��� 34 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 17 exx; SSD-23; 6.X.2015; coll. V. M. O. ��� 13 exx; same locality; 13. VI.2016; coll. V. M. O. ��� 14 exx; same locality; 22.IX.2016; coll. V. M. O. ��� 3 exx; SSD-24; 22.X.2015; coll. V. M. O. ��� 7 exx; SSD-25; 22.X.2015; coll. V. M. O. ��� 25 exx; same locality; 9. VI.2016; coll. V. M. O. ��� 4 exx; same locality; 6.X.2016; coll. V. M. O. ��� 1 ex; SSD-26; 8.VII.2016; coll. V. M. O. ��� 8 exx; SSD-28; 6.XI.2015; coll. V. M. O. ��� 1 ex; same locality; 14.X.2016; coll. V. M. O. ��� 2 exx; SSD-29; 6.XI.2015; coll. V. M. O. ��� 1 ex; same locality; 14.X.2016; coll. V. M. O. ��� 2 exx; SSD-33; 22.X.2015; coll. V. M. O. ��� 2 exx; same locality; 8.VII.2016; coll. V. M. O. ��� 1 ex; TSP-A; 22.IX.2015; coll. V. M. O. ��� 5 exx; same locaity; 13. VI.2016; coll. V. M. O. ��� 1 ex; same locality; 22.IX.2016; coll. V. M. O. ��� 2 exx; TSP-B; 13. VI.2016; coll. V. M. O. ��� 1 ex; TSP-C; 13. VI.2016; coll. V. M. O. ��� 12 exx; same locality; 6.X.2016; coll. V. M. O. ��� 11 exx; same locality; 5.IV.2017; coll. V. M. O. ��� 3 exx; TSP-D; 6.X.2016; coll. V. M. O. REMARK Previously reported in caves (see Fresneda & Salgado 2016) and MSS (Nitzu et al. 2006, 2010, 2014)., Published as part of Ledesma, Enrique, Jim��nez-Valverde, Alberto, Salgado, Jos�� Mar��a & Ortu��o, Vicente M., 2022, Cholevinae (Coleoptera: Leiodidae) of the Sierra de Guadarrama National Park, Spain: occurrence in the MSS of a siliceous landscape, pp. 125-149 in Zoosystema 44 (4) on pages 134-135, DOI: 10.5252/zoosystema2022v44a4, http://zenodo.org/record/6323123, {"references":["PANZER G. W. 1794. - Fauna insectorum germanicae initia oder Deutschlands Insekten. Nurnberg, pars 8 & pars 18.","PAYKULL G. 1798. - Fauna Svecica Insecta. Litteris Joh. F. Edman, Reg. Acad. Typogr. Upsaliae: 1 - 360. https: // doi. org / 10.5962 / bhl. title. 120338","FABRICIUS J. C. 1801. - Systema eleutheratorvm secvndvm ordines, genera, species: adiectis synonymis, locis, observationibvs, descriptionibvs. Tomus II. Impensis Bibliopolii Academici Novi, Kiliae, 1 - 687; 1 - 94.","SPENCE W. 1815. - A monograph of the British Species of the Genus Choleva. Transactions of the Linnean Society of London 11: 123 - 160.","ERICHSON W. F. 1837. - Die Kafer der Mark Brandenburg. Berlin, 384 p.","FRESNEDA J. & SALGADO J. M. 2016. - Catalogo de los coleopteros Leiodidae Cholevinae Kirby, 1837 de la peninsula iberica e Islas Baleares. Monografies del Mueseu de Ciencies Naturals 7: 1 - 38."]}

Published

2022

29. Attumbra josephinae subsp. josephinae josephinae (Saulcy 1862

Author

Ledesma, Enrique, Jiménez-Valverde, Alberto, Salgado, José María, and Ortuño, Vicente M.

Subjects

Coleoptera, Insecta, Arthropoda, Attumbra, Animalia, Biodiversity, Attumbra josephinae, Attumbra josephinae josephinae (saulcy, 1862), Leiodidae, Taxonomy

Abstract

Attumbra josephinae josephinae (Saulcy, 1862) (Fig. 5D) Catopsimorphus josephinae Saulcy, 1862: 286. Attumbra josephinae ��� Des Gozis 1886: 17. TYPE LOCALITY. ��� France: Pyr��n��es-Orientales, Port-Vendres (Saulcy 1862). DISTRIBUTION. ��� (SOER) Known from France and Corsica Island. Present in distant locations in Spain. MATERIAL COLLECTED. ��� 1 ex. Spain ��� 1 ex; SSD-33; 22.X.2015; coll. V. M. O. REMARK First record for Sierra de Guadarrama National Park, also first record in the hypogean environment., Published as part of Ledesma, Enrique, Jim��nez-Valverde, Alberto, Salgado, Jos�� Mar��a & Ortu��o, Vicente M., 2022, Cholevinae (Coleoptera: Leiodidae) of the Sierra de Guadarrama National Park, Spain: occurrence in the MSS of a siliceous landscape, pp. 125-149 in Zoosystema 44 (4) on page 134, DOI: 10.5252/zoosystema2022v44a4, http://zenodo.org/record/6323123, {"references":["SAULCY M. F. 1862. - Observations sur les genres Choleva, Catops et Catopsimorphus et remarques sur le nouveau catalogue de Mr. Schaum suivies de la description de deux nouveaux genres et de quatre nouvelles especes de Coleopteres propes a la faune de France. Annales de la Societe entomologique de France, 4 e serie 2: 281 - 291.","DES GOZIS M. 1886. - Recherche de l'espece typique de quelques anciens genres. Rectifications synonymiques et notes diverses. Imprimerie Herbin, Montlucon, 36 p. https: // www. biodiversitylibrary. org / page / 43206984"]}

Published

2022

30. Sciodrepoides watsoni subsp. watsoni watsoni (Spence 1815

Author

Ledesma, Enrique, Jiménez-Valverde, Alberto, Salgado, José María, and Ortuño, Vicente M.

Subjects

Coleoptera, Insecta, Arthropoda, Sciodrepoides watsoni, Sciodrepoides, Animalia, Sciodrepoides watsoni watsoni (spence, 1815), Biodiversity, Leiodidae, Taxonomy

Abstract

Sciodrepoides watsoni watsoni (Spence, 1815) (Fig. 5K) Choleva watsoni Spence, 1815: 156. Ptomaphagus watsoni ��� Stephens 1829a: 7; 1829b: 72. Catopomorphus curticornis Fairmaire, 1877: 65. Sciodrepa rugulosa Thomson, 1884: 1034. Catops (Catops) watsoni ��� Bugnion 1890: 145. Choleva horniana Blanchard, 1915: 294. Sciodrepoides watsoni ��� Jeannel 1934: 5. TYPE LOCALITY. ��� United Kingdom (Spence 1815). DISTRIBUTION. ��� (ASER) Species with a wide European distribution. Unknown from the western of the Iberian Peninsula. MATERIAL COLLECTED. ��� 3 exx. Spain ��� 2 exx; TSP-A; 13. VI.2016; coll. V. M. O. ��� 1 exx; same locality and date; MNHN. REMARK Reported previously in caves (see Fresneda & Salgado 2016) and the MSS (Fresneda et al. 2007, 2010; Langourov et al. 2014; Mammola et al. 2017)., Published as part of Ledesma, Enrique, Jim��nez-Valverde, Alberto, Salgado, Jos�� Mar��a & Ortu��o, Vicente M., 2022, Cholevinae (Coleoptera: Leiodidae) of the Sierra de Guadarrama National Park, Spain: occurrence in the MSS of a siliceous landscape, pp. 125-149 in Zoosystema 44 (4) on page 139, DOI: 10.5252/zoosystema2022v44a4, http://zenodo.org/record/6323123, {"references":["SPENCE W. 1815. - A monograph of the British Species of the Genus Choleva. Transactions of the Linnean Society of London 11: 123 - 160.","STEPHENS J. F. 1829 a. - The Nomenclature of British Insects; being a compendious list of such species as are contained in the systematic catalogue or British insects, and forming a guide to their classification, & c. Baldwin and Cradock, London, 68 p. https: // doi. org / 10.5962 / bhl. title. 51800","STEPHENS J. F. 1829 b. - A systematic catalogue of british insects: being an attempt to arrange all the hitherto discovered indigenous insects in accordance with their natural affinities. Containing also the references to every english writer on entomology, and to the principal foreign authors. With all the published british genera to the present time. Baldwin and Cradock, London, xxxiv + 388 p.","FAIRMAIRE L. 1877. - Catopomorphus curticornis. Annales de la Societe entomologique de France, 5 eme serie 7 (Seance du 11 Avril 1877): 65 - 67.","THOMSON C. G. 1884. - Opuscula Entomologica. Tomus decimus. Typis expressit haquinus Ohlsson, Lundae: 937 - 1656. https: // www. biodiversitylibrary. org / page / 9665811","BUGNION E. 1890. - Introduction a la faune entomologique du Valais, in FAVRE E. (ed.), Faune des Coleopteres du Valais et des regions limitrophes. Imprimerie Zurcher & Furrer, Zurich: 9 - 44.","BLANCHARD F. 1915. - Two new Silphids (Col.). Entomological News 26: 294. https: // www. biodiversitylibrary. org / page / 26320152","JEANNEL R. 1934. - Les Catops de France. Revue francaise d'Entomologie 1 (1): 2 - 24.","FRESNEDA J. & SALGADO J. M. 2016. - Catalogo de los coleopteros Leiodidae Cholevinae Kirby, 1837 de la peninsula iberica e Islas Baleares. Monografies del Mueseu de Ciencies Naturals 7: 1 - 38.","FRESNEDA J., CARDENAS A. M., CASTRO A., LENCINA J. L., LOPEZ- COLON J. I. & BAENA M. 2007. - Nuevos datos de los Cholevidae en la Peninsula Iberica (Coleoptera). Boletin de la Asociacion espanola de Entomologia 31 (3 - 4): 187 - 214.","FRESNEDA J., BORDEAU C. & FAILLE A. 2010. - Sobre la presencia de Catops subfuscus Kellner, 1846 en los Pirineos (Coleoptera, Leiodidae, Cholevinae, Catopini). Arxius de Miscel. lania Zoologica 8: 9 - 14.","LANGOUROV M., LAZAROV S., STOEV P., GUEORGUIEV B., DELTSHEV C., PETROV B., ANDREEV S., SIMOV N., BEKCHIEV R., ANTONOVA V., LJUBOMIROV T., DEDOV I. & GEORGIEV D. 2014. - New and interesting records of the MSS and cave fauna of Vitosha Mt., Bulgaria. Proceedings of Balkan Speleological Conference Sofia: 66 - 76.","MAMMOLA S., PIANO E., GIACHINO P. M., ISAIA M. 2017. - An ecological survey of the invertebrate community at the epigean. hypogean interface. Subterranean Biolology 24: 27 - 52. https: // doi. org. 10.3897. subtbiol. 24.21585"]}

Published

2022

31. The uncertain nature of absences and their importance in species distribution modelling

Author

Lobo, Jorge M., Jiménez-Valverde, Alberto, and Hortal, Joaquín

Published

2010

32. Species distribution models do not account for abundance: the case of arthropods on Terceira Island

Author

Jiménez-Valverde, Alberto, Diniz, Francisco, de Azevedo, Eduardo B., and Borges, Paulo A. V.

Published

2009

33. Not as Good as They Seem: The Importance of Concepts in Species Distribution Modelling

Author

Jiménez-Valverde, Alberto, Lobo, Jorge M., and Hortal, Joaquín

Published

2008

34. Historical Bias in Biodiversity Inventories Affects the Observed Environmental Niche of the Species

Author

Hortal, Joaquín, Jiménez-Valverde, Alberto, Gómez, José F., Lobo, Jorge M., and Baselga, Andrés

Published

2008

35. AUC: A Misleading Measure of the Performance of Predictive Distribution Models

Author

Lobo, Jorge M., Jiménez-Valverde, Alberto, and Real, Raimundo

Published

2008

36. Challenging species distribution models: the case of Maculinea nausithous in the Iberian Peninsula

Author

Jiménez-Valverde, Alberto, Gómez, José F., Lobo, Jorge M., Baselga, Andrés, and Hortal, Joaquín

Published

2008

37. The crucial role of the accessible area in ecological niche modeling and species distribution modeling

Author

Barve, Narayani, Barve, Vijay, Jiménez-Valverde, Alberto, Lira-Noriega, Andrés, Maher, Sean P., Peterson, A. Townsend, Soberón, Jorge, and Villalobos, Fabricio

Published

2011

38. The uniform AUC: Dealing with the representativeness effect in presence–absence models

Author

Jiménez‐Valverde, Alberto, primary

Published

2022

39. Cholevinae (Coleoptera: Leiodidae) of the Sierra de Guadarrama National Park, Spain: occurrence in the MSS of a siliceous landscape

Author

Ledesma, Enrique, primary, Jiménez-Valverde, Alberto, additional, Salgado, José María, additional, and Ortuño, Vicente M., additional

Published

2022

40. Plusiocampa (Plusiocampa) imereti Sendra & Barjadze 2021, sp. nov

Author

Sendra, Alberto, Palero, Ferran, Sánchez-García, Alba, Jiménez-Valverde, Alberto, Selfa, Jesús, Maghradze, Eter, and Barjadze, Shalva

Subjects

Campodeidae, Arthropoda, Plusiocampa, Animalia, Entognatha, Diplura, Biodiversity, Taxonomy, Plusiocampa imereti

Abstract

Plusiocampa (Plusiocampa) imereti Sendra & Barjadze sp. nov. urn:lsid:zoobank.org:act: 40C3DB96-19CD-4354-ACA9-434F0ADA34BB Figs 2���12 Diagnosis Troglomorphic species. Antennae with 39���45 antennomeres; 12 complex olfactory chemoreceptors within cupuliform organ; non-protruding frontal process slightly protruding, plain, with non-tubercular setae or just slightly tubercular. Pronotum 1+1 ma, 2+2 la 1,2 , 2+2 lp 2,3 ; mesonotum with 1+1 ma, 3+3 la 1���3 , 2+2 lp 2,3 , 1+1 mp; metanotum with 1+1 ma, 2+2 la 1,2 or sla 1,2 , 1+1 lp 2 , 1+1 mp; thin; all notal macrosetae long and covered by thin barbs on half to distal portions; thin, middle-sized clothing setae covered by 0���4 thin distal barbs. Legs elongated, pretarsus of metathoracic legs slightly overpasses end of abdomen. Femora I���III with one long, barbed dorsal macroseta and one shorter, barbed ventral macroseta. Tibiae I���III with two short barbed ventral macrosetae. Claws unequal (posterior claw 1.3 �� as long as anterior one); large, backward overhang on posterior claw; lateral crests well-developed. Pretarsal process long and setiform. Urotergites 1+1 post 1 on I���II; 0+0, 0+1 or 1+1 la, 1+1 or 2+2 post 1,2 on III; 1+1 la 3 , 2+2 to 4+4 post 1���4 on IV; 2+2 la 2,3 , 4+4 post 1���4 on V���VII; 6+6 post 1���6 on VIII and 8+8 or 8+7 post 1���8 on abdominal IX. Urosternite I with 8+8���7+7 macrosetae (Figs 8���9); urosternites II���VII with 6+6 macrosetae; urosternite VIII with 2+2 macrosetae. Male urosternite I (Fig. 8) with slightly enlarged subcylindrical appendages, each bearing up to 21 glandular a 1 setae. Female appendages slightly thinner, with up to 11 glandular a 1 setae. Etymology The specific epithet refers to the Imereti region, the location of the Shvilobisa Cave, treated as a noun in apposition. Type material Holotype GEORGIA ��� ♀, ���holotype-♀ IZISU-TD-T-00001���; Shvilobisa Cave, Bunikauri village, Chiatura Municipality, Imereti region, Zemo Imereti Plateau; 42��19���31.44��� N, 43��16���4.33��� E; 24 Feb. 2018; Shalva Barjadze and Eter Maghradze leg.; IZISU-TD-T-00001. Paratypes GEORGIA ��� 1 ♂, ���paratype-♂1 IZISU-TD-T-00002���; same collection data as for holotype; IZISU- TD-T-00002 ��� 1 ♀, ���paratype-♀1 MZB (MCNB) 2021-2336���; same locality as for holotype; 20 Jul. 2020; Eter Maghradze leg.; MZB (MCNB) 2021-2336 ��� 1 ♀, ���paratype-♀2 MZB (MCNB) 2021-2337���; same collection data as for preceding; MZB (MCNB) 2021-2337 ��� 1 ♂, ���paratype-♂2 Coll AS���; same collection data as for preceding; Coll AS. Other material GEORGIA ��� 2 specs, unknown sex [for SEM photography and one specimen for DNA analysis]; Shvilobisa Cave; 24 Feb. 2018; Shalva Barjadze and Eter Maghradze leg. ��� 2 specs [for SEM photography and one for DNA analysis]; same collection data as for preceding; 20 Jul. 2020; Eter Maghradze leg. Other material from two other caves (all Coll AS) GEORGIA ��� 1 ♀; Kumistavi village Tskaltubo Municipality, Imereti Region, Sataplia-Tskaltubo karst massif, Datvis (Bear) Cave; 42��22���28������ N, 42��35���45��� E; 5 Jul. 2018; Eter Maghradze leg. ��� 1 ♀; same collection data as for preceding; 1 Sept. 2019 ��� 1 ♂; near Melouri village, Tskaltubo Municipality, Imereti Region, Sataplia-Tskaltubo karst massif, Melouri Cave; 42��23���15.1��� N, 42��37���41.5��� E; 1 Nov. 2018; Eter Maghradze leg. Description BODY. Body length 4.3���7.2 mm (females) and 4.9���5.2 mm (males) (Table 1). Epicuticle smooth under optical microscope and SEM; body with thin, middle-sized clothing setae covered by 0���4 thin distal barbs. HEAD. Three intact antennae, all slightly longer than body length, with 39���45 antennomeres (Table 1). Small, thin, subcylindrical sensillum on third antennomere located in ventral position between c and d macrosetae. Central antennomeres 2.1 �� as long as wide, apical antennomere 3.0 �� as long as wide. Cupuliform organ occupying ⅓ of total length of apical antennomere, with about 12 complex olfactory chemoreceptors. Each olfactory chemoreceptor is composed of a complete fold surrounding a central cylinder with two lateral expansions, entirely reticulated and perforated (Fig. 5). Gouge sensilla 30��� 40 ��m long, in a single distal whorl of 13���16 sensilla on each medial and distal antennomere. Frontal process slightly protruding, plain, with non-tubercular setae or just slightly tubercular on distal portion (Fig. 3); macrosetae along the insertion line of antennomere and i macrosetae and x setae longer than other macrosetae (a / i / p/ x with relative lengths of 25 / 36 / 19 / 37 in holotype). Suboval labial palps with a bacilliform latero-external sensillum, two guard setae, up to 7 setae on anterior border, and up to 130 neuroglandular setae in holotype. THORAX. Thoracic macrosetal distribution (Figs 2, 4, 6): pronotum with 1+1 ma, 2+2 la 1���2 , 2+2 lp 2,3 ; mesonotum with 1+1 ma, 3+3 la 1���3 , 2+2 lp 2,3 , 1+1 mp; metanotum with 1+1 ma, 2+2 la 1,2 or sla 1,2 , 1+1 lp 2 , 1+1 mp. All notal macrosetae are long and covered by thin barbs on half to distal portions (Figs 4, 6); submacrosetae sla are thinner and shorter than notal macrosetae; marginal setae are similar to clothing setae, and covered by 1���8 thin distal barbs. Legs elongated, pretarsus of metathoracic legs slightly overpasses end of abdomen (Table 1). Femora I���III with one long, barbed dorsal macroseta and one shorter, barbed ventral macroseta. Tibiae I���III with two short barbed ventral macrosetae. Calcars with 4���5 long barbs. Tarsi with two rows of thicker ventral setae with 2���3 very thin barbs on middle portion. Two dorsal and one ventral, smooth, subapical tarsal setae. Claws are unequal (posterior claw 1.3 �� as long as anterior one); large, backward overhang on posterior claw; lateral crests well-developed. Pretarsal process long and setiform, overpassing end of claws. ABDOMEN. Distribution of abdominal macrosetae on tergites (Fig. 7): 1+1 post 1 on I���II; 0+0, 0+1 or 1+1 la, 1+1 or 2+2 post 1,2 on III; 1+1 la 3 , 2+2 to 4+4 post 1���4 on IV; 2+2 la 2,3 , 4+4 post 1���4 on V���VII; 6+6 post 1���6 on VIII and 8+8 or 8+7 post 1���8 on abdominal segment IX. All post urotergal macrosetae long and covered by thin barbs along distal four-fifths (Fig. 10); la urotergal macrosetae shorter than post macrosetae, covered by barbs along distal half. Urosternite I with 8+8���7+7 macrosetae (Figs 8���9); urosternites II���VII with 6+6 macrosetae; urosternite VIII with 2+2 macrosetae (Fig. 12); all urosternal macrosetae robust and large, covered by long barbs along distal third to four-fifths. Apical, subapical and ventromedial setae with a few (two to four) thin, short and long barbs (Fig. 11). SECONDARY SEX CHARACTERS. Male urosternite I (Fig. 8) with slightly enlarged subcylindrical appendages, each bearing up to 21 glandular a1 setae. Female appendages slightly thinner, with up to 11 glandular a 1 setae. Spermatozoid fascicles 40 ��m in diameter without apparently spiral filament. Molecular analysis The nucleotide substitution model selected was GTR+G+I (BIC = 6998.6), with the proportion of invariant sites (I = 0.46) and estimated alpha parameter for the gamma distribution (�� = 1.39), indicating a significant heterogeneity in the DNA substitution among sites. The Campodeidae sequences formed a well-supported clade, clearly distinct from that of Japygidae (Fig. 13). Although bootstrap values were low, the ML phylogenetic tree grouped Plusiocampa (P.) imereti Sendra & Barjadze sp. nov. with Eastern Europe taxa such as Plusiocampa (Plusiocampa) aff. elongata Ionescu, 1955 and Plusiocampa (Plusiocampa) humicola Ionescu, 1955, whereas Iberian Peninsula taxa (Plusiocampa (Plusiocampa) gadorensis Sendra, 2001, Plusiocampa (Plusiocampa) baetica Sendra, 2004 and Cestocampa iberica Sendra & Cond��, 2012) clustered in a distinct clade. K2P genetic distances also showed P. (P.) aff. elongata (0.206�� 0.027) and P. (P.) humicola (0.205 �� 0.028) to be the closest species to the new Plusiocampa (P.) imereti Sendra & Barjadze sp. nov. from Georgia. Habitat Plusiocampa (Plusiocampa) imereti Sendra & Barjadze sp. nov. inhabits the deep zone (over 50 m from the entrance) of three caves. The Shvilobisa Cave, the type locality, is a 1000 m long, tunnellike, easily accessible sub-horizontal cave with a small subterranean water stream (Tatashidze et al. 2009b). The others two nearby caves are about 55 km away from the Shvilobisa Cave; the Melouri Cave is 5300 meters long and has the status of natural monument (Tatashidze et al. 2009b), whereas the Datvis Cave is a poorly known cavern (K. Tsikarishvili, pers. comm.). The distance between the Datvis and Melouri caves is ca 3.5 km. The Melouri Cave ��� easily accessible ��� has dried halls and a permanent subterranean water stream near its end. This cave has gigantic stalagmites and fallen stones. The Datvis Cave is a horizontal, dry, and easily accessible cave with several halls, which are rich in different speleothems like the Shvilobisa Cave (Tatashidze et al. 2009b). Invertebrate cavernicolous species of the studied caves The three caves (Shvilobisa, Datvis, and Melouri) which Plusiocampa (Plusiocampa) imereti Sendra & Barjadze sp. nov. inhabits are also the dwellings of other troglobitic arthropod species. Datvis and Melouri caves share three troglobitic species: the Diplopoda Leucogeorgia prometheus Antić & Reip, 2020, the Isopoda Colchidoniscus kutaissianus Borutzky, 1974, and the Pseudoscorpionida Chthonius satapliaensis Schawaller & Dashdamirov, 1988. In addition, the Insecta (Carabidae Coleoptera) Troglocimmerites imereti Dolzhanski & Ljovuschkin, 1985 dwells in the Datvis cave; and the Melouri Cave has five more species: the Opiliones Nemaspela melouri Martens, Maghradze & Barjadze, 2021, the Araneae Centromerus bulgarianus Drensky, 1931, the Hexapoda Collembola Pseudacherontides zenkevitchi Djanashvili, 1971; the Insecta (Carabidae Coleoptera) Inotrechus kurnakovi Dolzhanski & Ljovuschkin, 1989; and Troglocimmerites sp. 1. In the Shvilobisa Cave, eight troglobitic species dwell: the Diplopoda Leucogeorgia gioi Antić & Reip, 2020, the Isopoda Caucasonethes cf. borutzkyi Verhoeff, 1932 and Colchidoniscus sp., the Pseudoscorpionida Chthonius satapliaensis Schawaller & Dashdamirov, 1988, the Opiliones Nemaspela sp., the Hexapoda Collembola Oncopodura sp. and Pseudosinella sp., and the Insecta (Carabidae Coleoptera) Troglocimmerites sp. 2. (Barjadze et al. 2019; Maghradze et al. 2019; Antić & Reip 2020; Martens et al. 2021; Maghradze & Barjadze, unpublished data)., Published as part of Sendra, Alberto, Palero, Ferran, S��nchez-Garc��a, Alba, Jim��nez-Valverde, Alberto, Selfa, Jes��s, Maghradze, Eter & Barjadze, Shalva, 2021, A new Diplura species from Georgia caves, Plusiocampa (Plusiocampa) imereti (Diplura, Campodeidae), with morphological and molecular data, pp. 71-85 in European Journal of Taxonomy 778 on pages 74-79, DOI: 10.5852/ejt.2021.778.1567, http://zenodo.org/record/5675209, {"references":["Ionescu M. A. 1955. Diplura. In: Academia Republicii Socialiste Romania (ed.) Fauna Republicii Populare Romane, Insecta 7 (2): 1 - 48.","Sendra A., Lara M. D., Ruiz Aviles F. & Tinaut A. 2004. Une nouvelle espece du genre Plusiocampa Silvestri, 1912 (Diplura, Campodeidae) et donnees pour sa reconstruction paleobiogeographique dans les Betiques. Subterranean Biology 2: 113 - 122.","Tatashidze Z. K., Tsikarishvili K. D. & Jishkariani J. M. 2009 b. The Cadastre of the Karst Caves of Georgia. Petiti Publishing House, Tbilisi [in Georgian].","Antic D. Z & Reip H. R. 2020. The millipede genus Leucogeorgia Verhoeff, 1930 in the Caucasus, with descriptions of eleven new species, erection of a new monotypic genus and notes on the tribe Leucogeorgiini (Diplopoda: Julida: Julidae). European Journal of Taxonomy 713: 1 - 106. https: // doi. org / 10.5852 / ejt. 2020.713","Martens J., Maghradze E. & Barjadze Sh. 2021. Two new species of the genus Nemaspela Silhavy from caves in Georgia (Opiliones: Nemastomatidae). Zootaxa 4951 (3): 541 - 558. https: // doi. org / 10.11646 / zootaxa. 4951.3.7","Barjadze Sh., Arabuli T., Mumladze L., Maghradze E., Asanidze Z. & Shavadze R. 2019. Cave Biodiversity of Georgia, Open Access Database. Institute of Zoology at Ilia State University. Available from https: // cbg. iliauni. edu. ge / en / [accessed: 20 Apr. 2021].","Maghradze E., Faille A., Barjadze Sh. & Hlavac P. 2019. A new cavernicolous species of the genus Bergrothia Reitter, 1884 (Coleoptera, Staphylinidae, Pselaphinae) from Georgia. Zootaxa 4608 (2): 371 - 379. https: // doi. org / 10.11646 / zootaxa. 4608.2.11"]}

Published

2021

41. A new Diplura species from Georgia caves, Plusiocampa (Plusiocampa) imereti (Diplura, Campodeidae), with morphological and molecular data

Author

Sendra, Alberto, primary, Palero, Ferran, additional, Sánchez-García, Alba, additional, Jiménez-Valverde, Alberto, additional, Selfa, Jesús, additional, Maghradze, Eter, additional, and Barjadze, Shalva, additional

Published

2021

42. Pacificampa Chevrizov 1978

Author

Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús, and Jiménez-Valverde, Alberto

Subjects

Pacificampa, Campodeidae, Arthropoda, Animalia, Entognatha, Diplura, Biodiversity, Taxonomy

Abstract

Genus Pacificampa Chevrizov, 1978 Diagnosis (based on Chevrizov 1978) Thoracic macrosetae with no more than 3+3 macrosetae on pronotum, 4+4 on mesonotum (2+2 lateral posterior included), and 2+2 on metanotum (1+1 lateral posterior included). One dorsal macroseta on metathoracic femora and one or two on tibia. Subequal elbowed claws with ridges on dorsal side that look like very small lateral crests under optical microscope; without lateral processes. Urotergites V– VII with no more than 1+1 medial posterior, 1+1 lateral anterior and 2+2 lateral posterior macrosetae and on urotergite VIII with no more than 1+1 medial posterior and 3+3 lateral macrosetae. Up to 7+7 macrosetae on first urosternite, 5+5 macrosetae on second to seventh urosternites, and 1+1 macrosetae on eighth urosternite. First urosternite in males with thick appendages with large field of glandular a1 setae., Published as part of Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús & Jiménez-Valverde, Alberto, 2021, Asian cave-adapted diplurans, with the description of two new genera and four new species (Arthropoda, Hexapoda, Entognatha), pp. 1-46 in European Journal of Taxonomy 731 on page 22, DOI: 10.5852/ejt.2021.731.1199, http://zenodo.org/record/4422557, {"references":["Chevrizov B. P. 1978. Two new genera of the Family Campodeidae from the Far East Caves. Zoologichesky Zhurnal 57 (2): 197 ‾ 205."]}

Published

2021

43. Pacificampa wudonghuii Sendra & Komerički & Lips & Luan & Selfa & Jiménez-Valverde 2021, sp. nov

Author

Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús, and Jiménez-Valverde, Alberto

Subjects

Pacificampa, Pacificampa wudonghuii, Campodeidae, Arthropoda, Animalia, Entognatha, Diplura, Biodiversity, Taxonomy

Abstract

Pacificampa wudonghuii Sendra sp. nov. urn:lsid:zoobank.org:act: 447EE93A-F466-4C66-827A-0751A259070F Figs 51–64 Etymology This species is dedicated to Professor Wu Donghui, from the Northeast Institute of Geography and Agroecology (NEIGAE), Chinese Academy of Sciences, Changchun (China), for his enthusiastic contribution and support to the knowledge of Northern China soil and cave biodiversity. Type material Holotype CHINA • ♀; Liaoning Province, Benxi, Huanren, Xianren Dong; 17 May 2019, L. Deharveng, A. Bedos and Wu Donghui leg.; labelled “CHILN19-005-holotype”; NEIGA-diplura-01. Paratypes CHINA • 1 ♀, 1 juvenile, same collection data as for holotype; labelled “CHILN19-005-female paratype”; MZB (MCNB) 2020-1160 • 1 juvenile; same collection data as for preceding; labelled “CHILN19- 005-juvenile paratype”; MZB (MCNB) 2020-1161 • 1 ♀; Liaoning Province, Benxi, Huanren, Pylon cave; 17 May 2019; L. Deharveng, A. Bedos and Wu Donghui leg.; labelled “CHILN19-007-female paratype”; MZB (MCNB) 2020-1164. Other material examined CHINA • 1 ♂, same collection data as for holotype; mounted on an aluminium stage and coated with palladium-gold; Coll. AS. Description BODY. Length 6.5–6.9 mm in females; 3.9 mm in one juvenile. Epicuticle smooth under optical microscope but well reticulated under high magnifications as one can see irregular polygonal structures of variable sizes with scattered external glands either visible or covered with secretion (Figs 51, 53); body with smooth clothing setae. HEAD. Antennae broken in all specimens; central antennomeres with two whorls of distal barbed macrosetae and uneven short setae; in addition, with single distal whorl of up to 8–12 gouge sensilla of 22–29 µm long (Fig. 51) and among them one or two small coniform sensilla (5 µm long). Proximal antennomeres with typical trichobothria disposition with bacilliform sensillum (9–10 µm long) on third antennomere in ventral position, between c–d macrosetae (Fig. 52). Plain frontal process with one anterior macrosetae, longer than clothing setae. Three macrosetae along each side of insertion line of antennomere and x setae with length ratios of a / i / p / x, 42/55/42/45, respectively, in holotype (Fig. 54). Large suboval labial palps, each with enlarged coniform latero-external sensillum near two gard setae and eight normal setae on anterior portion, up to 150 neuroglandular setae in medial and posterior positions. THORAX. Thoracic macrosetae distribution: pronotum has 1+1 ma, 1+1 la, 1+1 lp macrosetae; mesonotum has 1+1 ma, 1+1 la and 2+2 lp macrosetae; and metanotum has 1+1 ma and 1+1 lp macrosetae. Long macrosetae with long barbs in distal three-fourths; marginal setae longer than clothing setae, which are barbed from distal half to three-fourths. Legs elongated, metathoracic legs reach posterior border of seventh abdominal segment. Mesothoracic and metathoracic femora have one dorsal macroseta each, barbed along distal three-fourths (Fig. 55), absent in prothoracic femora. Calcars with two or three long barbs in middle (Fig. 56). Prothoracic and mesothoracic tibia with one short ventral macrosetae with one apical barb and two in metathoracic tibia (Fig. 57). Each tarsus with two separated ventral rows of thicker and longer setae among clothing setae, and a few setiform sensilla (Fig. 58). Three long smooth dorsal tarsal and one ventral setae. Subequal elbowed claws with smooth ventral surface ridged on dorsal side that can be mistaken for lateral crests under optical microscopes, between a blunt unguiculus and without lateral processes (Figs 59–60). ABDOMEN. Distribution of abdominal macrosetae on tergites (Fig. 61 shows 1+1 ma on III in the paratype from Grotte du Pylone, but absent in Xianren Dong Cave types; 1+1 ma, 1+1 la and 2+2 lp on IV–VII; 1+1 mp and 3+3 lp on VIII and 1+1 mp and 5+5 lp on IX abdominal; ma and la macrosetae with barbs in distal half to one third and shorter than mp and lp macrosetae, which bear long barbs along distal four-fifths. Urosternite I with 7+7 macrosetae (Fig. 62); urosternites II to VII with 4+4 macrosetae (Fig. 63); urosternite VIII with 1+1 macrosetae (Fig. 64); urosternal macrosetae of varying lengths, with one apical to twenty distal long barbs. Stylus setae smooth, apical and subapical setae shorter than ventromedial seta (Fig. 63). SECONDARY SEX CHARACTERS. Female urosternite I with subcylindrical appendages, each bearing up to 40 glandular a 1 setae in apical field. Male urosternite I with thick short, and subcylindrical appendages, each with large apical field of about 220 glandular a 1 setae (Fig. 62). Taxonomic affinities Pacificampa wudonghuii sp. nov. shares with P. birsteini Chevrizov, 1978, P. caesa Chevrizov, 1978 and P. nipponica Sendra, 2018 the same distribution of notal macrosetae (1+1 medial anterior, 1+1 lateral anterior, and 1+1 lateral posterior macrosetae on pronotum; 1+1 medial anterior, 1+1 lateral anterior, and 2+2 lateral posterior macrosetae on mesonotum; and 1+1 medial anterior and 1+1 lateral anterior macrosetae on metanotum). An undescribed species mentioned by Ferguson (1997) from northeastern China also has this setal distribution. However, P. wudonghuii sp. nov. differs from other species of Pacificampa in having 1+1 medial anterior, 1+1 lateral anterior, and 2+2 lateral posterior macrosetae on the fourth urotergite (Fig. 61), a pattern distribution that begins on the fifth urotergite for the other species. In addition, the larger male appendages have more abundant glandular a 1 setae in P. wudonghuii sp. nov. (Fig. 62) than in the other species of Pacificampa.

Published

2021

44. Anisuracampa ywangana Sendra & Komericki 2021, sp. nov

Author

Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús, and Jiménez-Valverde, Alberto

Subjects

Campodeidae, Arthropoda, Animalia, Entognatha, Diplura, Biodiversity, Anisuracampa, Anisuracampa ywangana, Taxonomy

Abstract

Anisuracampa ywangana Sendra & Komerički sp. nov. urn:lsid:zoobank.org:act: 511F81B5-6CB2-4A98-AB3E-11AF72205A26 Figs 1, 3–19; Tables 1–2; Supp. file 2 Etymology This species is named after the important karst region Ywangan in Myanmar, the location of Win Twin Cave (Figs 1, 3–4). Type material Holotype MYANMAR • ♀; Shan State, Ywangan, Win Twin Cave; 21º11′51.47″ N, 96º32′40.34″ E; 16 Nov. 2018; Aung Lin leg.; labelled “holotype”; MZB (MCNB) 2020-1152. Paratypes MYANMAR • 1 ♀; same collection data as for holotype; labelled “paratype-H1”; MZB (MCNB) 2020- 0620 • 1 ♀, 1 ♂, 1 juvenile; same collection data as for holotype; 8 May 2018; labelled “paratype-H2”, “paratype-M”, “paratype-J”; MZB (MCNB) 2020-1153, MZB (MCNB) 2020-1155, MZB (MCNB) 2020-1154. Other material examined MYANMAR • 2 specs; same collection data as for the holotype; 8 May 2018; mounted on two separate aluminium stages and coated with palladium-gold; Coll. AS. Description BODY. Length is 4.3–6.0 mm (n = 4) in adults and 2.6 mm in one juvenile (Table 1). The epicuticle is smooth under optical microscope but reticulated at higher magnification, showing irregular polygonal structures of variable sizes (Fig. 11). Body with long smooth clothing setae. HEAD. Two complete and intact antennae in holotype and paratype-M with 35 antennomeres each, whereas paratype-J (juvenile) has 38 antennomeres. The antennae are similar to length of body (Table 1), with medial antennomeres 2× as long as wide but apical antennomeres 1½ × as long as wide. Cupuliform organ with up to 17 spheroidal olfactory chemoreceptors arranged in two uneven concentric circles; each chemoreceptor forms a complex structure of multi–perforated folds with one distinguishing crown of fringes a surrounding central column. Each of these structures is inside a polygonal cell (Figs 5–6). Distal and central antennomeres with three whorls of distal barbed macrosetae and 5–6 scattered whorls of smooth setae in addition to single distal whorl of up to 14 gouge sensilla of 24–28 µm length (Figs 7–8) that are more abundant on dorsal side of antennomere. Proximal antennomeres with typical trichobothria, plus small bacilliform sensillum on third antennomere in ventral position. Round protrusion of frontal process covered with one anterior macroseta and two or three posterior macrosetae (Fig. 10). Three macrosetae along each side of insertion line of antennomere and x setae with thin distal barbs; length ratios of a / i / p / x, 45/57/56/65, respectively, in paratype-H2. Labial palps large and suboval, each with bacilliform latero-external sensillum, two guard setae, up to 18 normal setae and up to 140 neuroglandular setae. THORAX. Thoracic macrosetae distribution (Figs 9, 11) have pronotum with 1+1 ma, 1+1 la, 2+2 lp 2,3 macrosetae; mesonotum with 1+1 ma, 2+2 la and 4+4 lp 1–4 macrosetae; and metanotum with 1+1 ma, 2+2 la and 3+3 lp 1–3 macrosetae. All macrosetae long and with thin barbs along basal half to twothirds of each seta; marginal setae barbed and longer than clothing setae. Legs elongated, metathoracic legs reach end of abdomen in adults or overpass it in juvenile. Tibia always longer than femur or tarsus (Table 1). Each femur III with three or, less frequently, two long dorsal macrosetae with distal barbs (0.25 mm in 0.62 mm femur of paratype-H1) (femora I–II with one to three long dorsal macrosetae). Calcars covered with thin abundant barbs all over. Tibiae I–III usually with two short, completely barbed ventral macrosetae, occasionally just one. Each tibia with two rows of ventral barbed setae almost from base and scattered throughout with thin, long setiform sensilla. Three well-barbed dorsal distal tarsal setae longer than rest of tarsal setae. Subequal claws with lateral expansion in crest; basal and ventral portion of claws covered with short to long spiniform formations. Laminar pretarsus of lateral processes sharply curved with what apparently looks like thin fringes under optical microscope, but under SEM seen as narrow laminar expansions (Figs 12–15). ABDOMEN. Distribution of macrosetae on tergites with 1+1 post 1 on I–III; 1+1 post 1 to 3+3 post 1–3 on IV, 4+4 post 1–4 and 1+1 la on V, 5+5 post 1–5 or 6+6 post 1–6 and 1+1 la on VI–VII; 7+7 post on VIII; and 8+8 or 9+9 post macrosetae on IX abdominal segment. All tergal abdominal macrosetae long and barbed along distal half to four-fifths. Urosternite I has 7+7 macrosetae (Figs 16–17); while urosternites II to VII with 5+5 macrosetae; and urosternite VIII with 1+1 macrosetae; urosternal macrosetae of medium size and barbed along distal half. Stylus with short apical seta with small barbs, and each subapical seta completely covered with barbs and with short, barbed ventromedial seta (Figs 18–19). One intact cercus 2.4 × body length and with 14 primary articles (Table 2). Article length increases from proximal to distal articles; covered with long thin macrosetae, with distal barbs, and less abundant long, thin setae. Each primary article with whorl of shorter thin plumose setae at distal position. SECONDARY SEX CHARACTERS. Female urosternite I with enlarged subcylindrical appendages, each bearing up to 60 ventral glandular a 2 setae proximally and apical field of up to 28 glandular a 1 setae (Figs 16–17). Male with similar appendages with two fields of glandular setae (19 a 2 and 27 a 1) in one appendage of male paratype. Spermatozoid fascicles small, 0.04 mm in diameter, and formed by undistinguishable filament of spermatozoids in spiral. Taxonomic affinities Anisuracampa was proposed for a soil-dwelling species, Anisuracampa suoxiensis Xie & Yang, 1990 from Hunan Province in southeastern China. As a plusiocampine genus, Anisuracampa is characterized by the laminar pretarsus but with the lateral processes with long barbs and weakly developed lateral crests (Figs 12–15) (see Xie & Yang 1991: fig. 34). In addition to this trait, Anisuracampa has two or three dorsal femoral macrosetae and 1+1 macrosetae on the eighth urosternite. All of these characters are present in A. ywangana sp. nov., a cave-adapted species from the Win Twin Cave in eastern Myanmar. Therefore, these morphological similarities together with the congruent geographical distribution in Southeast Asia are considered sufficient reason to place this new species in Anisuracampa. However, A. ywangana sp. nov. differs from A. suoxiensis in several characters besides the traits related to adaptations to cave ecosystems. Anisuracampa ywangana sp. nov. has 4+4 lateral posterior macrosetae on the mesonotum (Fig. 9) (2+ 2 in A. suoxiensis), 3+3 lateral posterior and 2+2 lateral anterior macrosetae on the metanotum (2+2 lateral posterior and no lateral anterior macrosetae in A. suoxiensis) and 5+5 posterior and 1+1 lateral anterior macrosetae on urotergites V–VII (4+4 posterior and no lateral anterior macrosetae in A. suoxiensis). Regarding the new species’ cave-adapted features, it has a larger body and longer appendages at least double the size of those of A. suoxiensis, with 30–35 antennomeres in A. ywangana sp. nov. (24 in A. suoxiensis). It is impossible to compare other useful taxonomical characteristics mentioned in the description of A. ywangana sp. nov. with A. suoxiensis as the former was described using SEM, whereas the latter was described under optical observations with a brief diagnosis and the type material of A. suoxiensis is not available for study. Remarks Anisuracampa ywangana sp. nov. was observed and collected walking on the Win Twin cave floor and boulders, approximately 300 m from the entrance, and on the wet flowstone in a vast chamber (Figs 1–3; Supp. file 2). The Win Twin cave is located within a large karst area referred to as Ywangan karst, which is situated in the western part of the Shan plateau, approximately 10 km northeast of Ywangan Township and 15 km east of the Panlaung Pyadalin Wildlife Sanctuary. The cave has only been discovered recently and is currently under tourist development by the local community. It has not been fully surveyed and approximately only the first 400 m were explored during the collection of the type material. The cave itself is large, with numerous chambers, and its entrance was enlarged by mining (Fig. 4); after approximately 300 m into the main passage, it opens into a vast chamber filled with speleothems (Fig. 3), from which it again continues further by smaller, narrow passages opening into new chambers. At the bottom of the vast chamber, the oxygen level becomes too low for further exploration during the dry season (May), while by the end of the rainy season (November) it was possible to reach two further lower chambers before the oxygen level became too low. No active water flow was observed, but sparse remains of particular organic matter are present and the air temperature recorded in May 2018 was 20.0°C, while the sediment temperature was 19.6°C (unpublished data)., Published as part of Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús & Jiménez-Valverde, Alberto, 2021, Asian cave-adapted diplurans, with the description of two new genera and four new species (Arthropoda, Hexapoda, Entognatha), pp. 1-46 in European Journal of Taxonomy 731 on pages 4-9, DOI: 10.5852/ejt.2021.731.1199, http://zenodo.org/record/4422557, {"references":["Xie R. & Yang Y. 1991. Description of two new genera and three new species of Campodeidae in China (Diplura). Contribution Shanghai Institute of Entomology 10: 95 ‾ 102."]}

Published

2021

45. Hubeicampa melissa Sendra & Komerički & Lips & Luan & Selfa & Jiménez-Valverde 2021, gen. et sp. nov

Author

Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús, and Jiménez-Valverde, Alberto

Subjects

Hubeicampa, Campodeidae, Arthropoda, Hubeicampa melissa, Animalia, Entognatha, Diplura, Biodiversity, Taxonomy

Abstract

Hubeicampa aff. melissa Sendra & Lips gen. et sp. nov. Material examined CHINA • 3 ♂♂ (6.6 to 8.0 mm), 1 ♀ (9.6 mm), 1 juv. (5.5 mm); Hubei, Banqiao, Kedu Dong (Grotte des Têtards); 6 Aug. 2009; Josiane Lips leg.; Coll. AS. Remark Specimens from Kedu Dong are considered as H. aff. melissa gen. et sp. nov. due to the specimens’ bad condition which does not allow us to clearly observe any variations in the taxonomical features. Nevertheless, they have the same important traits as the new species, but there is no dorsal macrosetae on the femur, except in a juvenile. Taxonomic affinities Hubeicampa melissa Sendra & Lips gen. et sp. nov. is closely related to another cave-adapted species, Hubeicampa lipsae (Condé, 1993), which is a new combination of Plusiocampa (Dydimocampa) lipsae Condé, 1993, and thus leads us to propose Hubeicampa as a new genus for both species that live in karst regions of the Chinese province of Hubei. The new genus is distinguished by the pretarsus, which has lateral crests and a laminar lateral process covered by spiniform formations and micro-barbs, pubescent setae and macrosetae (Figs 36–39), as well as by 1+1 macrosetae on the eighth urosternite. A significant number of taxonomic characters separates H. melissa gen. et sp. nov. from H. lipsae. The most relevant differences are in the number of macrosetae on the mesonotum (Fig. 30) (with 1+1 medial anterior, 1+1 lateral anterior and 1+1 medial posterior macrosetae in H. melissa gen. et sp. nov. instead of 1+1 medial anterior and 2+2 lateral posterior macrosetae in H. lipsae), and the number of macrosetae on metanotum (with 1+1 medial anterior macrosetae and none or 1+1 medial posterior submacrosetae instead of 1+1 medial anterior and 1+1 lateral posterior in H. lipsae). Other important features are the larger lateral crests in the pretarsus of H. melissa gen. et sp. nov. (Figs 36–37) the presence of one dorsal macroseta on the metathoracic femora, and one ventral macroseta on the metathoracic tibia in H. melissa gen. et sp. nov. instead of two dorsal femora and two ventral tibia macrosetae in H. lipsae. Finally, there are 4+4 posterior macrosetae on V–VII urotergites in H. melissa gen. et sp. nov. (Fig. 40) instead of 3+ 3 in H. lipsae. Remarks Hubeicampa melissa Sendra & Lips gen. et sp. nov. lives in the “Grotte du 8 ième Ciel Baxian Dong”, a cave situated at an elevation of 1870 m in the mountain near Banqiao village in the Hubei Province. The cave is 1703 m long and 122 m deep, with a huge entrance and giant galleries, as well as narrow passages and a narrow independent entry. The holotype of Hubeicampa melissa gen. et sp. nov. was observed and collected on the cave floor at about 300 m from the huge entry and at the top of the - 40 m deep pit on clay ground above the Saltpetre passage (Lips et al. 2009) (Figs 46–48). Some paratypes were collected in the same cave in the big chamber “Grande galerie du Va-et-Vient”., Published as part of Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús & Jiménez-Valverde, Alberto, 2021, Asian cave-adapted diplurans, with the description of two new genera and four new species (Arthropoda, Hexapoda, Entognatha), pp. 1-46 in European Journal of Taxonomy 731 on pages 14-18, DOI: 10.5852/ejt.2021.731.1199, http://zenodo.org/record/4422557, {"references":["Conde B. 1993. Premiers Campodeidae cavernicoles de China, comme exemple de l'evolution souterraine de la Famille (Diplura). Revue suisse de Zoologie 100 (4): 823 ‾ 828. Available from https: // www. biodiversitylibrary. org / page / 41223963 [accessed 19 Nov. 2020].","Lips B., Faverjon M., Routhieau V., Schalk P. & Lips J. 2009. Rapport de la 8 ieme expedition speleologique en Chine, provinces de l'Hubei et du Sichuan. Aventures karstiques lointaines & Institut de technologie de Chengdu. Speleologie au pays de l'Homme sauvage 8: 1 ‾ 112."]}

Published

2021

46. Hubeicampa Sendra & Komerički & Lips & Luan & Selfa & Jiménez-Valverde 2021, gen. nov

Author

Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús, and Jiménez-Valverde, Alberto

Subjects

Hubeicampa, Campodeidae, Arthropoda, Animalia, Entognatha, Diplura, Biodiversity, Taxonomy

Abstract

Genus Hubeicampa Sendra & Lips gen. nov. urn:lsid:zoobank.org:act: 3992F636-8036-4734-ACA6-A4972A157D82 Type species Hubeicampa lipsae (Condé, 1993) comb. nov. Plusiocampa (Dydimocampa) lipsae Condé, 1993: 826, figs 2a–c. Diagnosis Dense pubescence of thin micro-barbs on setae. No more than 4+4 macrosetae on pronotum, 3+3 on mesonotum and 2+2 on metanotum. One or two dorsal macrosetae on metathoracic femora and one or two on tibia. Subequal elbowed claws with lateral crests; basal and ventral portion of claws covered with very small, thin, spiniform formations that look pubescent under optical microscope. Laminar lateral processes of the pretarsus completely covered with dense micro–barbs. Urotergites V–VII with 3+3 or 4+4 posterior macrosetae and without lateral anterior macrosetae. Up to 12+12 macrosetae on first urosternite, 4+4 or 5+5 macrosetae on second to seventh urosternites and 1+1 macrosetae on eighth urosternite. First urosternite in males without glandular g 1 setae and appendages with glandular a 1 setae. Etymology The genus name refers to the Chinese province of Hubei where the first cave-adapted dipluran was described., Published as part of Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús & Jiménez-Valverde, Alberto, 2021, Asian cave-adapted diplurans, with the description of two new genera and four new species (Arthropoda, Hexapoda, Entognatha), pp. 1-46 in European Journal of Taxonomy 731 on pages 10-11, DOI: 10.5852/ejt.2021.731.1199, http://zenodo.org/record/4422557, {"references":["Conde B. 1993. Premiers Campodeidae cavernicoles de China, comme exemple de l'evolution souterraine de la Famille (Diplura). Revue suisse de Zoologie 100 (4): 823 ‾ 828. Available from https: // www. biodiversitylibrary. org / page / 41223963 [accessed 19 Nov. 2020]."]}

Published

2021

47. Mueggejapyx Sendra & Komericki 2021, gen. nov

Author

Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús, and Jiménez-Valverde, Alberto

Subjects

Arthropoda, Japygidae, Animalia, Entognatha, Diplura, Biodiversity, Taxonomy, Mueggejapyx

Abstract

Mueggejapyx Sendra & Komerički gen. nov. urn:lsid:zoobank.org:act: 924B9ABA-1630-4832-86EE-19CE73C3E7CB Type species Mueggejapyx brehieri Sendra & Komerički gen. et sp. nov. Diagnosis Large and elongated body; antennae with 36 antennomeres; trichobothria on antennomeres 4–6 in a 3/5/5 pattern; a trichobothria in distal position; 1–2 placoid sensilla on medial and distal antennomere; apical antennomere with 16–18 placoid sensilla; dorsal and ventral side of head with numerous uniformly distributed sM and sm, and several M; five laminae pectinate on maxilla; elongated thoracic segments; and cuticle with tiny micro-holes, pronotum and mesonotum each with 5+5 M, metanotum with 2+2 M; strong internal Y cuticular furcisternite structures in pro-presternites and pro-, meso- and metasternites; urotergites with at most 1+1 M (ma), 1+1 M 1, 1+1 M 2–5; urite X longer than wide, with marked carinae with subparallel margins, with 2+2 intracarinal macrosetae; acropygium rounded; lateral angles of urotergites VI and VII with weakly to moderate lobiform projection; first urosternite with multiperforated surface and rounded protrusions, with 3+3 M on prescutum and 11+11 M on scutum; median glandular organ with seta-shaped sensilla; lateral subcoxal organs with one to three rows of short glandular setae (GS), one row of sensory setae (SS), and a row of setae with large socket; sternites with abundant sm and strong M; cerci strong, elongated, rectilinear and becoming curved subapically, heavily sclerotized with external dorsal and ventral carinae. Both cerci without medial tooth, but with one short row of small round denticles on the right cercus and two rows of small round denticles on the left cercus. Etymology This genus is dedicated to the memory of the American entomologist Mark Alan Muegge (pronounced Meggy), who died young due to an unfortunate car accident in 2015. He left behind a promising career and was devoted, among other groups, to diplurans; alongside other taxa, he provided a description of the highly cave-adapted japygid from Texas, Mixojapyx reddelli Muegge, 1992., Published as part of Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús & Jiménez-Valverde, Alberto, 2021, Asian cave-adapted diplurans, with the description of two new genera and four new species (Arthropoda, Hexapoda, Entognatha), pp. 1-46 in European Journal of Taxonomy 731 on pages 28-29, DOI: 10.5852/ejt.2021.731.1199, http://zenodo.org/record/4422557, {"references":["Muegge M. A. 1992. New species of cavernicolous japygid (Diplura: Japygidae) from Texas. Annals of the Entomological Society of America 85 (4): 406 ‾ 412. https: // doi. org / 10.1093 / aesa / 85.4.406"]}

Published

2021

48. Plutocampa speophila Chevrizov 1978

Author

Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús, and Jiménez-Valverde, Alberto

Subjects

Campodeidae, Plutocampa, Arthropoda, Animalia, Entognatha, Diplura, Biodiversity, Taxonomy, Plutocampa speophila

Abstract

Plutocampa speophila Chevrizov, 1978 Plutocampa speophila Chevrizov, 1978: 201, fig. 2(1‾9). Material examined RUSSIA • ♀, holotype (6 mm), 1 ♀ paratype (5 mm); Far East, Primorye region, Olgisk District, Priiskovaya cave; 3 Nov. 1966; S.I. Ljovuschkin leg.; slide; ZMMU Dip0007. Redescription (based on Chevrizov 1978) Under optical microscope it has a smooth cuticle covered by thin smooth clothing setae. Antennae are apparently intact with 23 antennomeres in the paratype, medial antennomeres 1.4 × as long as wide; third antennomere with a thick sensillum in ventral position (c–d macrosetae); last antennomere with at least eight olfactory chemoreceptors. Small and pointed frontal process has one long anterior smooth macrosetae and two shorter posterior macrosetae; there are three smooth macrosetae along each side of the line of insertion of antennomere and smooth x setae with a similar length, ratios of a / i / p / x are 20/23/22/23, respectively. Labial palps are large with thick sensilla. Pronotum with 1+1 ma, 3+3 (2+ 2 paratype) la, 2+2 lp 1,3 mesonotum with 1+1 ma, 3+3 (2+ 2 paratype) la, 2+2 lp 2,3 , 1+1 (0+ 1 paratype) mp and metanotum with 1+1 ma, 2+2 lp, 1+1 mp macrosetae, long and thin notal macrosetae covered with thin barbs along their distal three-fourths; marginal setae are long and some of them are as long and barbed as the macrosetae. The metathoracic legs reach the posterior border of the VII abdominal segment; femora have two long barbed dorsal macrosetae and one ventral macrosetae. The tibia has one ventral short macrosetae, a few distal barbs, and calcars with several long barbs. The tarsus has two rows of smooth ventral setae, slightly thicker than clothing setae and on distal part: three long smooth dorsal setae and one ventral seta; the pretarsus has no lateral processes, with unequal elbowed claws, and with large lateral crests. Urotergite I with 1+1 post 1 ; urotergite II 1+2 (1+ 1 paratype) post 1,2 ; urotergite III 2+2 post 1,2 ; urotergites IV–VII 4+4 post 1–4 ; urotergite VIII 5+5 post 1–5 and abdominal segment IX 7+7 post, macrosetae long with barbs along three-fourths. Urosternite I with 5+5, urosternites II–VII 4+4, and urosternite VIII 1+1 macrosetae; urosternal macrosetae are shorter than urotergal macrosetae with long barbs; smooth stylar setae. First urosternite appendages (female) have large, short and subconical appendages, each with apical field with about fifty glandular a 1 setae., Published as part of Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús & Jiménez-Valverde, Alberto, 2021, Asian cave-adapted diplurans, with the description of two new genera and four new species (Arthropoda, Hexapoda, Entognatha), pp. 1-46 in European Journal of Taxonomy 731 on page 20, DOI: 10.5852/ejt.2021.731.1199, http://zenodo.org/record/4422557, {"references":["Chevrizov B. P. 1978. Two new genera of the Family Campodeidae from the Far East Caves. Zoologichesky Zhurnal 57 (2): 197 ‾ 205."]}

Published

2021

49. Mueggejapyx brehieri Sendra & Komericki 2021, gen. et sp. nov

Author

Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús, and Jiménez-Valverde, Alberto

Subjects

Arthropoda, Japygidae, Animalia, Entognatha, Diplura, Biodiversity, Mueggejapyx brehieri, Taxonomy, Mueggejapyx

Abstract

Mueggejapyx brehieri Sendra & Komerički gen. et sp. nov. urn:lsid:zoobank.org:act: 8D581345-0B2E-4E5C-918C-DBF84F3B6978 Figs 2, 65–97; Tables 5–6 Etymology This species is dedicated to Franck Brehier, French biospeleologist, who has dedicated himself to exploring and studying many karst areas and caves in Southeast Asia. Type material Holotype MYANMAR • ♂; Shan State, Ywangan, Win Twin Cave; 21º11′51.47″ N, 96º32′40.34″ E, 16 Nov. 2018: Aung Lin leg.; labelled “♂4-holotype”; MZB (MCNB) 2020-1156. Paratypes MYANMAR • 1 ♂, 1 ♀; same collection data as for holotype; labelled “♂3-paratype” and “♀1– paratype”; MZB (MCNB) 2020-0626, MZB (MCNB) 2020-0627 • 1 ♀; same collection data as for holotype; labelled “♀2-paratype”; MZB (MCNB) 2020-1159 • 1 ♂; Shan State, Parpent Cave 1; 2 Dec. 2015; Franck Brehier leg; collected by hand; collector’s code BUR15-FB20; labelled “♂5-paratype”; MZB (MCNB) 2020-0628 • 1 ♂; same collection data as for preceding; collector’s code MY15–20.06; labelled “♂7-paratype”; MZB (MCNB) 2020-1158 • 1 ♀; Shan State, Kyauk Khaung [= Stone Cave]; 30 Nov. 2015; Franck Brehier leg.; collector’s codes: BUR15–FB17, MY15–17.03; labelled “♀6-paratype”; MZB (MCNB) 2020-1157. Other material examined MYANMAR • 2 specs; same collection data as for holotype; mounted on two separate aluminium stages and coated with palladium-gold; Coll. AS. Description BODY. Elongated (Fig. 2), length 23 mm in male holotype (19–26 mm in three paratype females, 15–23 mm in three paratype males). Greatest width at urotergite VII 2.6 mm. Epicuticle smooth under optical microscope, with numerous micropores at higher magnifications (Figs 72, 85). Cuticle unpigmented, except for slightly sclerotized areas on dorsal head, mandible tips, femoral and tibial condyles and segments VI–X (Fig. 2). HEAD. Antennae with 36 antennomeres; antennae less than ½ body length; first antennomere short, followed by three longer and larger antennomeres (2 nd to 4 th antennomeres with reinforced borders) (Figs 65–68, 70; Table 5). All antennomeres with abundant setae including sM and sm setae, which appear more abundant on ventral side of 7 th to 16 th antennomeres under light microscope; trichobothria present on antennomeres 4–6 in a 3/5/5 pattern, in which a trichobothria in distal position; 1 or 2 placoid sensilla present on latero-interior ventral side on 17 th and more distal antennomeres; apical antennomere bearing 16–18 placoid sensilla distributed in three irregular whorls (Figs 65–66). Dorsal and ventral side of head with numerous uniformly distributed sM and sm, and several M, more obvious in young specimens (♂7- paratype); on dorsal side A1–3, S2,4,6, M2,3,5, I4,5, P2 and L1–5 (Fig. 69); on ventral side, submentum with large 1+1 M in posterior position, admentum with 4+4 M, mentum at base of labial palps with 1+1 M; external lobes of mentum with abundant sM; internal lobes with 1+1 short M. Elongated, conical labial palps almost 3 × as long as wide compared with sM and sm in addition to one long, apical seta and a few shorter setiform sensilla (Figs 75–77). Lacinia falciform well sclerotized, all five laminae pectinate. THORAX. Thoracic segments elongated (Figs 71, 75). Pronotum with 5+5 M and numerous uniformly distributed sM and sm; mesonotum with 5+5 M and a few sM and sm; metanotum with 2+2 M and a few sm; both prescuta have 1+1 M and scattered sM and sm; at high magnifications tiny, uniformly distributed micropores (0.10–0.15 µm diameter) visible on cuticle surface (Fig. 72). Thoracic sternites, intersternites, and presternites well defined with sm, sM, and M setae (Figs 75, 77–79). Pro-presternites and pro-, meso- and metasternites have strong internal Y-shaped cuticular structures (furcisternites) (Barlet & Carpentier 1962), and only in pro-presternites prolongation of posterior branch named spine clearly visible on surface (Denis 1949). Pro-presternum with 1+1 short M in anterior lateral position and 1+1 sM in medial anterior; prosternum with 1+1 medial anterior M; 3+3 lateral anterior M, 1+1 medial intermediate M and 2+2 lateral posterior M; meso-poststernum with 5+5 M; meso-intersternum with 5+5 M; mesosternum with 1+1 medial anterior M, 4+4 lateral anterior M, 1 M sagittal, 1+1 medial intermediate M, 1+0 medial posterior M and 3+3 lateral posterior M; metapoststernum with 5+5 M; meta-intersternum 4+4 M; and metasternum with 1+1 medial anterior M, 3+3 lateral anterior M; 1+1 sagittal M, 1+1 medial intermediate M, 3+3 lateral posterior M (Figs 75, 77–79). Legs elongated, hind legs reaching 5 th abdominal segment. Frictional setae between trochantercoxa-femora articulations; femora-tibia-tarsus articulations with row of long M or sM setae with large sockets, plus additional 1 M in coxa, 5 M in trochanter and 7 M in femora. Tibia and tarsus with M and sM; 5 M in tibia and 2 M in tarsus. Tibia also bearing one calcar seta at ventral apex, thicker and more robust than other tibial setae, and two rows of four or five thick setae along ventral side. Pretarsus with two unequal claws and sharp medial unguiculus. ABDOMEN. Abdominal tergites with few sm and sM. Tergite I (prescutum and scutum) without M; tergite II with 0 or 1+1 M5; tergite III with 1+1 M (medial anterior macrosetae), 0 or 1+1 M1, 1+1 M4–5; tergites IV–VI with 1+1 M (ma), 0 or 1+1 M1, 1+1 M2–5; tergite VIII with 1+1 M4–5; tergite IX lacking M except (M1 present in specimens from Parpent Cave 1 (Fig. 88). Urite X (Figs 89, 92) nearly 1.5 × as long as wide, distinctly marked carinae present with subparallel margins slightly convergent towards posterior; 2+2 intracarinal D1 and D3 macrosetae and 3+3 macrosetae (L1, L3, L5) on carinae (Fig. 89); ventral side with four rows of 3+3 M, 3+3 M, 2+2 M, and 2+2 M from anterior to posterior position; acropygium rounded (Fig. 91). Tergites I–V with blunt, slightly rounded to pointed posterolateral angles; angles on tergites VI and VII more conspicuous, lobiform projection small to more prolonged and visibly sclerotized in largest specimens; tergite IX with projections (Fig. 88). Sternite I (Figs 80–85) with multiperforated surface and rounded protrusions covered by abundant sm and lesser sM and 3+3 or 3+4 M on prescutum and 11+11 M on scutum. Median glandular organ with 12 seta-shaped sensilla (Fig. 83). Lateral subcoxal organs invaginated below posterior margin or evaginated showing central opening protruding over margin of first urosternite (Figs 81–82). Each lateral subcoxal organ with one, two, or three rows of glandular setae (GS) (54–100 in males, 47–66 in females) and one row of sensory setae (SS) (11–24 in males, 13–15 in females) occupying 0.22–0.30 (males) and 0.23–0.25 (females) of interstyle width; GS/st1 (stylus of first sternite) = 0.1–0.23 (males) and 0.18–0.28 (females), SS/st1= 0.19 (male) and 0.16–0.26 (females); row of setae with large sockets anterior to glandular setae, 7–12 in males and 6–10 in females (Figs 80–85). Sternites have abundant sm and strong M; sternites II–VII with 7+7 A M, 5+5 (4+4) B M and 4+4 C M; sternite VIII with 3+3 (4+4) A M, 3+3 (2+2) B M and 3+3 C M (see Material and methods for terminology); sternite IX with 1+1 M (Figs 86–87). Cerci strong, well developed, elongated and rectilinear, becoming curved toward apex (Figs 89–92), length ranging from 2.8 mm in largest specimen (♀ 1- paratype) to 1.4 mm in the smallest (♂7- paratype); cerci always slightly longer than urite X, heavily sclerotized with external dorsal andventral carinae projecting from dorsal and ventral acetabular articulations running almost to apex ventrally and halfway dorsally. Cerci with medial tooth; right cercus with basal notch complementary in shape to round tooth at ventral side of basal portion of left cercus. Posterior to right notch and left tooth: in right cercus short row of 5 or 6 small, round denticles in line; and in left cercus two rows of small round denticles (4+4); these rows of denticles occupying 1/8 of total length of each cercus (Figs 89–95, 97). Each cercus with scattered sm, sM, and M setae and several conical sensilla throughout, more abundant distally (Figs 96–97). Dorsal side of each cercus with 6 or 7 D macrosetae, D1, D3 and D5 largest on both cerci; ventral side with 12 V-macrosetae, V3 and V8 being largest; intracarinal region with 5–7 L macrosetae, a pair of macrosetae in L1 being largest (Figs 91, 94–95). Taxonomic affinities Mueggejapyx gen. nov. is distinguished by its elongated, rectilinear, heavily sclerotized cerci curving subapically, and lacking a medial tooth but with one or two rows of basal small round denticles, its median glandular organ with seta-shaped sensilla, and short lateral subcoxal organs, each with a row of setae that have large sockets. Remarks Mueggejapyx brehieri gen. et sp. nov., was observed and collected along with A. ywangana sp. nov. in Win Twin Cave (Figs 1–4), as well as in two nearby caves: Parpent Cave 1 and Kyauk Khaung (synonyms: Sin Lae Ye Win, Stone Cave). The latter is the second longest cave so far explored in Myanmar. Kyauk Khaung Cave is over 4790 m long and also situated in the Ywangan karst area. Its entrance is located only 1240 m southeast of the entrance to Win Twin, and the cave itself extends mostly towards the northeast of the entrance. During the 2015 biological research of Kyauk Khaung, specimens of Campodeidae and Japygidae were found in the northernmost parts of the cave, which indicates the species is most likely distributed throughout the entire subterranean habitats of the Ywangan karst (unpublished data). The Ywangan karst covers 1050 ha, and at the moment hosts three other endemic troglobitic invertebrates: the carabid beetle Birmaphaenops brehieri Deuve, 2017 (Deuve 2017), the cave crab Shanphusa ywarngan Ng & Whitten, 2017 (Ng & Whitten 2017), and a woodlouse Bamaoniscus lobatus Taiti et al, 2020 as well as an endemic karst-adapted gecko, the Linn-Way bent-toed gecko Cyrtodactylus linnwayensis Grismer et al., 2017 (Grismer et al. 2017), and 17 species of bats (unpublished data). Due to its biodiversity, Ywangan karst is proposed as a karst Key Biodiversity Area and a subterranean Ramsar Site. Although cave tourism is being developed in the area, there are substantial efforts being made by the NGO sector (Fauna & Flora International Myanmar) to provide guidance for development of sustainable, low-impact tourism as well as cave and biodiversity conservation (unpublished data)., Published as part of Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús & Jiménez-Valverde, Alberto, 2021, Asian cave-adapted diplurans, with the description of two new genera and four new species (Arthropoda, Hexapoda, Entognatha), pp. 1-46 in European Journal of Taxonomy 731 on pages 29-37, DOI: 10.5852/ejt.2021.731.1199, http://zenodo.org/record/4422557, {"references":["Barlet J. & Carpentier F. 1962. Le thorax des Japygides. Bulletin et Annales de la Societe royale d'Entomologie de Belgique 8: 95 ‾ 127.","Denis J. R. 1949. Ordre des Diploures. In: P. P. Grasse (ed.) Traite de Zoologie IX: 160 ‾ 185. Masson, Paris.","Deuve T. 2017. Decouverte du premier Carabique troglobie de Birmanie et descriptions de deux nouveaux Lanxangaphaenops du Laos (Coleoptera, Caraboidea, Trechidae). Bulletin de la Societe entomologique de France 122 (1): 97 ‾ 104.","Ng P. K. L. & Whitten A. J. 2017. On a new species of Shanphusa Yeo & Ng, 2007 (Brachyura, Potamoidae, Potamidae), from a cave in central Myanmar. Crustaceana 90 (2) 235 ‾ 245. https: // doi. org / 10.1163 / 15685403 - 00003646","Taiti S. & Montesanto G. 2020. Troglobiotic terrestrial isopods from Myanmar, with descriptions of a new genus and three new species (Crustacea, Oniscidea). In: Kottelat M., Deharveng L. & Ng P. K. L. (eds) Anthony J. Whitten (1953 - 2017) Memorial Issue. Raffles Bulletin of Zoology Supplement 35: 109 - 122.","Grismer L. L., Perry L., Wood Jr., Myint Kyaw T., Thaw Z., Evan S. H., Quah M. L., Murdoch M. S., Grismer A. L., Htet K. & Ngwe L. 2017. Twelve new species of Cytodactylus Gray (Squamata: Gekkonidae) from isolated limestone habitats in east-central and southern Myanmar demonstrate high localized diversity and unprecedented microendemism. Zoological Journal of the Linnean Society 182: 862 ‾ 959. https: // doi. org / 10.1093 / zoolinnean / zlx 057"]}

Published

2021

50. Pacificampa caesa Chevrizov 1978

Author

Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús, and Jiménez-Valverde, Alberto

Subjects

Pacificampa, Campodeidae, Arthropoda, Pacificampa caesa, Animalia, Entognatha, Diplura, Biodiversity, Taxonomy

Abstract

Pacificampa caesa Chevrizov, 1978 Pacificampa caesa Chevrizov, 1978: 199, figs 1(10‾19). Material examined RUSSIA • ♂ holotype (6.8 mm); Far East, Primoriye region, Chandolaz Mountain Range, Bliznets Cave; 23 Jun. 1974; B.P. Chevrizov leg.; slide; ZMMU Dip0004. Redescription (based on Chevrizov 1978) It has a smooth cuticle under optical microscope and is covered by abundant short and smooth clothing setae. The antennae are apparently intact with 27 antennomeres, medial antennomeres are 3 × as long as wide; third antennomere has a sensillum in ventral position (c–d macrosetae). The plain frontal process has one long anterior smooth macroseta and two, almost two times shorter, posterior macrosetae; the three macrosetae with short distal barbs along each side of the insertion line of the antennomere are longer than the smooth x setae with length ratios of a / i / p / x, 7/8/4/3, respectively. Pronotum with 1+1 ma, 1+1 la, 1+1 lp, mesonotum with 1+1 ma, 1+1 la, 2+2 lp, and metanotum with 1+1 ma, 1+1 lp macrosetae; all notal macrosetae are robust with a few short distal barbs, in particular the la are longer and the lp pronotal macrosetae have more numerous short distal barbs; the marginal setae are thicker than the clothing setae with short distal barbs, the lateral posterior marginal setae are larger and have more numerous small barbs. The metathoracic legs reach the end of the abdomen; the femora have one robust dorsal macroseta with short distal barbs, whereas the tibia has one ventral short macroseta with 1–2 apical barbs and the calcars are with 3–4 long barbs; the tarsus has two rows of robust, smooth ventral setae, three long, smooth dorsal and one distal ventral setae; the pretarsus is without lateral processes, with subequal elbowed claws, and with a smooth ventral surface ridged on the dorsal side that looks like very small lateral crests under optical microscopes, but they are not. Urotergites V–VII have 1+1 ma, 1+1 la, 2+2 lp; urotergite VIII and abdominal segment IX has 1+1 mp, 3+3 lp, all macrosetae are robust and with a few short distal barbs. Urosternite I has 6+6, urosternites II–VII 5+5, and urosternite VIII 1+1 macrosetae; all urosternal macrosetae are robust and with a few long barbs; robust smooth stylar setae. First urosternite appendages have (male) subcylindrical appendages thick, each of these has a large apical field with more than one hundred glandular a 1 setae., Published as part of Sendra, Alberto, Komerički, Ana, Lips, Josiane, Luan, Yunxia, Selfa, Jesús & Jiménez-Valverde, Alberto, 2021, Asian cave-adapted diplurans, with the description of two new genera and four new species (Arthropoda, Hexapoda, Entognatha), pp. 1-46 in European Journal of Taxonomy 731 on page 23, DOI: 10.5852/ejt.2021.731.1199, http://zenodo.org/record/4422557, {"references":["Chevrizov B. P. 1978. Two new genera of the Family Campodeidae from the Far East Caves. Zoologichesky Zhurnal 57 (2): 197 ‾ 205."]}

Published

2021