Your search keyword '"Kutalová K"' showing total 10 results

1. Occurrence of certain cuticular structures confirms functionality of dorsal abdominal scent glands in Acanthosomatidae (Heteroptera: Pentatomoidea)

Author

Vilímová, J., primary and Kutalová, K., additional

Published

2011

2. Occurrence of certain cuticular structures confirms functionality of dorsal abdominal scent glands in Acanthosomatidae (Heteroptera: Pentatomoidea).

Author

Vilímová, J. and Kutalová, K.

Subjects

*STERNAL gland, *ACANTHOSOMATIDAE, *ENDOCRINE glands, *SEXUAL dimorphism in animals, *HEMIPTERA, *LARVAE

Abstract

Elasmucha ferrugata (Fabricius, 1787) (Heteroptera: Acanthosomatidae) provides maternal care of eggs and larvae. Adults of both sexes have functional anterior dorsal abdominal scent glands (DAGs). Study of all internal and external cuticular structures of DAGs revealed that no DAGs are fully functional in the 1st larval instar, and very probably they are only slightly functional in the 2nd instar. Median and posterior DAGs are undoubtedly not functional in adults. There exists sexual dimorphism in the number of multicellular glandular units in anterior glands in adults. The occurrence of cuticular ductules of these units proves these to be functional glands. This is best considered in combination with the findings of a well-developed evaporatorium. Developed cuticular intima of the gland reservoir and/or the nearly closed ostiole or ostiolar scar bears no information about the functionality of the gland. [ABSTRACT FROM PUBLISHER]

Published

2012

3. The nature of alarm communication in Constrictotermes cyphergaster (Blattodea: Termitoidea: Termitidae): the integration of chemical and vibroacoustic signals.

Author

Cristaldo PF, Jandák V, Kutalová K, Rodrigues VB, Brothánek M, Jiříček O, DeSouza O, and Šobotník J

Abstract

Alarm signalling is of paramount importance to communication in all social insects. In termites, vibroacoustic and chemical alarm signalling are bound to operate synergistically but have never been studied simultaneously in a single species. Here, we inspected the functional significance of both communication channels in Constrictotermes cyphergaster (Termitidae: Nasutitermitinae), confirming the hypothesis that these are not exclusive, but rather complementary processes. In natural situations, the alarm predominantly attracts soldiers, which actively search for the source of a disturbance. Laboratory testing revealed that the frontal gland of soldiers produces a rich mixture of terpenoid compounds including an alarm pheromone. Extensive testing led to identification of the alarm pheromone being composed of abundant monoterpene hydrocarbons (1S)-α-pinene and myrcene, along with a minor component, (E)-β-ocimene. The vibratory alarm signalling consists of vibratory movements evidenced as bursts; a series of beats produced predominantly by soldiers. Exposing termite groups to various mixtures containing the alarm pheromone (crushed soldier heads, frontal gland extracts, mixture of all monoterpenes, and the alarm pheromone mixture made of standards) resulted in significantly higher activity in the tested groups and also increased intensity of the vibratory alarm communication, with the responses clearly dose-dependent. Lower doses of the pheromone provoked higher numbers of vibratory signals compared to higher doses. Higher doses induced long-term running of all termites without stops necessary to perform vibratory behaviour. Surprisingly, even crushed worker heads led to low (but significant) increases in the alarm responses, suggesting that other unknown compound in the worker's head is perceived and answered by termites. Our results demonstrate the existence of different alarm levels in termites, with lower levels being communicated through vibratory signals, and higher levels causing general alarm or retreat being communicated through the alarm pheromone., (© 2015. Published by The Company of Biologists Ltd.)

Published

2015

4. Chemical alarm in the termite Termitogeton planus (Rhinotermitidae).

Author

Dolejšová K, Krasulová J, Kutalová K, and Hanus R

Subjects

Animals, Exocrine Glands chemistry, Gas Chromatography-Mass Spectrometry, Monoterpenes chemistry, Social Behavior, Hydrocarbons chemistry, Isoptera chemistry, Isoptera physiology, Pheromones chemistry

Abstract

Effective defense is a common characteristic of insect societies. Indeed, the occurrence of specialized defenders, soldiers, has been the first step toward eusociality in several independent lineages, including termites. Among the multitude of defensive strategies used by termite soldiers, defense by chemicals plays a crucial role. It has evolved with complexity in advanced isopteran lineages, whose soldiers are equipped with a unique defensive organ, the frontal gland. Besides direct defense against predators, competitors, and pathogens, the chemicals emitted by soldiers from the frontal gland are used as signals of alarm. In this study, we investigated the chemical composition of the defensive secretion produced by soldiers of the termite Termitogeton planus (Isoptera: Rhinotermitidae), from West Papua, and the effects of this secretion on the behavior of termite groups. Detailed two-dimensional gas chromatography/mass spectrometry analyses of the soldier defensive secretion revealed the presence of four linear and nine monoterpene hydrocarbons. Soldier head extracts, as well as synthetic mixtures of the monoterpenes found in these extracts, elicited alarm behavior in both soldiers and pseudergates. Our results suggest that the alarm is not triggered by a single monoterpene from the defensive blend, but by a multi-component signal combining quantitatively major and minor compounds.

Published

2014

5. Age-dependent changes in ultrastructure of the defensive glands of Neocapritermes taracua workers (Isoptera, Termitidae).

Author

Sobotník J, Kutalová K, Vytisková B, Roisin Y, and Bourguignon T

Subjects

Age Factors, Animals, Exocrine Glands growth & development, Exocrine Glands ultrastructure, French Guiana, Microscopy, Electron, Scanning, Microscopy, Electron, Transmission, Isoptera growth & development, Isoptera ultrastructure

Abstract

Protection against predators and competitors is one of the main concerns of termite colonies, which developed a specialised defensive caste, the soldiers. However, soldiers are rare or even missing in several lineages of termites, while workers often develop new defence strategies especially in soil-feeding species. Here, we describe the morphology and ultrastructure of the autothysis-associated glands of Neocapritermes taracua workers and report their age-related changes in structure. The defensive glands of N. taracua workers consist of a pair of labial and a pair of crystal glands, whose secretions mix together through autothysis. Autothysis always occurs at the line of weakness connecting the anterior parts of the crystal-bearing pouches. The crystal glands consist of groups of bicellular secretory units (secretory and corresponding canal cells) which secrete the blue crystal material into external pouches. Their secretory activity is maximal in the middle of worker life, and is considerably lower in very young and old workers. The labial glands are composed of two types of secretory cells: the central and the parietal cells. While the central cells are developed similarly to other termites and secrete proteinaceous secretion into labial gland ducts, the parietal cells develop proteinaceous granules which may eventually bud off the cells. The secretory function of parietal cells is so far unique to N. taracua and differs from other termite species in which they are only responsible of water uptake by acini. The defensive device of N. taracua is truly exceptional as it involves a new gland and a previously undescribed function for parietal cells, being a remarkable example of evolution of morphological innovation., (Copyright © 2014. Published by Elsevier Ltd.)

Published

2014

6. Mutual use of trail-following chemical cues by a termite host and its inquiline.

Author

Cristaldo PF, Desouza O, Krasulová J, Jirošová A, Kutalová K, Lima ER, Sobotník J, and Sillam-Dussès D

Subjects

Animal Distribution, Animals, Choice Behavior physiology, Female, Pheromones physiology, Polyenes metabolism, Animal Communication, Cooperative Behavior, Cues, Isoptera physiology

Abstract

Termite nests are often secondarily inhabited by other termite species ( = inquilines) that cohabit with the host. To understand this association, we studied the trail-following behaviour in two Neotropical species, Constrictotermes cyphergaster (Termitidae: Nasutitermitinae) and its obligatory inquiline, Inquilinitermes microcerus (Termitidae: Termitinae). Using behavioural experiments and chemical analyses, we determined that the trail-following pheromone of C. cyphergaster is made of neocembrene and (3Z,6Z,8E)-dodeca-3,6,8-trien-1-ol. Although no specific compound was identified in I. microcerus, workers were able to follow the above compounds in behavioural bioassays. Interestingly, in choice tests, C. cyphergaster prefers conspecific over heterospecific trails while I. microcerus shows the converse behaviour. In no-choice tests with whole body extracts, C. cyphergaster showed no preference for, while I. microcerus clearly avoided heterospecific trails. This seems to agree with the hypothesis that trail-following pheromones may shape the cohabitation of C. cyphergaster and I. microcerus and reinforce the idea that their cohabitation is based on conflict-avoiding strategies.

Published

2014

7. Armed reproductives: evolution of the frontal gland in imagoes of Termitidae.

Author

Kutalová K, Bourguignon T, Sillam-Dussès D, Hanus R, Roisin Y, and Sobotník J

Subjects

Animals, Exocrine Glands ultrastructure, Female, Male, Microscopy, Electron, Transmission, Phylogeny, Population Dynamics, Biological Evolution, Isoptera genetics, Isoptera ultrastructure

Abstract

The frontal gland of termites is a structure without any equivalent among other animals. Although this gland is well known in soldiers, it received almost no attention in other castes. Recently, we described it in imagoes of Rhinotermitidae and Serritermitidae. In order to provide a complete picture of the evolution of this gland in termite imagoes, we studied it in additional 34 species of Termitidae, representing 7 of the 8 subfamilies. The frontal gland of these species is formed by class 1 secretory cells only, and occurs in two basic shapes: epithelial with reservoir in Foraminitermitinae and Macrotermitinae, and epithelial without reservoir in all other subfamilies. The size variability of the gland is high, not only among Termitidae subfamilies, but also within subfamilies. Our data suggest that the ancestral form of the frontal gland is epithelial with reservoir, as found in Rhinotermitidae, Serritermitidae, and basal Termitidae. The reduction of the reservoir occurred at least two times and the gland was lost two times independently: in Protermes sp. and in Microtermes toumodiensis (both Macrotermitinae)., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

8. Chemistry and anatomy of the frontal gland in soldiers of the sand termite Psammotermes hybostoma.

Author

Krasulová J, Hanus R, Kutalová K, Šobotník J, Sillam-Dussès D, Tichý M, and Valterová I

Subjects

Animals, Egypt, Gas Chromatography-Mass Spectrometry, Sesquiterpenes isolation & purification, Isoptera anatomy & histology, Isoptera chemistry, Sesquiterpenes chemistry

Abstract

A great diversity of defensive chemicals has been described in termite soldiers equipped with a unique defensive organ, the frontal gland. Along with the functional diversity of these compounds, reflecting the evolutionary history of particular lineages and their defensive strategies, a considerable degree of chemical variability often occurs among species and populations. Thus, the chemistry of termite defense may provide information on the phylogeny and geographic dispersal of species and populations. In this paper, we report on the anatomy of the frontal gland and on the diversity of soldier defensive chemicals in the sand termite, Psammotermes hybostoma, from nine colonies and five different localities in Egypt. Using gas chromatography-mass spectrometry, a total of 30 sesquiterpene hydrocarbons, or their oxygenated derivatives, were detected, and the chemical identity of most of them identified. In addition, a ketone, an ester, and a diterpene were identified in some colonies. Within colonies, the chemical composition was stable and did not differ among soldier size categories. However, there were pronounced quantitative and qualitative differences in frontal gland chemicals among colonies and geographic locations. The findings are discussed in a broader comparison with other termite taxa.

Published

2012

9. Comparative study of the labial gland secretion in termites (Isoptera).

Author

Sillam-Dussès D, Krasulová J, Vrkoslav V, Pytelková J, Cvačka J, Kutalová K, Bourguignon T, Miura T, and Šobotník J

Subjects

Amino Acid Sequence, Animals, Electrophoresis, Polyacrylamide Gel, Gas Chromatography-Mass Spectrometry, Insect Proteins chemistry, Insect Proteins metabolism, Molecular Sequence Data, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Exocrine Glands metabolism, Isoptera physiology

Abstract

Labial glands are present in all castes and developmental stages of all termite species. In workers, their secretion contains a food-marking pheromone and digestive enzymes, while soldier secretion plays a defensive role. However, these functions were studied only in a limited set of species, and do not allow drawing general conclusions. Hence, we have investigated the chemical composition of the labial gland extracts from soldiers and workers in 15 termite species belonging to 6 families using an integrative approach based on proteomic and small-molecule profiling. We confirmed the presence of hydroquinone and cellulase in the labial glands of workers, and we identified new toxic compounds in soldiers and workers of several species. Our results highlight the dual role of labial gland secretion, i.e. the defensive role in soldiers and workers of several termite species, and the digestive function in workers.

Published

2012

10. Not only soldiers have weapons: evolution of the frontal gland in imagoes of the termite families Rhinotermitidae and Serritermitidae.

Author

Šobotník J, Bourguignon T, Hanus R, Sillam-Dussès D, Pflegerová J, Weyda F, Kutalová K, Vytisková B, and Roisin Y

Subjects

Animals, Biological Evolution, Endocrine Glands physiology, Female, Head growth & development, Isoptera growth & development, Male, Microscopy, Electron, Scanning methods, Skull physiology, Species Specificity, Endocrine Glands anatomy & histology, Head anatomy & histology, Isoptera anatomy & histology

Abstract

Background: The frontal gland is a unique adaptation of advanced termite families. It has been intensively studied in soldiers with respect to its anatomy and chemistry, with numerous novel compounds being discovered within the tremendous richness of identified products. At the same time, the presence of the frontal gland in non-soldier castes received only negligible attention in the past., Principal Findings: Here, we report on the development of the frontal gland in alate imagoes of 10 genera and 13 species of Rhinotermitidae and Serritermitidae, in order to shed light on the evolution and function of this gland in imagoes. All investigated species possess a frontal gland. In most cases, it is well-developed and equipped with a sac-like reservoir, located in the postero-dorsal part of cranium, but reaching as far as the seventh abdominal segment in some Rhinotermitinae. The only exception is the genus Psammotermes, in which the gland is very small and devoid of the reservoir., Conclusions: Our direct observations and comparisons with soldiers suggest a defensive role of the gland in imagoes of all studied species. This functional analogy, along with the anatomic homology between the frontal gland in soldiers and imagoes, make it likely that the gland appeared once during the early evolution of rhinotermitid ancestors, and remained as a defensive organ of prime importance in both, soldiers and imagoes.

Published

2010