First Report on Karyotypic, Morphometric and Meiotic Analysis of a Predatory Bombardier Beetle Pherosophus catoirai (Coleoptera: Carabidae) from Jammu region of Outer Himalayas, India

Published by Oriental Scientific Publishing Company © 2021 This is an Open Access article licensed under a Creative Commons license: Attribution 4.0 International (CC-BY). *Corresponding author E-mail: arshadayoub60@gmail.com First Report on Karyotypic, Morphometric and Meiotic Analysis of a Predatory Bombardier Beetle Pherosophus catoirai (Coleoptera: Carabidae) from Jammu region of Outer Himalayas, India

Carabidae (ground beetles) represented by 40,000 species worldwide ranging in size from 2 mm to 35 mm having spiny powerful legs, massive jaws and large eyes, these are forbidding predators in the insect world. Carabid beetles are proved to be the dominant predators due to their performance in food chain dynamics and pest control 1 . Conservation of ground beetles through their culture and habitat manipulations leads to the enhancement of natural suppression of arthropod pest and weed populations, thus minimize the use of chemicals to control them. Bombardier beetles (sub-family: brachininae) are known for their peculiar explosive self-defence mechanism by which they propel out very hot spray like secretion from defensive gland that keep the predators away 2 . Chromosomal description of nearly 850 species has been given for the family Carabidae 1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16 . Carabids showed a remarkable diversity in chromosome numbers from 2n=8 to 2n=44 and different types of sex determination 17 . The available karyological studies of the family Carabidae are limited to chromosome numbers without their morphometry and meiotic details. Present work analyses karyotypic, morphometric and meiotic details of a ground beetle Pherosophus catoirai Dejean (bombardier beetle) from Jammu district of Outer Himalayas.

Materials and Methods
Beetles were collected from agricultural fields of Jammu region using pitfall traps. Traps were made using biodegradable cups of diameter 7cm. Testis tissue of adult male ( fig.2a,b) beetles was used for cytological studies. Male beetles can be identified by the presence of pad like structures on the protarsi while female beetles lack these pads. Preparation of slides was done by staining technique described by Rozek 18 with little modifications.
Adult male beetles were first anaesthetised with vapours of ethyl acetate because they are very active runners. The anaesthetised beetle was dissected on a clean glass slide. The abdomen was dissected very carefully in order to prevent explosion due to accidental rupturing of the explosion apparatus of this beetle. Testes are present in posterior half nearby the explosion apparatus. Then the abdomen was squeezed gently so as to take out the gonads which were then placed in hypotonic solution (0.7% KCl) for 20 minutes.
Hypotonic treatment was followed by fixation, the tissue was kept in freshly prepared Cornoys fixative solution (3:1 methanol and glacial acetic acid) for 10-12 minutes and this was repeated for three times. Slides were primed by dabbing technique and were dried in air. The dried slides were stained with 2% working giemsa stain solution in phosphate buffer (pH 6.8). Stained slides were scanned and results were recorded using Olympus CH20i BIMF microscope attached with Sony SSC-DC378P camera under 1000X magnification.  The sex chromosome X was the largest in the complement with an absolute length of 1.05 µm.The y sex chromosome was absent in the complement. The total mean haploid length was calculated as 9.41 µm. The last autosomal telocentric pair is smallest among the autosomes with an absolute length of 0.15 µm. Meiotic observations included the stages pachytene, diplotene, diakinesis and metaphase-I. Pachytene showed little condensation in chromosomes without visible chromatids ( fig.2c). Diplotene represented by 17 condensed bivalents with interstitial or terminal chiasmata. They appeared as small stubby structures and the sex chromosome was univalent ( fig.2d). There were present characteristic small ring like chromosomes in diakinesis ( fig.2e) X chromosome appeared as single condensed large chromosome in this stage. Metaphase-I characterized by 17 highly condensed autosomal bivalents and a single sex (X) chromosome ( fig.2f). This stage also confirmed the diploid chromosome number of present species.

discussion
Chromosome number of beetles in family Carabidae showed a wide variation from 2n=8 to 2n=44, however 6% of the species exhibited a chromosome number less than 2n=18+Xy p , the ancestral karyotype of the order Coleoptera. This separates Carabid beetles from rest of the major groups of Coleoptera (mainly those belonging to Polyphaga) characterised by karyotypes with 2n=20. Smith 19 has proposed that the high diploid chromosome numbers of Caraboidea have arisen from ancestral karyotype of 20 chromosomes through frequent dissociations, so the karyotype with 35 chromosomes should be considered derived one. The presence of only one sex chromosome (X) in this species might be the result of gradual erosion of the y chromosome during the course of evolution as many species of carabidae showed a small sized y chromosome 20 . Studies on the predatory species of this family are scarce. Agarwal 21 reported 35 chromosomes in the species Pherosophus bimaculatus. She also mentioned sex chromosome mechanism as X0 and X chromosome being metacentric and larger in the complement. Recent cytogenetic work on four species of family Cleridae-Trichodes favarius, Trichodes quadriguttatus, Trichodes reichei, and Tilloidea transversalis revealed their chromosome number as 2n=18 with Xy p sex mechanism 22 . All the chromosomes except y chromosomes were metacentric in morphology. Azambuja et al 23 cytogenetically analysed three mimetic species of genus Alagoasa (Coleoptera: Alticinae) and found diploid chromosome number as 2n=22 with Xy sex chromosomes.

acknowledgeMent
I would like to show my gratitude to Prof. N.K. Tripathi, HOD Zoology, Central University of Jammu and Prof. Seema Langer, HOD Zoology, University of Jammu for providing necessary lab facilities and support.

Conflict of Interest
There is no conflict of interest between any authors in this research article.

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All the authors have assured their consent for the publication of manuscript. The first draft of the manuscript was written by Arshad Ayoub Bhatti and all authors commented on previous versions of the manuscript. All authors read and approved the final manuscript.

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