DOCSLIB.ORG

Exceptional Diversity of Opsin Expression Patterns in Neogonodactylus Oerstedii (Stomatopoda) Retinas

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Exceptional Diversity of Opsin Expression Patterns in Neogonodactylus Oerstedii (Stomatopoda) Retinas Exceptional diversity of opsin expression patterns in Neogonodactylus oerstedii (Stomatopoda) retinas Megan L. Portera,b,1,2, Hiroko Awataa,1, Michael J. Boka,c, and Thomas W. Cronina aDepartment of Biological Sciences, University of Maryland Baltimore County, Baltimore, MD 21250; bDepartment of Biology, University of Hawai’iat Manoa, Honolulu, HI 96822; and cSchool of Biological Sciences, University of Bristol, BS8 1TQ Bristol, United Kingdom Edited by Claude Desplan, New York University, New York, NY, and approved February 27, 2020 (received for review October 4, 2019) Stomatopod crustaceans possess some of the most complex animal Most of the spectral diversity found in stomatopod retinas visual systems, including at least 16 spectrally distinct types of exists in the four dorsal-most ommatidial MB rows (MB rows 1 photoreceptive units (e.g., assemblages of photoreceptor cells). Here to 4). In MB rows 1 to 4, the seven proximal photoreceptor cells we fully characterize the set of opsin genes expressed in retinal tissues (R1–7) are subdivided into two separate photoreceptive units, and determine expression patterns of each in the stomatopod Neo- formed by sets of three or four retinula cells. Therefore, in MB gonodactylus oerstedii. Using a combination of transcriptome and rows 1 to 4 each ommatidium is formed from three successive RACE sequencing, we identified 33 opsin transcripts expressed in each photoreceptive layers comprising the distal UVS R8 photore- N. oerstedii eye, which are predicted to form 20 long-wavelength– ceptor, and middle and proximal photoreceptive layers sensitive sensitive, 10 middle-wavelength–sensitive, and three UV-sensitive to the visible spectrum (Fig. 1C). Each of the three photore- visual pigments. Observed expression patterns of these 33 tran- ceptor layers in each of the first four MB rows is spectrally dis- scripts were highly unusual in five respects: 1) All long-wavelength tinct, adding 12 classes to the overall spectral diversity of the and short/middle-wavelength photoreceptive units expressed multi- N. oerstedii eye. The spectral diversity of the photoreceptors in these ple opsins, while UV photoreceptor cells expressed single opsins; 2) layers is the result of distinct visual pigment expression, filtering most of the long-wavelength photoreceptive units expressed at least through the visual pigments of photoreceptors of successive – one middle-wavelength sensitive opsin transcript; 3) the photore- layers, and additional optical filtering by photostable pigments in ceptors involved in spatial, motion, and polarization vision expressed the crystalline cones and rhabdoms that further tune their more transcripts than those involved in color vision; 4) there is a – – spectral sensitivities (3 7, 10 13). EVOLUTION unique opsin transcript that is expressed in all eight of the photore- In all animal visual systems, photoreceptor spectral absorbance ceptive units devoted to color vision; and 5) expression patterns in is due to the expression of light-absorbing visual pigments. These the peripheral hemispheres of the eyes suggest visual specializations visual pigments are composed of an opsin protein covalently not previously recognized in stomatopods. Elucidating the expres- bound to a vitamin A-derived chromophore. The spectral diversity sion patterns of all opsin transcripts expressed in the N. oerstedii observed among different photoreceptors within an organism’s retina reveals the potential for previously undocumented functional visual system is generally based on the expression of different diversity in the already complex stomatopod eye and is a first step opsin proteins bound to the same chromophore. Crustacean opsin toward understanding the functional significance of the unusual abun- dance of opsins found in many arthropod species’ visual systems. Significance Stomatopoda | opsin | retinal expression | in situ hybridization | evolution Our study reveals the most elaborate opsin expression patterns tomatopod crustaceans are successful predators in marine ever described in any animal eye. In mantis shrimp, a pugnacious Shabitats. They are famous for their aggressive nature, pow- crustacean renowned for its visual sophistication, we found erful prey capture, and defense system, and in particular their unexpected retinal expression patterns highlighting the poten- highly unusual visual system (1). Unlike other arthropods, each tial for cryptic photoreceptor functional diversity, including sin- stomatopod compound eye consists of three distinct regions: gle photoreceptors that coexpress opsins from different spectral Dorsal and ventral hemispheres separated by an equatorial re- clades and a single opsin with a putative nonvisual function important in color vision. This study demonstrates the evolu- gion of specialized ommatidia referred to as the “midband” tionary potential for increasing visual system functional diversity (MB). While the hemispheres are typically thought to have an- through opsin gene duplication and diversification, as well as atomically and physiologically similar ommatidia throughout, the changes in patterns of gene coexpression among photoreceptors MB is most commonly formed from six parallel rows of omma- and retinula cells. These results have significant implications for tidia that contain photoreceptors specialized for color (MB rows the function of other visual systems, particularly in arthropods 1 to 4) and polarization (MB rows 5 and 6) discrimination (Fig. – where large numbers of retinally expressed opsins have been 1) (2 5). documented. The Caribbean species Neogonodactylus oerstedii has been particularly well studied and is thought to be representative of Author contributions: M.L.P. and T.W.C. designed research; M.L.P., H.A., and M.J.B. per- many stomatopods with six-row MBs (6–10). Altogether, its formed research; M.L.P., H.A., and M.J.B. analyzed data; and M.L.P. and H.A. wrote retina is composed of 16 spectrally distinct photoreceptive units the paper. (10). Similar to other crustaceans, each ommatidium is com- The authors declare no competing interest. posed of eight photoreceptor (retinula) cells (R1–8). In the This article is a PNAS Direct Submission. hemispheres and in MB rows 5 and 6, these eight cells are or- Published under the PNAS license. ganized into two spectrally distinct layers composed of seven Data deposition: The sequences reported in this paper have been deposited in the retinula cells (R1–7) situated proximal to a single-celled eighth GenBank database (SRA PRJNA609025, accession nos. MT112859–MT112888). retinula (R8) photoreceptor. Ommatidia in both hemispheres of 1M.L.P. and H.A. contributed equally to this work. N. oerstedii and in the two most ventral ommatidial rows of the 2To whom correspondence may be addressed. Email: [email protected]. MB, MB rows 5 and 6, have two photoreceptive layers: a UV- This article contains supporting information online at https://www.pnas.org/lookup/suppl/ sensitive (UVS) R8 receptor distal to a middle-wavelength– doi:10.1073/pnas.1917303117/-/DCSupplemental. sensitive (MWS) layer composed of R1–7 cells (6, 7, 9–11). www.pnas.org/cgi/doi/10.1073/pnas.1917303117 PNAS Latest Articles | 1of10 Downloaded by guest on October 2, 2021 eyes Results A N. oerstedii Retinal Opsin Transcript Diversity. In addition to pre- vious results, we identified 15 new N. oerstedii opsins, bringing the expressed retinal visual opsin total to 33 transcripts (7, 8). Of these 33 visual opsins, 24 are full-length transcripts, 8 are partial transcripts missing only the 5′ end of the coding sequence, and 1 is a partial transcript missing coding regions on both the 5′ and 3′ ends. All 33 transcripts contain typical opsin structural motifs, including the predicted seven-transmembrane domains, a lysine residue that forms a protonated Schiff base with the bound mDH retinal chromophore, a glutamic acid residue at the predicted B C mid-band (MB) DH VH R-type opsin counterion site for the positive charge of the pro- DH tonated lysine, and a conserved amino acid motif (e.g., glutamic 1 2 3 4 5 6 MB cornea acid/aspartic acid–arginine–tyrosine) in transmembrane-helix 3 that stabilizes the inactive state conformation of class A rhodopsin- VH crystalline cones like G protein-coupled receptors (15). mVH In phylogenetic reconstructions including previously published R8 crustacean opsin sequences, all N. oerstedii retinal opsins clus- D 1 tered into the expected three arthropod visual pigment clades middle tier (LWS, MWS, and SWS/UVS) (Fig. 2). In total, the 33 N. oer- R1-7 stedii retinal opsins consist of 20 LWS (5 newly identified), 10 proximal tier MWS (all newly identified), and 3 UVS transcripts (previously norm. abs. 0 identified) (7). Within each spectral clade the opsin transcripts 300 400 500 600 were further divided into well-supported subgroups. The LWS wavelength (nm) opsins all clustered into the six previously identified stomatopod Fig. 1. The complex photoreceptor arrangement and spectral absorbance opsin subgroups A to F (8). The five new LWS opsins identified in the N. oerstedii compound eye. (A) Image of N. oerstedii. (Scale bar: 5 in this study belong to subgroup B (NoL18), subgroup C (NoL20), mm.) (B) The external division of the ommatidia into five regions: The and subgroup E (NoL16, NoL17, and NoL19). In particular, the marginal dorsal hemisphere (mDH), dorsal hemisphere (DH), MB composed three opsin transcripts in LWS subgroup E are uniquely charac- of six rows of ommatidia, ventral hemisphere (VH), and marginal ventral
Load more

Recommended publications
  • National Monitoring Program for Biodiversity and Non-Indigenous Species in Egypt
    UNITED NATIONS ENVIRONMENT PROGRAM MEDITERRANEAN ACTION PLAN REGIONAL ACTIVITY CENTRE FOR SPECIALLY PROTECTED AREAS National monitoring program for biodiversity and non-indigenous species in Egypt PROF. MOUSTAFA M. FOUDA April 2017 1 Study required and financed by: Regional Activity Centre for Specially Protected Areas Boulevard du Leader Yasser Arafat BP 337 1080 Tunis Cedex – Tunisie Responsible of the study: Mehdi Aissi, EcApMEDII Programme officer In charge of the study: Prof. Moustafa M. Fouda Mr. Mohamed Said Abdelwarith Mr. Mahmoud Fawzy Kamel Ministry of Environment, Egyptian Environmental Affairs Agency (EEAA) With the participation of: Name, qualification and original institution of all the participants in the study (field mission or participation of national institutions) 2 TABLE OF CONTENTS page Acknowledgements 4 Preamble 5 Chapter 1: Introduction 9 Chapter 2: Institutional and regulatory aspects 40 Chapter 3: Scientific Aspects 49 Chapter 4: Development of monitoring program 59 Chapter 5: Existing Monitoring Program in Egypt 91 1. Monitoring program for habitat mapping 103 2. Marine MAMMALS monitoring program 109 3. Marine Turtles Monitoring Program 115 4. Monitoring Program for Seabirds 118 5. Non-Indigenous Species Monitoring Program 123 Chapter 6: Implementation / Operational Plan 131 Selected References 133 Annexes 143 3 AKNOWLEGEMENTS We would like to thank RAC/ SPA and EU for providing financial and technical assistances to prepare this monitoring programme. The preparation of this programme was the result of several contacts and interviews with many stakeholders from Government, research institutions, NGOs and fishermen. The author would like to express thanks to all for their support. In addition; we would like to acknowledge all participants who attended the workshop and represented the following institutions: 1.
    [Show full text]
  • Learning in Stomatopod Crustaceans
    International Journal of Comparative Psychology, 2006, 19 , 297-317. Copyright 2006 by the International Society for Comparative Psychology Learning in Stomatopod Crustaceans Thomas W. Cronin University of Maryland Baltimore County, U.S.A. Roy L. Caldwell University of California, Berkeley, U.S.A. Justin Marshall University of Queensland, Australia The stomatopod crustaceans, or mantis shrimps, are marine predators that stalk or ambush prey and that have complex intraspecific communication behavior. Their active lifestyles, means of predation, and intricate displays all require unusual flexibility in interacting with the world around them, imply- ing a well-developed ability to learn. Stomatopods have highly evolved sensory systems, including some of the most specialized visual systems known for any animal group. Some species have been demonstrated to learn how to recognize and use novel, artificial burrows, while others are known to learn how to identify novel prey species and handle them for effective predation. Stomatopods learn the identities of individual competitors and mates, using both chemical and visual cues. Furthermore, stomatopods can be trained for psychophysical examination of their sensory abilities, including dem- onstration of color and polarization vision. These flexible and intelligent invertebrates continue to be attractive subjects for basic research on learning in animals with relatively simple nervous systems. Among the most captivating of all arthropods are the stomatopod crusta- ceans, or mantis shrimps. These marine creatures, unfamiliar to most biologists, are abundant members of shallow marine ecosystems, where they are often the dominant invertebrate predators. Their common name refers to their method of capturing prey using a folded, anterior raptorial appendage that looks superficially like the foreleg of a praying mantis.
    [Show full text]
  • Downloaded from Brill.Com10/11/2021 08:33:28AM Via Free Access 224 E
    Contributions to Zoology, 67 (4) 223-235 (1998) SPB Academic Publishing bv, Amsterdam Optics and phylogeny: is there an insight? The evolution of superposition eyes in the Decapoda (Crustacea) Edward Gaten Department of Biology, University’ ofLeicester, Leicester LEI 7RH, U.K. E-mail: [email protected] Keywords: Compound eyes, superposition optics, adaptation, evolution, decapod crustaceans, phylogeny Abstract cannot normally be predicted by external exami- nation alone, and usually microscopic investiga- This addresses the of structure and in paper use eye optics the tion of properly fixed optical elements is required construction of and crustacean phylogenies presents an hypoth- for a complete diagnosis. This largely rules out esis for the evolution of in the superposition eyes Decapoda, the use of fossil material in the based the of in comparatively on distribution eye types extant decapod fami- few lies. It that arthropodan specimens where the are is suggested reflecting superposition optics are eyes symplesiomorphic for the Decapoda, having evolved only preserved (Glaessner, 1969), although the optics once, probably in the Devonian. loss of Subsequent reflecting of some species of trilobite have been described has superposition optics occurred following the adoption of a (Clarkson & Levi-Setti, 1975). Also the require- new habitat (e.g. Aristeidae,Aeglidae) or by progenetic paedo- ment for good fixation and the fact that complete morphosis (Paguroidea, Eubrachyura). examination invariably involves the destruction of the specimen means that museum collections Introduction rarely reveal enough information to define the optics unequivocally. Where the optics of the The is one of the compound eye most complex component parts of the eye are under investiga- and remarkable not on of its fixation organs, only account tion, specialised to preserve the refrac- but also for the optical precision, diversity of tive properties must be used (Oaten, 1994).
    [Show full text]
  • Linkage Mechanics and Power Amplification of the Mantis Shrimp's
    3677 The Journal of Experimental Biology 210, 3677-3688 Published by The Company of Biologists 2007 doi:10.1242/jeb.006486 Linkage mechanics and power amplification of the mantis shrimp’s strike S. N. Patek1,*, B. N. Nowroozi2, J. E. Baio1, R. L. Caldwell1 and A. P. Summers2 1Department of Integrative Biology, University of California, Berkeley, CA 94720-3140, USA and 2Ecology and Evolutionary Biology, University of California–Irvine, Irvine, CA 92697-2525, USA *Author for correspondence (e-mail: [email protected]) Accepted 6 August 2007 Summary Mantis shrimp (Stomatopoda) generate extremely rapid transmission is lower than predicted by the four-bar model. and forceful predatory strikes through a suite of structural The results of the morphological, kinematic and modifications of their raptorial appendages. Here we mechanical analyses suggest a multi-faceted mechanical examine the key morphological and kinematic components system that integrates latches, linkages and lever arms and of the raptorial strike that amplify the power output of the is powered by multiple sites of cuticular energy storage. underlying muscle contractions. Morphological analyses of Through reorganization of joint architecture and joint mechanics are integrated with CT scans of asymmetric distribution of mineralized cuticle, the mantis mineralization patterns and kinematic analyses toward the shrimp’s raptorial appendage offers a remarkable example goal of understanding the mechanical basis of linkage of how structural and mechanical modifications can yield dynamics and strike performance. We test whether a four- power amplification sufficient to produce speeds and forces bar linkage mechanism amplifies rotation in this system at the outer known limits of biological systems.
    [Show full text]
  • DEEP SEA LEBANON RESULTS of the 2016 EXPEDITION EXPLORING SUBMARINE CANYONS Towards Deep-Sea Conservation in Lebanon Project
    DEEP SEA LEBANON RESULTS OF THE 2016 EXPEDITION EXPLORING SUBMARINE CANYONS Towards Deep-Sea Conservation in Lebanon Project March 2018 DEEP SEA LEBANON RESULTS OF THE 2016 EXPEDITION EXPLORING SUBMARINE CANYONS Towards Deep-Sea Conservation in Lebanon Project Citation: Aguilar, R., García, S., Perry, A.L., Alvarez, H., Blanco, J., Bitar, G. 2018. 2016 Deep-sea Lebanon Expedition: Exploring Submarine Canyons. Oceana, Madrid. 94 p. DOI: 10.31230/osf.io/34cb9 Based on an official request from Lebanon’s Ministry of Environment back in 2013, Oceana has planned and carried out an expedition to survey Lebanese deep-sea canyons and escarpments. Cover: Cerianthus membranaceus © OCEANA All photos are © OCEANA Index 06 Introduction 11 Methods 16 Results 44 Areas 12 Rov surveys 16 Habitat types 44 Tarablus/Batroun 14 Infaunal surveys 16 Coralligenous habitat 44 Jounieh 14 Oceanographic and rhodolith/maërl 45 St. George beds measurements 46 Beirut 19 Sandy bottoms 15 Data analyses 46 Sayniq 15 Collaborations 20 Sandy-muddy bottoms 20 Rocky bottoms 22 Canyon heads 22 Bathyal muds 24 Species 27 Fishes 29 Crustaceans 30 Echinoderms 31 Cnidarians 36 Sponges 38 Molluscs 40 Bryozoans 40 Brachiopods 42 Tunicates 42 Annelids 42 Foraminifera 42 Algae | Deep sea Lebanon OCEANA 47 Human 50 Discussion and 68 Annex 1 85 Annex 2 impacts conclusions 68 Table A1. List of 85 Methodology for 47 Marine litter 51 Main expedition species identified assesing relative 49 Fisheries findings 84 Table A2. List conservation interest of 49 Other observations 52 Key community of threatened types and their species identified survey areas ecological importanc 84 Figure A1.
    [Show full text]
  • On a Hitherto Unknown Phyllosoma Larval Species of the Slipper Lobster Scyllarus (Decapoda, Scyllaridae) in the Hawaiian Archipelago L
    Pacific Science (1977), vol. 31, no. 2 © 1977 by The University Press of Hawaii. All rights reserved On a Hitherto Unknown Phyllosoma Larval Species of the Slipper Lobster Scyllarus (Decapoda, Scyllaridae) in the Hawaiian Archipelago l MARTIN W. JOHNSON 2 IN A PREVIOUS ANALYSIS of plankton from thorax has a short spine situated at the 140 scattered oceanographic stations in the base of each of legs 1-4 (Figure 1-2). Coxal Hawaiian area, mainly around Oahu Island, and subexopodal spines (Figure I-I, sp.) are six scyllarid larval species were found (John­ present and the exopods of legs I, 2, and 3 son 1971). Five ofthese species were assigned are provided with 21, 21, and 19 pairs of respectively to Parribacus antarcticus (Lund); swimming setae, respectively; pleopods and Scyllarides squamosus (H. Milne Edwards); uropods are bilobed buds (Figure 1-3). The Arctides regalis Holthuis; Scyllarus timidus eyestalks are 2.4 mm long and the first Holthuis; and Scyllarus modestus Holthuis. antennae are about equal in length to the These five species comprise all of the then slender second antennae (Figure 1-4). Only known adult slipper lobsters of the Hawaiian very rudimentary second maxillae and first area. The sixth larval species, a Scyllarus, maxillipeds are present and the second maxi1­ could not be identified specifically and lipeds bear no exopod buds (Figure 1-5). appears to represent an unknown adult species of that genus inhabiting the area. It is of interest to report here yet another unknown larva ofScyllarus that was probably Scyllarus sp. phyllosoma. Length 30.1 mm, produced in this relatively isolated oceanic final fully gilled stage (Figure 2-6).
    [Show full text]
  • Morphology and Function in the Cambrian Burgess Shale
    Haug et al. BMC Evolutionary Biology 2012, 12:162 http://www.biomedcentral.com/1471-2148/12/162 RESEARCH ARTICLE Open Access Morphology and function in the Cambrian Burgess Shale megacheiran arthropod Leanchoilia superlata and the application of a descriptive matrix Joachim T Haug1*, Derek EG Briggs2,3 and Carolin Haug1 Abstract Background: Leanchoilia superlata is one of the best known arthropods from the middle Cambrian Burgess Shale of British Columbia. Here we re-describe the morphology of L. superlata and discuss its possible autecology. The re-description follows a standardized scheme, the descriptive matrix approach, designed to provide a template for descriptions of other megacheiran species. Results: Our findings differ in several respects from previous interpretations. Examples include a more slender body; a possible hypostome; a small specialised second appendage, bringing the number of pairs of head appendages to four; a further sub-division of the great appendage, making it more similar to that of other megacheirans; and a complex joint of the exopod reflecting the arthropod’s swimming capabilities. Conclusions: Different aspects of the morphology, for example, the morphology of the great appendage and the presence of a basipod with strong median armature on the biramous appendages indicate that L. superlata was an active and agile necto-benthic predator (not a scavenger or deposit feeder as previously interpreted). Keywords: Megacheira, Great-appendage arthropods, Chelicerata sensu lato, Descriptive matrix, Active predator Background shared with other species. As a consequence, morpho- The description of species is fundamental to the science logical details in many phylogenetic matrices have to be of zoology, including taxonomy, phylogenetic systema- (re-)interpreted, often without the benefit of a compre- tics, functional morphology and ultimately evolutionary hensive description.
    [Show full text]
  • Marine Invertebrate Diversity in Aristotle's Zoology
    Contributions to Zoology, 76 (2) 103-120 (2007) Marine invertebrate diversity in Aristotle’s zoology Eleni Voultsiadou1, Dimitris Vafi dis2 1 Department of Zoology, School of Biology, Aristotle University of Thessaloniki, GR - 54124 Thessaloniki, Greece, [email protected]; 2 Department of Ichthyology and Aquatic Environment, School of Agricultural Sciences, Uni- versity of Thessaly, 38446 Nea Ionia, Magnesia, Greece, dvafi [email protected] Key words: Animals in antiquity, Greece, Aegean Sea Abstract Introduction The aim of this paper is to bring to light Aristotle’s knowledge Aristotle was the one who created the idea of a general of marine invertebrate diversity as this has been recorded in his scientifi c investigation of living things. Moreover he works 25 centuries ago, and set it against current knowledge. The created the science of biology and the philosophy of analysis of information derived from a thorough study of his biology, while his animal studies profoundly infl uenced zoological writings revealed 866 records related to animals cur- rently classifi ed as marine invertebrates. These records corre- the origins of modern biology (Lennox, 2001a). His sponded to 94 different animal names or descriptive phrases which biological writings, constituting over 25% of the surviv- were assigned to 85 current marine invertebrate taxa, mostly ing Aristotelian corpus, have happily been the subject (58%) at the species level. A detailed, annotated catalogue of all of an increasing amount of attention lately, since both marine anhaima (a = without, haima = blood) appearing in Ar- philosophers and biologists believe that they might help istotle’s zoological works was constructed and several older in the understanding of other important issues of his confusions were clarifi ed.
    [Show full text]
  • MANTIS SHRIMPSSHRIMPS Fast, Flexible, Fearless - Scurrying and Scooting Among the Coral Rubble Or Suddenly Exploding from Their Burrows in the Muck
    93 Spotlight The Peacock Mantis Shrimp Odontodactylus scyllarus is - as its common name implies - the most colorful species among these widespread crustacean predators. THETHE LURKINGLURKING HORRORHORROR OFOF THETHE DEEPDEEP MANTISMANTIS SHRIMPSSHRIMPS Fast, flexible, fearless - scurrying and scooting among the coral rubble or suddenly exploding from their burrows in the muck. To impale and smash their hapless prey GOOGLE EARTH COORDINATES HERE 94 TEXT BY ANDREA FERRARI PHOTOS BY ANDREA & ANTONELLA FERRARI Wreathed any newcomers to scuba in a cloud of Mdiving are scared of sharks. Others are volcanic sand, a large afraid of morays. Some again are Lysiosquillina intimidated by barracudas... Little they sp. literally know that some of the scariest, most explodes from fearsome and probably most monstrous its burrow creatures of the deep lurk a few feet in a three- below the surface, silently waiting, millisecond coldly staring at their surroundings, attack. This is a “spearer” waiting for the opportunity to strike with species - notice a lightning-fast motion and to cruelly its sharply impale their prey or smash it to toothed smithereens! Luckily, most of these raptorial claws. terrifying critters are just a few inches long – otherwise diving on coral reefs might be a risky proposition indeed for every human being... But stop for a moment, and consider those cunning predators of the seabottom, the mantis shrimps: an elongated, segmented and armored body, capable of great flexibility and yet strong enough to resist the bite of all but the fiercest triggerfish; a series of short, parallel, jointed legs positioned under the thorax to swiftly propel it among the reefs rubble bottom; a pair of incredibly large, multifaceted dragonfly-like eyes, mounted on sophisticated swiveling joints, capable of giving the animal an absolutely unbeatable 3-D vision on a 360° field of vision, immensely better than our own and enabling it to strike with implacable accuracy at its chosen target.
    [Show full text]
  • SA Spider Checklist
    REVIEW ZOOS' PRINT JOURNAL 22(2): 2551-2597 CHECKLIST OF SPIDERS (ARACHNIDA: ARANEAE) OF SOUTH ASIA INCLUDING THE 2006 UPDATE OF INDIAN SPIDER CHECKLIST Manju Siliwal 1 and Sanjay Molur 2,3 1,2 Wildlife Information & Liaison Development (WILD) Society, 3 Zoo Outreach Organisation (ZOO) 29-1, Bharathi Colony, Peelamedu, Coimbatore, Tamil Nadu 641004, India Email: 1 [email protected]; 3 [email protected] ABSTRACT Thesaurus, (Vol. 1) in 1734 (Smith, 2001). Most of the spiders After one year since publication of the Indian Checklist, this is described during the British period from South Asia were by an attempt to provide a comprehensive checklist of spiders of foreigners based on the specimens deposited in different South Asia with eight countries - Afghanistan, Bangladesh, Bhutan, India, Maldives, Nepal, Pakistan and Sri Lanka. The European Museums. Indian checklist is also updated for 2006. The South Asian While the Indian checklist (Siliwal et al., 2005) is more spider list is also compiled following The World Spider Catalog accurate, the South Asian spider checklist is not critically by Platnick and other peer-reviewed publications since the last scrutinized due to lack of complete literature, but it gives an update. In total, 2299 species of spiders in 67 families have overview of species found in various South Asian countries, been reported from South Asia. There are 39 species included in this regions checklist that are not listed in the World Catalog gives the endemism of species and forms a basis for careful of Spiders. Taxonomic verification is recommended for 51 species. and participatory work by arachnologists in the region.
    [Show full text]
  • The First Complete Mitochondrial Genome Sequences For
    * Manuscript The First Complete Mitochondrial Genome Sequences For Stomatopod Crustaceans: Implications for Phylogeny Kirsten Swinstrom1,2, Roy Caldwell1, H. Matthew Fourcade2 and Jeffrey L. Boore1,2 1 Department of Integrative Biology, University of California Berkeley, Berkeley, CA 2 Evolutionary Genomics Department, DOE Joint Genome Institute and Lawrence Berkeley National Lab, Walnut Creek, CA For correspondence: Jeffrey Boore, DoE Joint Genome Institute, 2800 Mitchell Drive, Walnut Creek, CA 94598, phone: 925-296-5691, fax: 925-296-5620, [email protected] 1 Abstract We report the first complete mitochondrial genome sequences of stomatopods and compare their features to each other and to those of other crustaceans. Phylogenetic analyses of the concatenated mitochondrial protein-coding sequences were used to explore relationships within the Stomatopoda, within the malacostracan crustaceans, and among crustaceans and insects. Although these analyses support the monophyly of both Malacostraca and, within it, Stomatopoda, it also confirms the view of a paraphyletic Crustacea, with Malacostraca being more closely related to insects than to the branchiopod crustaceans. Key words: Stomatopod; mitochondrial genome; Crustacea; Arthropod phylogeny; mitochondrial DNA; Gonodactylus chiragra; Lysiosquillina maculata; Squilla empusa 2 Introduction Mitochondrial DNA (mtDNA) sequences have been used extensively in phylogenetic analyses to examine relationships among populations or higher taxa. Most of these studies are limited because they use only one or a few genes. More recently however, many complete mitochondrial genomes have been sequenced (Boore, 1999). In particular, a number of phylogenetic analyses using gene order or protein-coding sequences from complete mitochondrial genomes have been conducted to examine relationships within the phylum Arthropoda (e.g. Boore et al., 1998; Garcia-Machado et al., 1999; Wilson et al., 2000; Yamauchi et al., 2002; Nardi et al., 2003).
    [Show full text]
  • Molecular Diversity of Visual Pigments in Stomatopoda (Crustacea)
    Visual Neuroscience (2009), 26, 255–265. Printed in the USA. Copyright Ó 2009 Cambridge University Press 0952-5238/09 $25.00 doi:10.1017/S0952523809090129 Molecular diversity of visual pigments in Stomatopoda (Crustacea) MEGAN L. PORTER, MICHAEL J. BOK, PHYLLIS R. ROBINSON AND THOMAS W. CRONIN Department of Biological Sciences, University of Maryland, Baltimore County, Baltimore, Maryland (RECEIVED February 16, 2009; ACCEPTED May 11, 2009; FIRST PUBLISHED ONLINE June 18, 2009) Abstract Stomatopod crustaceans possess apposition compound eyes that contain more photoreceptor types than any other animal described. While the anatomy and physiology of this complexity have been studied for more than two decades, few studies have investigated the molecular aspects underlying the stomatopod visual complexity. Based on previous studies of the structure and function of the different types of photoreceptors, stomatopod retinas are hypothesized to contain up to 16 different visual pigments, with 6 of these having sensitivity to middle or long wavelengths of light. We investigated stomatopod middle- and long-wavelength-sensitive opsin genes from five species with the hypothesis that each species investigated would express up to six different opsin genes. In order to understand the evolution of this class of stomatopod opsins, we examined the complement of expressed transcripts in the retinas of species representing a broad taxonomic range (four families and three superfamilies). A total of 54 unique retinal opsins were isolated, resulting in 6–15 different expressed transcripts in each species. Phylogenetically, these transcripts form six distinct clades, grouping with other crustacean opsins and sister to insect long-wavelength visual pigments. Within these stomatopod opsin groups, intra- and interspecific clusters of highly similar transcripts suggest that there has been rampant recent gene duplication.
    [Show full text]