Species List

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The species collected in your Malaise trap are listed below. They are organized by group and are listed in the order of the 'Species Image Library'. ‘New’ refers to species that are brand new to our DNA barcode library. 'Rare' refers to species that were only collected in your trap out of all 64 that were deployed for the program. BIN Group (Scientific Name) Species Common Name Scientific Name New Rare BOLD:AAP2428 Spiders (Araneae) Ghost spider Anyphaena aperta BOLD:AAA4125 Spiders (Araneae) European garden spider Araneus diadematus BOLD:AAU0840 Spiders (Araneae) Mesh web weaver Lathys humilis BOLD:AAP6265 Spiders (Araneae) Sheetweb spider Linyphantes nehalem BOLD:AAD1127 Spiders (Araneae) Long-jawed orb weaver Metellina segmentata BOLD:AAJ7456 Spiders (Araneae) Tangle-web spider Platnickina tincta BOLD:AAD4292 Spiders (Araneae) Cobweb spider Steatoda bipunctata BOLD:ACY1154 Mites (Arachnida) Spider mite Tetranychidae BOLD:ACY1153 Mites (Arachnida) Mite Arachnida BOLD:AAF7756 Springtails (Collembola) Slender springtail Entomobryidae BOLD:ABV8847 Springtails (Collembola) Springtail Sminthurinus BOLD:ACC5051 Beetles (Coleoptera) False metallic wood-boring beetle Trixagus meybohmi BOLD:ACC2430 Beetles (Coleoptera) False metallic wood-boring beetle Trixagus sericeus BOLD:ACM1293 Beetles (Coleoptera) False metallic wood-boring beetle Throscidae BOLD:ACA1124 Flies (Diptera) Longlegged fly Medetera BOLD:ACH2821 Flies (Diptera) Longlegged fly Dolichopodidae BOLD:AAP8074 Flies (Diptera) Heleomyzid fly Suillia limbata BOLD:ACX8977 Flies (Diptera) Hybotid dance fly Hybotidae BOLD:AAN6453 Flies (Diptera) Dark-winged fungus gnat Sciaridae BOLD:ACB9102 Flies (Diptera) Dark-winged fungus gnat Sciaridae BOLD:ACC4249 True bugs (Hemiptera) Giant aphid Essigella BOLD:AAO8340 True bugs (Hemiptera) Leafhopper Dikraneura mali BOLD:ABA5828 True bugs (Hemiptera) Leafhopper Typhlocybinae BOLD:ACN7256 True bugs (Hemiptera) Thread-legged bug Empicoris rubromaculatus BOLD:AAG3816 True bugs (Hemiptera) Assassin bug Zelus tetracanthus BOLD:AAL7025 True bugs (Hemiptera) True bug Hemiptera BOLD:AAA4975 Bees, wasps & ants (Hymenoptera) Wood ant Formica BOLD:ABZ8330 Bees, wasps & ants (Hymenoptera) Black ant Lasius niger BOLD:AAA6280 Bees, wasps & ants (Hymenoptera) Ichneumon wasp Gelis BOLD:ACL6421 Bees, wasps & ants (Hymenoptera) Ichneumon wasp Ichneumonidae BOLD:ACS7652 Bees, wasps & ants (Hymenoptera) Megaspilid wasp Megaspilidae BOLD:AAU9340 Bees, wasps & ants (Hymenoptera) Platygastrid wasp Telenomus BOLD:ACP9474 Bees, wasps & ants (Hymenoptera) Platygastrid wasp Trissolcus BOLD:ACR8641 Bees, wasps & ants (Hymenoptera) Platygastrid wasp Scelioninae BOLD:ACP9221 Bees, wasps & ants (Hymenoptera) Pteromalid wasp Pteromalinae BOLD:ACL2581 Lacewings (Neuroptera) Dustywing Coniopterygidae BOLD:ACR3866 Barklice & booklice (Psocoptera) Lizard barklouse Valenzuela BOLD:AAP2620 Barklice & booklice (Psocoptera) Outer barklouse Ectopsocidae BOLD:AAP4627 Barklice & booklice (Psocoptera) Common barklouse Psocidae BOLD:ACB0984 Barklice & booklice (Psocoptera) Narrow barklouse Graphopsocus cruciatus BOLD:ACX5665 Barklice & booklice (Psocoptera) Granary booklouse Cerobasis guestfalica.

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Sexual Selection Research on Spiders: Progress and Biases
Biol. Rev. (2005), 80, pp. 363–385. f Cambridge Philosophical Society 363 doi:10.1017/S1464793104006700 Printed in the United Kingdom Sexual selection research on spiders: progress and biases Bernhard A. Huber* Zoological Research Institute and Museum Alexander Koenig, Adenauerallee 160, 53113 Bonn, Germany (Received 7 June 2004; revised 25 November 2004; accepted 29 November 2004) ABSTRACT The renaissance of interest in sexual selection during the last decades has fuelled an extraordinary increase of scientiﬁc papers on the subject in spiders. Research has focused both on the process of sexual selection itself, for example on the signals and various modalities involved, and on the patterns, that is the outcome of mate choice and competition depending on certain parameters. Sexual selection has most clearly been demonstrated in cases involving visual and acoustical signals but most spiders are myopic and mute, relying rather on vibrations, chemical and tactile stimuli. This review argues that research has been biased towards modalities that are relatively easily accessible to the human observer. Circumstantial and comparative evidence indicates that sexual selection working via substrate-borne vibrations and tactile as well as chemical stimuli may be common and widespread in spiders. Pattern-oriented research has focused on several phenomena for which spiders oﬀer excellent model objects, like sexual size dimorphism, nuptial feeding, sexual cannibalism, and sperm competition. The accumulating evidence argues for a highly complex set of explanations for seemingly uniform patterns like size dimorphism and sexual cannibalism. Sexual selection appears involved as well as natural selection and mechanisms that are adaptive in other contexts only. Sperm competition has resulted in a plethora of morpho- logical and behavioural adaptations, and simplistic models like those linking reproductive morphology with behaviour and sperm priority patterns in a straightforward way are being replaced by complex models involving an array of parameters.
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Ontogenetic Changes in the Spinning Fields of Nuctenea Cornuta and Neoscona Iheish Araneae, Araneidae)
Yu. L. and J. A. Coddington. J990. Ontogenetic changes in the spinning fields of Nuctenea cornuta and Neoscona iheisH Araneae, Araneidae). J. Arachnol., 18:331-345. ONTOGENETIC CHANGES IN THE SPINNING FIELDS OF NUCTENEA CORNUTA AND NEOSCONA THEISI (ARANEAE, ARANEIDAE) Liuming Yu Div. of Biological Sciences University of Missouri Columbia, Missouri 65211 USA and Jonathan A. Coddington Department of Entomology National Museum of Natural History Smithsonian Institution, Washington, DC 20560 USA ABSTRACT The postembryonie development of spinning organs of Nuctenea cornuta (Clerck) and Neoscona theisi (Walckenaer) (Araneae, Araneidae), was studied with SEM. emphasizing first appearance of, and increase in. spigot and fusule complements. Our results suggest that these species may renew their spinning fields by two distinct methods during their ontogeny: spigots may be merely molted in situ like any other cuticular appendage; and/or spigots in one position are lost and "replaced" by an apparently new spigot in a new position. Some or all of each class of fusule (aciniform and pyrifornf) as well as major and minor ampullate spigots are replaced as well as merely molted. Flagelliform and aggregate spigots seem to be merely molted, never replaced. Evidence for these modes of replacement are the apparently vestigial spinning structures that persist from the previous instar, termed "nubbins" in the case of spigots, and "tartipores" in the case of fusules, as well as patterns in the increase in numbers of fusules and spigots. Spinneret ontogeny confirms Theridiidae and Tetragnathidae as phylogenetically derived taxa relative to Araneidae. INTRODUCTION Previous work on spinnerets has concerned histology (see Kovoor 1987 for a review), morphology (Glatz 1967, 1972, 1973; Mikulska 1966, 1967, 1969; Wasowska 1966, 1967, 1970, 1973; Coddington 1989), and function (Peters 1983.
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4. Garden Spider
M Identification ary Sykes abandons her web and seeks out a sheltered spot to lay her eggs – in vegetation, at the Although the shape of the Garden spider’s abdomen is base of a wall or sometimes inside usually quite distinctive the ‘shoulders’ are less obvious outbuildings. The egg sac is covered in tough, when it has just eaten. These rounder individuals could be yellowish silk and is initially guarded by the confused with the Four-spot Orb-weaver Araneus now eggless and shrivelled mother. She will quadratus, but that species is unlikely to be found in die before the new year, leaving her egg sac gardens and has an abdomen with four large, white secure within its protective silk. spots. Two very common species, Metellina segmentata and Metellina mengei, can also look like the Garden spider but they are a lot smaller and their webs have a Webs hole in the centre - the centre of a Garden spider’s web is criss-crossed with silk. Adult male garden spiders look like Garden spiders spin the classic orb web, females but are very much smaller. Without their strung between suitable supports up to two enlarged palps (‘boxing gloves’ – see Essential spider info. metres from the ground. Its main supporting Factsheet 1) they could be mistaken for juveniles. strand can be over three metres long. The web consists of a series of silk threads radiating from the centre across which the spider lays a Life history spiral of thread. The very centre of the web is filled with a criss-cross of strands.
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Arachnida: Araneae) of the Canadian Prairies
75 Chapter 4 Spiders (Arachnida: Araneae) of the Canadian Prairies Héctor Cárcamo Lethbridge Research Centre, Agriculture and Agri-Food Canada, Lethbridge, AB Jaime Pinzón Department of Renewable Resources, Faculty of Agricultural, Life and Environmental Sciences, University of Alberta, Edmonton Robin Leech 10534, 139 St NW, Edmonton AB John Spence Department of Renewable Resources, Faculty of Agricultural, Life and Environmental Sciences, University of Alberta, Edmonton Abstract. Spiders are the seventh most diverse order of arthropods globally and are prominent predators in all prairie habitats. In this chapter, a checklist for the spiders of the Prairie Provinces (767 recorded species and 44 possible species) is presented along with an overview of all 26 families that occur in the region. Eighteen of the species from the region are adventive. Linyphiidae is by far the dominant family, representing 39% of all species in the three provinces. Gnaphosidae and Lycosidae each represent 8% and three other families (Salticidae, Dictynidae, and Theridiidae) each account for 7%. A summary of biodiversity studies conducted in the Prairies Ecozone and from transition ecoregions is also provided. The Mixed Grassland Ecoregion has the most distinctive assemblage; Schizocosa mccooki and Zelotes lasalanus are common only in this ecoregion. Other ecoregions appear to harbour less distinctive assemblages, but most have been poorly studied. Lack of professional opportunities for spider systematists in Canada remains a major barrier to the advancement of the taxonomy and ecology of spiders. Résumé. Les aranéides forment le septième ordre le plus diversiﬁ é d’arthropodes dans le monde; ce sont des prédateurs très présents dans tous les habitats des Prairies.
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Species List
The species collected in all Malaise traps are listed below. They are organized by group and are listed in the order of the 'Species Image Library'. 'New' refers to species that are brand new to our DNA barcode library. 'Rare' refers to species that were only collected in one trap out of all 64 that were deployed for the program. BIN Group (Scientific Name) Species Common Name Scientific Name New Rare BOLD:AAB0090 Spiders (Araneae) Grass spider Agelenopsis utahana BOLD:AAB5726 Spiders (Araneae) Grass spider Agelenopsis BOLD:AAP2428 Spiders (Araneae) Ghost spider Anyphaena aperta BOLD:AAC6924 Spiders (Araneae) Ghost spider Wulfila saltabundus BOLD:AAD7855 Spiders (Araneae) Starbellied orbweaver Acanthepeira stellata BOLD:AAA4125 Spiders (Araneae) European garden spider Araneus diadematus BOLD:AAA8399 Spiders (Araneae) Six-spotted orb weaver Araniella displicata BOLD:AAN4894 Spiders (Araneae) Six-spotted orb weaver Araniella displicata BOLD:ACY1317 Spiders (Araneae) Humpbacked orb weaver Eustala anastera BOLD:AAA8999 Spiders (Araneae) Furrow orbweaver Larinioides cornutus BOLD:AAA3681 Spiders (Araneae) Furrow spider Larinioides patagiatus BOLD:AAB7330 Spiders (Araneae) Orb weaver Mangora gibberosa BOLD:AAA4123 Spiders (Araneae) Arabesque orbweaver Neoscona arabesca BOLD:AAD1564 Spiders (Araneae) Leafcurling sac spider Clubiona abboti BOLD:AAP3591 Spiders (Araneae) Leafcurling sac spider Clubiona moesta BOLD:AAD5417 Spiders (Araneae) Leafcurling sac spider Clubiona obesa BOLD:AAI4087 Spiders (Araneae) Leafcurling sac spider Clubiona
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Novel Approaches to Exploring Silk Use Evolution in Spiders Rachael Alfaro University of New Mexico
University of New Mexico UNM Digital Repository Biology ETDs Electronic Theses and Dissertations Spring 4-14-2017 Novel Approaches to Exploring Silk Use Evolution in Spiders Rachael Alfaro University of New Mexico Follow this and additional works at: https://digitalrepository.unm.edu/biol_etds Part of the Biology Commons Recommended Citation Alfaro, Rachael. "Novel Approaches to Exploring Silk Use Evolution in Spiders." (2017). https://digitalrepository.unm.edu/ biol_etds/201 This Dissertation is brought to you for free and open access by the Electronic Theses and Dissertations at UNM Digital Repository. It has been accepted for inclusion in Biology ETDs by an authorized administrator of UNM Digital Repository. For more information, please contact [email protected]. Rachael Elaina Alfaro Candidate Biology Department This dissertation is approved, and it is acceptable in quality and form for publication: Approved by the Dissertation Committee: Kelly B. Miller, Chairperson Charles Griswold Christopher Witt Joseph Cook Boris Kondratieff i NOVEL APPROACHES TO EXPLORING SILK USE EVOLUTION IN SPIDERS by RACHAEL E. ALFARO B.Sc., Biology, Washington & Lee University, 2004 M.Sc., Integrative Bioscience, University of Oxford, 2005 M.Sc., Entomology, University of Kentucky, 2010 DISSERTATION Submitted in Partial Fulfillment of the Requirements for the Degree of Doctor of Philosphy, Biology The University of New Mexico Albuquerque, New Mexico May, 2017 ii DEDICATION I would like to dedicate this dissertation to my grandparents, Dr. and Mrs. Nicholas and Jean Mallis and Mr. and Mrs. Lawrence and Elaine Mansfield, who always encouraged me to pursue not only my dreams and goals, but also higher education. Both of my grandfathers worked hard in school and were the first to achieve college and graduate degrees in their families.
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Seasonal Dynamics of Arboreal Spider Diversity in a Temperate Forest
Seasonal dynamics of arboreal spider diversity in a temperate forest Yu-Lung Hsieh & Karl Eduard Linsenmair Department of Animal Ecology and Tropical Biology, Universitat¨ Wurzburg,¨ D-97074 Wurzburg,¨ Germany Keywords Abstract Araneae, canopy fogging, European beech, recolonization, species richness estimation, Measuring and estimating biodiversity patterns is a fundamental task of the scien- true diversity tist working to support conservation and inform management decisions. Most bio- diversity studies in temperate regions were often carried out over a very short pe- Correspondence riod of time (e.g., a single season) and it is often—at least tacitly—assumed that Yu-Lung Hsieh, Department of Animal Ecology these short-term ﬁndings are representative of long-term general patterns. However, and Tropical Biology, Universitat¨ Wurzburg,¨ D-97074 Wurzburg,¨ Germany. should the studied biodiversity pattern in fact contain signiﬁcant temporal dynam- Tel: +49-931-31-89027; ics, perhaps leading to contradictory conclusions. Here, we studied the seasonal di- Fax: +49-931-31-84352; versity dynamics of arboreal spider communities dwelling in 216 European beeches E-mail: [email protected] (Fagus sylvatica L.) to assess the spider community composition in the following seasons: two cold seasons (I: November 2005–January 2006; II: February–April) and Funded by German Research Foundation (DFG) two warm seasons (III: May–July; IV: August–October). We show that the usually and the Universitat¨ Wurzburg¨ in the funding measured diversity of the warm season community (IV: 58 estimated species) alone programme Open Access Publishing. did not deliver a reliable image of the overall diversity present in these trees, and Received: 9 October 2011; Revised: 25 January therefore, we recommend it should not be used for sampling protocols aimed at 2012; Accepted: 6 February 2012 providing a full picture of a forest’s biodiversity in the temperate zones.
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The Diversity and Ecology of the Spider Communities of European Beech Canopy
The diversity and ecology of the spider communities of European beech canopy Dissertation zur Erlangung des naturwissenschaftlichen Doktorgrades der Bayerischen Julius-Maximilians-Universität Würzburg vorgelegt von Yu-Lung Hsieh geboren in Taipeh, Taiwan Würzburg 2011 In the vegetable as well as in the animal kingdom, the causes of the distribution of species are among the number of mysteries, which natural philosophy cannot reach… —Alexander von Humboldt Table of Contents I. General Introduction……………………………...………………………...…1 II. Effects of tree age on diversity and community structure of arboreal spider: implications for old-growth forest conservation…………………………….11 III. Underestimated spider diversity in a temperate beech forest……………33 IV. Seasonal dynamics of arboreal spider diversity in a temperate forest…….51 V. Neutral and niche theory jointly explain spider diversity within temperate forest canopies…………………………………………………………………69 VI. Biodiversity prediction by applying Verhulst Grey Model (GM 1,1)…....…85 VII. Summary and Outlook………………………………………………………93 VIII. Zusammenfassung und Ausblick……………………………………………99 IX. Acknowledgements………………………………………………………….105 X. Curriculum Vitae and Appendix…………………………………………..107 XI. Ehrenwörtliche Erklärung……………………………………….…………114 Declaration This dissertation is the result of my own work and includes nothing that is the outcome of work done in collaboration. Chapter I General Introduction Canopy research and temperate forests Forests, coral reefs and soil contain the majority of the world’s known biodiversity (Connell 1978; Ozanne et al. 2003; Floren and Schmidl 2008), and as much as half of all the macroscopic life forms are believed to dwell in forest canopies, where they remain insufficiently investigated, or undiscovered entirely (Floren and Schmidl 2008). The study of canopy arthropod communities is a relatively young subfield of ecology, and it can be traced back to the study of the extremely diverse flora and fauna of tropical tree canopies in the late 1970s (Perry 1978; Erwin and Scott 1980; Stork and Hammond 1997).
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An Extraordinary New Genus of Spiders from Western Australia with an Expanded Hypothesis on the Phylogeny of Tetragnathidae (Araneae)
Zoological Journal of the Linnean Society, 2011, 161, 735–768. With 17 figures An extraordinary new genus of spiders from Western Australia with an expanded hypothesis on the phylogeny of Tetragnathidae (Araneae) DIMITAR DIMITROV*† and GUSTAVO HORMIGA Department of Biological Sciences, The George Washington University, Washington, DC 20052, USA Received 29 October 2009; Revised 19 January 2010; accepted for publication 9 February 2010 We describe Pinkfloydia Hormiga & Dimitrov gen. nov., a new genus of tetragnathid spiders from Western Australia and study its phylogenetic placement. The taxon sampling from our previous cladistic studies was expanded, with the inclusion of representatives of additional tetragnathid genera and outgroup taxa. Sequences from six genetic markers, 12S, 16S, 18S, 28S, cytochrome c oxidase subunit 1, and histone 3, along with morphological and behavioural data were used to infer tetragnathid relationships. These data were analysed using parsimony (under both static homology and dynamic optimization) and Bayesian methods. Our results indicate that Pinkfloydia belongs to the ‘Nanometa’ clade. We also propose a revised set of synapomorphies to define this lineage. Based on the new evidence presented here we propose a revised hypothesis for the intrafamilial relationships of Tetragnathidae and show that Mimetidae is most likely the sister group of Tetragnathidae. The single species in this genus so far, Pinkfloydia harveii Dimitrov& Hormiga sp. nov., is described in detail and its web architecture documented and illustrated. © 2011 The Linnean Society of London, Zoological Journal of the Linnean Society, 2011, 161, 735–768. doi: 10.1111/j.1096-3642.2010.00662.x ADDITIONAL KEYWORDS: Bayesian analysis – biodiversity – direct optimization – mating plugs – molecular systematics.
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Dynamic Population Structure and the Evolution of Spider Mating Systems
Provided for non-commercial research and educational use only. Not for reproduction, distribution or commercial use. This chapter was originally published in the book Advances in Insect Physiology, Vol. 41, published by Elsevier, and the attached copy is provided by Elsevier for the author's benefit and for the benefit of the author's institution, for non-commercial research and educational use including without limitation use in instruction at your institution, sending it to specific colleagues who know you, and providing a copy to your institution’s administrator. All other uses, reproduction and distribution, including without limitation commercial reprints, selling or licensing copies or access, or posting on open internet sites, your personal or institution’s website or repository, are prohibited. For exceptions, permission may be sought for such use through Elsevier's permissions site at: http://www.elsevier.com/locate/permissionusematerial From: Damian O. Elias, Maydianne C. B. Andrade, and Michael M. Kasumovic, Dynamic Population Structure and the Evolution of Spider Mating Systems. In Jérôme Casas, editor: Advances in Insect Physiology, Vol. 41, Burlington: Academic Press, 2011, pp. 65-114. ISBN: 978-0-12-415919-8 © Copyright 2011 Elsevier Ltd. Academic Press. Author's personal copy Dynamic Population Structure and the Evolution of Spider Mating Systems Damian O. Elias,* Maydianne C. B. Andrade,† and Michael M. Kasumovic‡ *Department of Environmental Science, Policy and Management, University of California, Berkeley, California,
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Heavy Metals in the Gonads and Hepatopancreas of Spiders (Araneae) from Variously Polluted Areas
Ekológia (Bratislava) Vol. 19, Supplement 3, 283-292, 2000 HEAVY METALS IN THE GONADS AND HEPATOPANCREAS OF SPIDERS (ARANEAE) FROM VARIOUSLY POLLUTED AREAS GRAŻYNA WILCZEK, AGNIESZKA BABCZYŃSKA Department of Human and Animal Physiology, The University of Silesia, Bankowa 9, 40-007 Katowice, Poland. Abstract WILCZEK G., BABCZYŃSKA A.: Heavy metals in the gonads and hepatopancreas of spiders (Arane- ae) from variously polluted areas. In GAJDOŠ P., PEKÁR S. (eds): Proceedings of the 18th European Colloquium of Arachnology, Stará Lesná, 1999. Ekológia (Bratislava), Vol. 19, Supplement 3/ 2000, p. 283-292. Spiders, as secondary consumers, ingest considerable amounts of various xenobiotics, including heavy metals. The amounts of ingested metals depends on hunting activity of the spider and on the body composition of their prey. On the other hand, specificity of metal excretion and storage in intracellular granules, rather than the quality of food, is responsible for their high metal body burden. The aim of this study was to determine whether heavy metal levels in the gonads and hepatopancreas of selected spiders species would reflect their adaptability to environmental pollu- tants in relation to their physiological and behavioural specificity. Contents of CD, Pb, Cu and Zn were measured by means of flameless and flame AAS in females of 6 species: Araneus diadema- tus, Araneus marmoreus (Araneidae), Metellina segmentata (Metidae), Linyphia triangularis (Linyphiidae), Pardosa amentata (Lycosidae) and Agelena labyrinthica (Agelenidae). The mate- rial was collected at two sites which differ in the level of industrial pollutants, including heavy metals: Łosień (near Katowice steelworks – heavily polluted environment) and Brenna-Bukowa in Beskid Śląski Mountains (reference site).
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Body Condition and Mate Choice in Tetragnatha Elongata (Araneae, Tetragnathidae)
2002. The Journal of Arachnology 30:20±30 BODY CONDITION AND MATE CHOICE IN TETRAGNATHA ELONGATA (ARANEAE, TETRAGNATHIDAE) Anne Danielson-FrancËois1: Dept. of Biology, Swarthmore College, Swarthmore, PA 19081. E-mail: [email protected] Christine A. Fetterer and Peter D. Smallwood: Dept. of Biology, University of Richmond, Richmond, VA 23173 ABSTRACT. The mate preference characteristics of adult Tetragnatha elongata were assessed with respect to measures of female mass, linear size (length), and condition (mass scaled by length: body condition). Males preferred longer, heavier females and females with higher body condition indices. When mass is partially controlled, males still preferred females of higher body condition, but reversed their preference for length and chose smaller females. We present evidence that female body condition and mass are associated with the volume of her egg load and the proximity of oviposition, whereas female body length is not associated with either. Females displayed no clear preference among males for mass or linear size, but were reluctant to mate in female-choice trials. The small sample size obtained may have obscured the detection of female mate preferences if they exist. This may be the ®rst evidence that mate choice is in¯uenced by body condition rather than mass or linear size among spiders. Keywords: Mate choice, size, body condition, oviposition, Tetragnatha elongata Body size is a signal used by many animals 1983; Rubenstein 1987; Watson 1990; Hack to assess the quality of a mate. Measurements et al. 1997). If this pattern holds true, where of mate quality, including overall energy in- mate competition exists females should prefer take, genetic quality, and other components of larger males as mates when given a choice.
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