Jumping Spider

Total Page：16

File Type：pdf, Size：1020Kb

Beneficial Species Profile Photo credit: Joseph Berger, Bugwood.org Common Name: Bold jumping spider Scientific Name: Phidippus audax Order and Family: Araneae, Salticidae Size and Appearance: Length (mm) Appearance Egg Pale yellow to light green in color. 1.13-1.33mm Larva/Nymph Adult Males- 6-13mm Overall, body is black and covered in hairs. Patterns of white, Females- 8-19mm yellow, or orange are usually present on dorsal side of abdomen and is variable among individuals. Chelicerae (fangs) are typically an iridescent green. Pupa (if applicable) Type of feeder (Chewing, sucking, etc.): Spiders have fangs in which they pierce their prey and then suck out the liquids. Host/s: The bold jumper is predatory and feeds on a diverse group of prey including a variety of insects and other spiders. Description of Benefits (predator, parasitoid, pollinator, etc.): Phidippus jumping spiders, like all jumping spiders, are diurnal (active during the daylight). This group of spiders is also characterized by their large anterior median eyes and the ability to jump a good distance when pursuing prey. Jumping spiders in the genus Phidippus are larger than most jumping spiders with P. audax one of the most common. Spiders, in general, are beneficial in their predatory nature and ability to consume pest insects. P. audax appears frequently in cropping systems and thus has been included in prey density and predation studies to determine their impact in reducing pest insects. It should be noted that they do indeed eat many insect pests but because they are predators, they will eat other spiders and some beneficial insects as well. References: Jacobs, S. (2015). Bold Jumper Spider. Insect Advice from Extension. Pennsylvania State University. Taylor, B. B., & Peck, W. B. (1975). A comparison of northern and southern forms of Phidippus audax (Hentz) (Araneida, Salticidae). Journal of Arachnology. 2:89-99. Young, O. P. (1989). Field observations of predation by Phidippus audax (Araneae: Salticidae) on arthropods associated with cotton. Journal of Entomological Science, 24(2), 266-273. .

Copy Link

Recommended publications

Untangling the Web… Spiders in Arizona Fields! Ayman Mostafa, Lydia M
Untangling the Web… Spiders in Arizona Fields! Ayman Mostafa, Lydia M. Brown, Tim Vandervoet, Peter C. Ellsworth (University of Arizona), Vonny Barlow (University of California) & Steven E. Naranjo (USDA-ARS, ALARC) Spiders are beneficial inhabitants of agricultural fields because of Lygus nymph prey their important contributions to biological control of pest insects, consuming tons of small arthropods every year. Spiders eat anything they can catch, even prey larger than themselves. When they are abundant, they contribute to the control of many insect pests in A Arizona crop fields including whiteflies, Lygus bugs, fleahoppers, Leafhopper and lepidopteran larvae. Field studies in Arizona demonstrate that the prey B crab spider, Misumenops celer (Family Thomisidae, Fig. 1A, B) and Dictyna spider, Dictyna reticulata (Family Dictynidae, Fig. 1C, D) are common in Arizona cotton fields and can be influential predators. Unlike other spiders that spin webs to capture their food, crab spiders rely on stealth and surprise. They actively search plant surfaces, litter, and debris for prey. They hide in flowers or foliage and ambush their prey. Their common name derives from the fact that they look like and walk like crabs. Dictyna are small, brownish, web-making E spiders that trap whitefly adults and other insects in their webs (Fig. 1C). Examining their webs enables easy identification of what D species of whitefly are in the field (sweetpotato or banded-winged). C Jumping spiders (Family Salticidae, Fig. 1E) are generally less abundant in cotton fields but, like crab spiders, ambush their prey. They have stout bodies and long front legs adapted for jumping, as well as four pairs of eyes with one very large set in the middle of their face.
[Show full text]
Prey of the Jumping Spider Phidippus Johnsoni (Araneae : Salticidae)
Jackson, R. R . 1977 . Prey of the jumping spider Phidippus johnsoni (Araneae : Salticidae) . J. Arachnol. 5 :145-149 . PREY OF THE JUMPING SPIDER PHIDIPPUS JOHNSONI (ARANEAE : SALTICIDAE) Robert R. Jackson I Zoology Departmen t University of Californi a Berkeley, California 9472 0 ABSTRACT Field data indicate that P. johnsoni is an euryphagous predator, whose diet includes organisms (aphids, ants, opilionids) sometimes considered distasteful to spiders . Other spiders are preyed upon , including conspecifics. Prey size tends to be one quarter to three quarters the size of the predator . INTRODUCTION Since spiders are probably a dominant group of predators of insects (Bristowe, 1941 ; Riechert, 1974; Turnbull, 1973), there is considerable interest in their feeding ecology . Spiders have usually been considered to be euryphagous predators with a stabilizing , rather than regulative, effect on insect populations (Riechert, 1974) . However, informa- tion concerning the prey taken by particular spider species, in the field, is limited . Field studies by Edgar (1969, 1970), Robinson and Robinson (1970) and Turnbull (1960) are especially noteworthy . During the course of a study of the reproductive biology of Phidippus johnsoni (Peckham and Peckham) (Jackson, 1976), occasionally individuals of this species were found in the field holding prey in their chelicerae . Each prey discovered in this way i s listed in Table 1 . In addition, Ken Evans and Charles Griswold, who were familiar wit h this species, recorded observations of P. johnsoni with prey. (Their data are included in Table 1 .) These data came from a variety of habitats in western North America, most o f which have been described elsewhere (Jackson, 1976) .
[Show full text]
Spiders of the Hawaiian Islands: Catalog and Bibliography1
Pacific Insects 6 (4) : 665-687 December 30, 1964 SPIDERS OF THE HAWAIIAN ISLANDS: CATALOG AND BIBLIOGRAPHY1 By Theodore W. Suman BISHOP MUSEUM, HONOLULU, HAWAII Abstract: This paper contains a systematic list of species, and the literature references, of the spiders occurring in the Hawaiian Islands. The species total 149 of which 17 are record ed here for the first time. This paper lists the records and literature of the spiders in the Hawaiian Islands. The islands included are Kure, Midway, Laysan, French Frigate Shoal, Kauai, Oahu, Molokai, Lanai, Maui and Hawaii. The only major work dealing with the spiders in the Hawaiian Is. was published 60 years ago in " Fauna Hawaiiensis " by Simon (1900 & 1904). All of the endemic spiders known today, except Pseudanapis aloha Forster, are described in that work which also in cludes a listing of several introduced species. The spider collection available to Simon re presented only a small part of the entire Hawaiian fauna. In all probability, the endemic species are only partly known. Since the appearance of Simon's work, there have been many new records and lists of introduced spiders. The known Hawaiian spider fauna now totals 149 species and 4 subspecies belonging to 21 families and 66 genera. Of this total, 82 species (5596) are believed to be endemic and belong to 10 families and 27 genera including 7 endemic genera. The introduced spe cies total 65 (44^). Two unidentified species placed in indigenous genera comprise the remaining \%. Seventeen species are recorded here for the first time. In the catalog section of this paper, families, genera and species are listed alphabetical ly for convenience.
[Show full text]
Checklist of Non-Insect Invertebrates of Steele Creek Park
Checklist of Non-Insect Invertebrates of Steele Creek Park Harvestmen (Order Opiliones) __ Leiobunum aldrichi __ Leiobunum vittatum (Eastern Harvestman) __ Odiellus nubivagus __ Odiellus pictus __ Vonones sayi (Ornate Harvestman) Centipedes (Class Chilopoda) __ Geophilus vittatus (Diamondback Soil Centipede) __ Hemiscolopendra marginata (Florida Blue Centipede, Eastern Bark Centipede) __ Scolopocryptops nigridius __ Scolopocryptops sexspinosus (Eastern Fire Centipede) __ Strigamia bothriopus __ Theatops posticus (Smooth-tailed Forceps Centipede) __ Cryptops leucopodus Millipedes (Class Diplopoda) __ Apheloria montana (Cherry Millipede) __ Brachycybe lecontii (Feather Millipede) __ Cambala annulata __ Oxidus gracilis (Greenhouse Millipede)* __ Pseudopolydesmus canadensis __ Abacion magnum __ Abacion tesselatum __ Euryurus leachii __ Andrognathus corticarius (Cope’s Noodle Millipede) __ Narceus americanus-annularis (American Giant Millipede) Spiders (Order Araneae) __ Agelenopsis sp. (Grass Spider) __ Araneus marmoreus (Marbled Orbweaver) __ Araniella displicata (Six-spotted Orbweaver) __ Dolomedes albineus (White-striped Fishing Spider) __ Dolomedes tenebrosus (Dark Fishing Spider) __ Dolomedes triton (Six-spotted Fishing Spider) __ Dolomedes vittatus (Banded Fishing Spider) __ Larinioides cornutus (Furrow Orbweaver) __ Leucage venusta (Orchard Orbweaver) __ Micrathena gracilis (Spiny Micrathena) __ Micrathena mitrata (White Micrathena) __ Micrathena sagitatta (Arrow-shaped Micrathena) __ Misumenoides formosipes (White-banded Crab Spider) __ Neoscona crucifera (Spotted Orbweaver) __ Phidippus audax (Bold Jumping Spider) __ Phidippus otiosus (Canopy Jumping Spider) __ Phidippus putnami (Putnam’s Jumping Spider) __ Platycryptus undatus (Tan Jumping Spider) __ Pardosa sp. (Thin-legged Wolf Spider) __ Pirata sp. (Pirate Wolf Spider) __ Rabidosa rabida (Rabid Wolf Spider) __ Schizocosa crassipes (Brush-footed Wolf Spider) __ Synema parvulum (Black-banded Crab Spider) __ Tetragnatha sp.
[Show full text]
Arthropods of Elm Fork Preserve
Arthropods of Elm Fork Preserve Arthropods are characterized by having jointed limbs and exoskeletons. They include a diverse assortment of creatures: Insects, spiders, crustaceans (crayfish, crabs, pill bugs), centipedes and millipedes among others. Column Headings Scientific Name: The phenomenal diversity of arthropods, creates numerous difficulties in the determination of species. Positive identification is often achieved only by specialists using obscure monographs to ‘key out’ a species by examining microscopic differences in anatomy. For our purposes in this survey of the fauna, classification at a lower level of resolution still yields valuable information. For instance, knowing that ant lions belong to the Family, Myrmeleontidae, allows us to quickly look them up on the Internet and be confident we are not being fooled by a common name that may also apply to some other, unrelated something. With the Family name firmly in hand, we may explore the natural history of ant lions without needing to know exactly which species we are viewing. In some instances identification is only readily available at an even higher ranking such as Class. Millipedes are in the Class Diplopoda. There are many Orders (O) of millipedes and they are not easily differentiated so this entry is best left at the rank of Class. A great deal of taxonomic reorganization has been occurring lately with advances in DNA analysis pointing out underlying connections and differences that were previously unrealized. For this reason, all other rankings aside from Family, Genus and Species have been omitted from the interior of the tables since many of these ranks are in a state of flux.
[Show full text]
Jump Takeoff in a Small Jumping Spider
Journal of Comparative Physiology A https://doi.org/10.1007/s00359-021-01473-7 ORIGINAL PAPER Jump takeof in a small jumping spider Erin E. Brandt1,2 · Yoshan Sasiharan2 · Damian O. Elias1 · Natasha Mhatre2 Received: 27 October 2020 / Revised: 4 February 2021 / Accepted: 23 February 2021 © The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature 2021 Abstract Jumping in animals presents an interesting locomotory strategy as it requires the generation of large forces and accurate timing. Jumping in arachnids is further complicated by their semi-hydraulic locomotion system. Among arachnids, jumping spiders (Family Salticidae) are agile and dexterous jumpers. However, less is known about jumping in small salticid species. Here we used Habronattus conjunctus, a small jumping spider (body length ~ 4.5 mm) to examine its jumping performance and compare it to that of other jumping spiders and insects. We also explored how legs are used during the takeof phase of jumps. Jumps were staged between two raised platforms. We analyzed jumping videos with DeepLabCut to track 21 points on the cephalothorax, abdomen, and legs. By analyzing leg liftof and extension patterns, we found evidence that H. conjunc- tus primarily uses the third legs to power jumps. We also found that H. conjunctus jumps achieve lower takeof speeds and accelerations than most other jumping arthropods, including other jumping spiders. Habronattus conjunctus takeof time was similar to other jumping arthropods of the same body mass. We discuss the mechanical benefts and drawbacks of a semi- hydraulic system of locomotion and consider how small spiders may extract dexterous jumps from this locomotor system.
[Show full text]
Visual Reactions to Auditory Stimulus by the Jumping Spider Phidippus Princeps (Araneae, Salticidae)
Visual reactions to auditory stimulus by the jumping spider Phidippus princeps (Araneae, Salticidae) Philip Denbaum Degree project in biology, Master of science (2 years), 2019 Examensarbete i biologi 45 hp till masterexamen, 2019 Biology Education Centre, Uppsala University, and Elizabeth Jakob lab, University of Massachusetts Supervisors: Elizabeth Jakob and Anders Berglund External opponent: Emilie Laurent & Julian Baur Table of contents Abstract 2 Introduction 3 Methods and Materials 5 Spider collection and care 5 General experimental setup 5 Overview of the eyetracker 5 Securing the spider 6 Aligning spider and finding retinas 6 Experiment 7 Data analysis 8 Statistical analyses 9 Results 10 Analysis 1 10 Analysis 2 13 Discussion 14 Future studies 15 Conclusions 16 Acknowledgements 16 References 17 Appendix 19 !1 Abstract Jumping spiders (Family Salticidae) are known for their exceptional vision, including color vision and spatial acuity. Salticids use their vision in many behaviors, including predation and courtship. Recently evidence of their ability to sense airborne vibrations, i.e. sound, was published. I used a specialized jumping-spider-specific eyetracker to study the visual reaction of the retinas of the jumping spider Phidippus princeps when exposed to the sound of a predator. I used a generic wasp sound, previously shown to induce a startle response, as stimulus and played it from different directions. The spiders showed strong reactions to the sound stimulus by large increases in retinal movement when exposed to the stimulus, and they showed no habituation to the stimulus over three rounds of exposure. However, I found no indication that the direction of retinal movement corresponded to the location of the sound source.
[Show full text]
Natural Prey of the Jumping Spider Menemerus Semilimbatus (Hahn, 1827) (Araneae: Salticidae), with Notes on Its Unusual Predatory Behaviour
EUROPEAN ARACHNOLOGY 2003 (LOGUNOV D.V. & PENNEY D. eds.), pp. 93100. © ARTHROPODA SELECTA (Special Issue No.1, 2004). ISSN 0136-006X (Proceedings of the 21st European Colloquium of Arachnology, St.-Petersburg, 49 August 2003) Natural prey of the jumping spider Menemerus semilimbatus (Hahn, 1827) (Araneae: Salticidae), with notes on its unusual predatory behaviour Åñòåñòâåííàÿ äîáû÷à ïàóêà ñêàêóí÷èêà Menemerus semilimbatus (Hahn, 1827) (Araneae: Salticidae) ñ çàìåòêàìè î åãî íåîáû÷íîì õèùíè÷åñêîì ïîâåäåíèè E.F. GUSEINOV Ý.Ô. ÃÓÑÅÉÍÎÂ Institute of Zoology, Azerbaijan Academy of Sciences, block 504, passage 1128, Baku 370073, Azerbaijan. email: [email protected] Èíñòèòóò çîîëîãèè ÍÀÍ Àçåðáàéäæàíà, êâàðòàë 504, ïðîåçä 1128, Áàêó 370073, Àçåðáàéäæàí. email: [email protected] ABSTRACT. Prey composition and the hunting behaviour of the jumping spider, Menemerus semilimbatus, which inhabits stone walls was studied. Less than 10% of the specimens in the population studied were observed feeding. Adult males fed significantly less frequently than adult females and juveniles. Diptera, the dominant prey group, accounted for more than 70% of all prey consumed. No other single prey type was present in significant numbers. M. semilimbatus adopts a specialized predatory behaviour towards flies that is unusual for salticids. This behaviour depends on how the fly is orientated towards the spider. If the fly is facing away from the spider, M. semilimbatus approaches it directly. When the fly is facing the spider, M. semilimbatus keeps its distance and encircles it until the prey is facing away from the spider. Only then, will the spider start to approach the fly directly. The specific habitat of M.
[Show full text]
Life-History Constraints in Inaccurate Batesian Myrmecomorphic Spiders (Araneae: Corinnidae, Gnaphosidae)
Eur. J. Entomol. 108: 255–260, 2011 http://www.eje.cz/scripts/viewabstract.php?abstract=1614 ISSN 1210-5759 (print), 1802-8829 (online) Life-history constraints in inaccurate Batesian myrmecomorphic spiders (Araneae: Corinnidae, Gnaphosidae) STANO PEKÁR and MARTIN JARAB Department of Botany and Zoology, Faculty of Science, Masaryk University, Kotlá Ĝská 2, 611 37 Brno, Czech Republic; e-mail: [email protected] Key words. Formicidae, prey, trophic niche, clutch size, copulation, courtship Abstract. Accurate Batesian mimicry is known to impose constraints on some traits of the mimic, such as foraging or reproductive behaviour. It is not known whether life-history traits of inaccurate Batesian mimics are constrained as well. We studied selected life- history traits of three spider species, Liophrurillus flavitarsis, Phrurolithus festivus (both Corinnidae), and Micaria sociabilis (Gna- phosidae), that are inaccurate mimics of ants. Namely, we were interested in how myrmecomorphy (ant-like resemblance) constrains their circadian activity, trophic niche and reproductive behaviour. The spiders were found to have diurnal activity like their models, whereas their close relatives have nocturnal activity. The three mimics do not catch ants, nor do they use food resources of ants, but catch various tiny invertebrates that occur in the vicinity of their models. Their trophic niche seems to be constrained by occurrence among ants. Absence of courtship and long lasting copulation, in a position that does not provide protective resemblance, do not seem to be constrained by mimicry in the three species. Comparative analysis of fecundity in mimetic and non-mimetic spiders showed that clutch size is also not constrained. Unlike in accurate mimics, life-history traits of inaccurate myrmecomorphs appear not to be constrained.
[Show full text]
The First Record of Phidippus Bidentatus (Araneae: Salticidae) in the United States
138 Volume 19, No. 3, September, 2005, INSECTA MUNDI The first record of Phidippus bidentatus (Araneae: Salticidae) in the United States A male of a neotropical jumping spider, Phidip- green scales, and bi-colored brown and iridescent pus bidentatus F. O. P.-Cambridge 1901, was col- blue chelicerae, is an attractive addition to the lected by John Scott Armstrong and his staff from fauna of the United States. a boll weevil trap in Cameron County, Texas. The We would like to thank Scott Armstrong and recent revision of the genus Phidippus (Edwards his crew, as well as the owners of the Russell 2004) gave the range of this species as central Plantation, Frank and James Russell, for the op- Mexico to northwest Costa Rica. In addition, the portunity to see this interesting specimen. The specimen has a character, namely the presence of a specimen is deposited in the Florida State Collec- distinct cheliceral distal dorsal tubercle, that would tion of Arthropods, Gainesville, FL. make it key out in the second couplet of the key, along with Phidippus audax (Hentz) and P. regius References cited C. L. Koch. However the structure of the male palpus is quite different than either of the latter Cambridge, F. O. P. 1901. Arachnida - Araneida species (Edwards 2004, Figures 153, 236 and 242). and Opiliones, in Biologia Centrali-Americana, The data for this adult male are: Zoology, London, 2: 193-312. Edwards, G. B. 2004. Revision of the jumping USA: Texas: Cameron County, Russell Plantation spiders of the genus Phidippus (Araneae: Salti- near San Benito, 97.550262ºW 26.0836625ºN, from cidae).
[Show full text]
Araneae: Salticidae)
Belgian Journal of Entomology 67: 1–27 (2018) ISSN: 2295-0214 www.srbe-kbve.be urn:lsid:zoobank.org:pub:6D151CCF-7DCB-4C97-A220-AC464CD484AB Belgian Journal of Entomology New Species, Combinations, and Records of Jumping Spiders in the Galápagos Islands (Araneae: Salticidae) 1 2 G.B. EDWARDS & L. BAERT 1 Curator Emeritus: Arachnida & Myriapoda, Florida State Collection of Arthropods, FDACS, Division of Plant Industry, P. O. Box 147100, Gainesville, FL 32614-7100 USA (e-mail: [email protected] – corresponding author) 2 O.D. Taxonomy and Phylogeny, Royal Belgian Institute of Natural Sciences, Vautierstraat 29, B-1000 Brussels, Belgium (e-mail: [email protected]) Published: Brussels, March 14, 2018 Citation: EDWARDS G.B. & BAERT L., 2018. - New Species, Combinations, and Records of Jumping Spiders in the Galápagos Islands (Araneae: Salticidae). Belgian Journal of Entomology, 67: 1–27. ISSN: 1374-5514 (Print Edition) ISSN: 2295-0214 (Online Edition) The Belgian Journal of Entomology is published by the Royal Belgian Society of Entomology, a non-profit association established on April 9, 1855. Head office: Vautier street 29, B-1000 Brussels. The publications of the Society are partly sponsored by the University Foundation of Belgium. In compliance with Article 8.6 of the ICZN, printed versions of all papers are deposited in the following libraries: - Royal Library of Belgium, Boulevard de l’Empereur 4, B-1000 Brussels. - Library of the Royal Belgian Institute of Natural Sciences, Vautier street 29, B-1000 Brussels. - American Museum of Natural History Library, Central Park West at 79th street, New York, NY 10024-5192, USA. - Central library of the Museum national d’Histoire naturelle, rue Geoffroy Saint- Hilaire 38, F-75005 Paris, France.
[Show full text]
Common Kansas Spiders
A Pocket Guide to Common Kansas Spiders By Hank Guarisco Photos by Hank Guarisco Funded by Westar Energy Green Team, American Arachnological Society and the Chickadee Checkoff Published by the Friends of the Great Plains Nature Center i Table of Contents Introduction • 2 Arachnophobia • 3 Spider Anatomy • 4 House Spiders • 5 Hunting Spiders • 5 Venomous Spiders • 6-7 Spider Webs • 8-9 Other Arachnids • 9-12 Species accounts • 13 Texas Brown Tarantula • 14 Brown Recluse • 15 Northern Black Widow • 16 Southern & Western Black Widows • 17-18 Woodlouse Spider • 19 Truncated Cellar Spider • 20 Elongated Cellar Spider • 21 Common Cellar Spider • 22 Checkered Cobweb Weaver • 23 Quasi-social Cobweb Spider • 24 Carolina Wolf Spider • 25 Striped Wolf Spider • 26 Dotted Wolf Spider • 27 Western Lance Spider • 28 Common Nurseryweb Spider • 29 Tufted Nurseryweb Spider • 30 Giant Fishing Spider • 31 Six-spotted Fishing Spider • 32 Garden Ghost Spider Cover Photo: Cherokee Star-bellied Orbweaver ii Eastern Funnelweb Spider • 33 Eastern and Western Parson Spiders • 34 Garden Ghost Spider • 35 Bark Crab Spider • 36 Prairie Crab Spider • 37 Texas Crab Spider • 38 Black-banded Crab Spider • 39 Ridge-faced Flower Spider • 40 Striped Lynx Spider • 41 Black-banded Common and Convict Zebra Spiders • 42 Crab Spider Dimorphic Jumping Spider • 43 Bold Jumping Spider • 44 Apache Jumping Spider • 45 Prairie Jumping Spider • 46 Emerald Jumping Spider • 47 Bark Jumping Spider • 48 Puritan Pirate Spider • 49 Eastern and Four-lined Pirate Spiders • 50 Orchard Spider • 51 Castleback Orbweaver • 52 Triangulate Orbweaver • 53 Common & Cherokee Star-bellied Orbweavers • 54 Black & Yellow Garden Spider • 55 Banded Garden Spider • 56 Marbled Orbweaver • 57 Eastern Arboreal Orbweaver • 58 Western Arboreal Orbweaver • 59 Furrow Orbweaver • 60 Eastern Labyrinth Orbweaver • 61 Giant Long-jawed Orbweaver • 62 Silver Long-jawed Orbweaver • 63 Bowl and Doily Spider • 64 Filmy Dome Spider • 66 References • 67 Pocket Guides • 68-69 1 Introduction This is a guide to the most common spiders found in Kansas.
[Show full text]