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Cyrtophora citricola

April 12, 2024

Cyrtophora citricola, also known as the tropical tent-web spider, is an orb-weaver spider in the family Araneidae. It is found in Asia, Africa, Australia, Costa Rica, Hispaniola, Colombia, and Southern Europe and in 2000, it was discovered in Florida. C. citricola differs from many of its close relatives due its ability to live in a wide variety of environments. In North America and South America, the spider has caused extensive damage to agricultural operations.

Cyrtophora citricola
C. citricola from Portugal
Scientific classification
Domain: Eukaryota
Kingdom: Animalia
Phylum: Arthropoda
Subphylum: Chelicerata
Class: Arachnida
Order: Araneae
Infraorder: Araneomorphae
Family: Araneidae
Genus: Cyrtophora
Species:
C. citricola
Binomial name
Cyrtophora citricola
(Forskål, 1775)
Synonyms

Aranea citricola
Epeira opuntiae
Epeira cacti-opuntiae
Epeira citricola
Epeira emarginata
Epeira flava
Epeira purpurea
Epeira dorsuosa
Cyrtophora sculptilis
Cyrtophora opuntiae
Epeira cajetana
Araneus citricola
Cyrtophora dorsuosa

C. citricola is in the orb web spider family, but its orb webs are considered atypical. They have a thick silk strand barrier above the orb and a thinner barrier below the orb. This gives the webs a horizontal mesh-like appearance. The spider has developed distinct and specific prey-capturing techniques using its unconventional webs. The prey flies into the upper mesh layer of the web and is deflected into the orb web. The spider then collects and stores the prey in its web. The difference in C. citricola's web silk stems from physiological variations in its spinning apparatuses, as compared to other closely related species. Its webs are non-adhesive and do not require daily respinning.

This spider is one of the few species to exhibit a variable level of sociality. C. citricola can be seen in colonies, which may have arisen due to reduced predation. Within these colonies, each spider has its own web that is linked to other spiders through communal webbing. The spider webs are often built in large matrices next to one another and can span entire trees. The spider usually peacefully coexists with other spiders in the colony. However, at times the spider may have to ward off other spiders in the colony that may try and claim its web.[1]

C. citricola is nocturnal, only performing necessary tasks during the day. During the day, it remains idle and tries to stay out of sight from predators. Most of its foraging and prey capture happen at night.[2]

C. citricola's color and size can vary greatly. Many spiders sport a black and white pattern while others are brown. Males often appear black. Male and female spiders have a sexual dimorphism. The body length in females normally reaches 10 millimetres (0.39 in), while males are only 3 millimetres (0.12 in) long.

Taxonomy edit

Peter Forsskal discovered Cyrtophora citricola in the Arabian Peninsula during his Yemen expedition, sometime between 1761 and 1763.[3] He first saw the spiders in citrus trees and described their horizontal webs as nets. The spider's common name, “tropical tent-web,” derives from these observations.[4] Unfortunately, Forsskal died in Yemen in 1763. His manuscripts, which included details of the spider, were collected and sent back to Denmark by his friend Carsten Niebuhr.[3] These records were published in 1775 as Descriptiones animalium, avium, amphibiorum, piscium, insectorum, vermium; the spider appeared under the name Aranea citricola.[4] C. citricola was classified in the Araneidae family because it creates orb-webs.[1] Between 1776 and 1864, the spider was classified under the genus Epeira, a synonym for Aranea, more commonly known as Araneus. The spider was moved from the genus Aranea to the genus Cyrtophora by Eugene Simon in 1864 – a decision made because its webs were so different from those constructed by other spiders in the genus Aranea.[5] C. citricola webs are horizontal and tent-shaped, similar to those of other spiders in the genus Cyrtophora. Like other members of Cyrtophora, C. citricola's 2nd, 3rd, and 4th pairs of legs have a shorter combined patella and tibia length than the femurs on the same legs. Additionally, it shares the same eye pattern where the posterior eye row is recurved: a typical genus-defining trait. C. citricola has broader cephalic structures than other orb-web spiders in the genus Manogea.[6]

Phylogeny edit

Cyrtophora citricola falls into the family Araneidae because of three characteristics. The male's palpal faces the mesial, or midline of the body. The male spider's palpal has an exoskeleton on their bulbous known as a radix, and the spider has a thin reflective layer of tissue in the posterior set of its eyes called the tapetum.[7] C. citricola differs from “derived araneoids”, which are a part of the superfamily Araneoidea, such as Theridion and Linyphiidae, because it lacks smaller aciniform spigots in their median spinnerets. These spigots each individually produce a strand of aciniform silk, the strongest type of spider silk.[8] C. citricola is a part of the argiopoid clade because there is a sexual dimorphism between males and females. Female are larger than males. The sexual dimorphism present in C. citricola separates them from members of the Araneinae subfamily including Nuctenea, Cyclosa, and Mangora.[7] C. citricola is a part of the Cyrtophorinae subfamily and shares the sexual dimorphism trait with the Argiopinae, Gasteracanthinae, and Micratheninae subfamilies. Within the argiopoid clade, C. citricola is a member of the argiopine clade because the upper section of its exoskeleton is hairy.[7] This trait distinguishes C. citricola from the Gasteracanthinae and Micratheninae subfamilies. Within the argiopine clade, C. citricola is a member of the Cyrtophorinae family, which includes the genera Cyrtophora and Manogea. Cyrtophorinae's subfamily defining features are its embolus, the palpal bulb's open duct, running in a counterclockwise direction, and its non-adhesive orb-webs.[7]

Description edit

Cyrtophora citricola occurs in various colors and may have different colored spots on the abdomen. The spider is sexually dimorphic. Females may reach 10 millimetres (0.39 in) long and are larger than their male counterparts who are usually 3 millimetres (0.12 in) long. C. citricola's legs are different lengths with legs I and II being the longest.[6] In Florida, male spiders are black, while females can change the color of their abdomens to match their surroundings and can camouflage in their webs. The females have white trichobothria. In Turkey, they usually appear brown with grey hair. C. citricola has a distinctive horizontal bifurcation at the posterior abdomen.[9][10] C. citricola is different from its other relatives because it has two pairs of dorsal tubercles and a pair of posterior tubercles.[6] C. citricola typically has seven denticles. The opisthosoma has two dorsal pairs of protuberances and two posterior lobes.[11] C. citricola has two rows of eyes. The largest eyes are the two median eyes in the anterior row.[12] In some places, C. citricola may be confused with Mecynogea lemniscata.[13]

Habitat and distribution edit

Cyrtophora citricola is found in Asia, Africa, Australia, Costa Rica, Hispaniola, Colombia, and Southern Europe.[2] The species is unable to survive in temperatures below -1 °C (30.2 °F).[10] C. citricola was also discovered in Florida in 2000 and it makes its webs on canal bridges from the east end of Everglades National Park to the east coast. The spider lives in a wide range of environments, but it is most prevalent in olive orchards and undergrowth.[6] C. citricola is also found in tropical agricultural operations.[2]

C. citricola can be found globally, unlike its close relatives that are concentrated in specific parts of the world. C. citricola's global presence may be a problem as seen in the Americas.[14] The spider is becoming common in agricultural and urban spaces. It is damaging farm operations. Currently, there are active efforts to remove the spider as its web is known to damage flora.[9]

C. citricola exhibits thermoregulative behaviors. This trait is common in web-building spiders, including Nephila clavipes, N. maculata, and Frontinella communis. During the hottest portions of the day, the spider will position themselves so that as little surface area of their body is shown to the sun as possible.

Behavior edit

Web edit

Cyrtophora citricola builds tent-webs that have a horizontal orb web and a network of webs above it resembling a tent.[1] These webs can be built alone or as part of a colony. The spiders exhibit advantages living in colonies, but there is no selection towards either solitary or colonial living.[15] Within colonies, the horizontal orb webs are solitary and maintained by individuals.[2] Other Araneidae species have a triad complex on their posterior spinnerets which produce a gluey thread material for the webs from the piriform glands. C. citricola lacks a triad complex and is unable to make gluey thread web material so it creates a distinct non-sticky, mesh-like web.[16]

C. citricola creates a thick silk strand barrier above the orb and a thinner barrier below the orb. The silk above the web is used to deflect insects onto the orb web below.[1] The webs above and below the horizontal orb webs are communal and maintained by the colony.[2] The horizontal orb web and silk are not sticky.[1][10] The orb webs appear as a fine mesh curtaining, made of radii and a non-adhesive structural spiral. This structure is different than the typical Araneidae family webs, as they lack a viscid spiral. These webs are durable, and may have evolved to be created outside of citrus trees. The webs may be large enough to span entire trees and are found on a variety of tree species.[9][10] C. citricola prefers to build its webs on firm substrates rather than non-firm substrates. Webs built on firmer substrates tend to last for longer periods of time.[17] The webs are strong enough to withstand environmental pressures, such as rain and wind.[18] Unlike adhesive webs, which must be respun daily, non-adhesive webs are only repaired when damaged. Most of this damage occurs at the peripheries of colony webs where the costs to create orb-webs is high. The center of these colonies infrequently require repairs, saving the spider the constant investment of respinning the web.[1]

 
C. citricola web
 
C. citricola web detail

C. citricola typically rests with all of its legs underneath its body when it is not watching over its egg sacs and uses various motions to detect prey and intrusions. The spider sits on the hub of the web. This positioning occurs during the night and day.[18] C. citricola also participates in web jerking, an act of quickly pulling the radii with a front leg. Web jerking may occur in response to movement in the web and prey capturing. The behavior may allow the spider to accurately find objects in its web, assist in prey location, and transmit signals.[18] In addition, the spider engages in web shaking, motions that cause sudden and rapid shaking of its webs. This shaking is created by a downward motion from the spiders' legs. C. citricola engages in web shaking to dislodge prey stuck in the upper barrier of the web. It may also shake off approaching kleptoparasites.[18]

Prey edit

C. citricola captures its prey in the upper section of the web. The rate of prey per capita due to web deflection is relatively low and may cause spiders to aggregate together.[1] Spiders who live in social aggregates are more efficient at capturing prey than solitary spiders.[1][10]

The process of capturing prey includes multiple steps. The first step is either biting the prey or wrapping it in silk. The second step is pulling and cutting the prey out of the web. The third step involves transporting the prey to the hub of the web by either carrying it in its jaws or rewrapping it and carrying it in silk. In the fourth step, the spider feeds on the prey in the hub of the web.[18]

C. citricola has four attack sequences. In the first variation, the spider wraps its prey and bites it. After biting the prey, the spider removes the prey from the web, rewraps it, and transports it to the hub. The second sequence follows the steps of the first variation but skips the biting stage. The third variation starts with the spider biting its prey and wrapping its prey. Later, the prey is removed and rewrapped before being transported to the web hub. The fourth sequence involves spiders biting and pulling or cutting the prey. The prey is transported to the hub in the spider's jaws. Whether the prey is bitten, wrapped, or both is determined by the type of prey that is captured.[18]

C. citricola preys on moths and flies. These insects are bitten and carried to the hub on silk. Orthopteras are also captured and eaten by C. citricola using a variety of the above sequences. Other common prey include dragonflies, beetles, and pentatomids.[18]

Reproduction edit

C. citricola is active from the middle of summer to the beginning of fall and adults mate between June and September.[6] Adult male spiders look for females.[19] These spiders exhibit sexual cannibalism at high rates. Female spiders will often eat males after mating.[20] Females cannibalize males after most successful copulations, up to 100% of the time. Spider age and feeding state have no effect on whether the male will be cannibalized. This sexual cannibalism encourages males to be choosy when picking a female mate. Males prefer to mate younger, well-fed, and virgin females. Females are not as choosy in their male mates, but may prefer well-fed and older males. About 50% of females re-mate within ten days after their first copulation. Sexual cannibalism forces monogamy on the male spiders.[20]

The female begins the mating process. Females traditionally approach the male until they are 1 cm from the male. At this point, the male advances quickly towards the female and tries to insert his pedipalp. If successful, copulation begins and lasts for a few seconds. This is the stage at which copulation most often fails.[20]

Unlike other cannibalizing spiders, the male C. citricola does not somersault into the female's chelicerae. The female bends her cephalothorax and orients herself to attack the male's abdomen while the pedipalp is in the female. The male is eaten and the pedipalp is detached from the female.[20]

Sociality edit

 
C. citricola in Gorongosa National Park[21]

C. citricola may exhibit aggregate social interactions with one another and live cooperatively in groups.[2] This behavior is distinct amongst spiders, as most spiders are solitary.[1] C. citricola make their own individual webs, but these webs are interconnected. This large network of webs with neighboring spiders creates a massive web matrix. Given the large size and visibility of the colonial web, prey who are visually acute may avoid approaching the colony.[1] If one member of a colonial group senses a nearby predator or prey, they perform a knee jerk on the web. This jerk often begins a chain reaction; up to 75% of nearby spiders may follow suit and jerk their webs as well.[1] Within colonies, there are three zones where spiders may live: the outside, the intermediate, and the inside zones. Spiders living in the intermediate zone have the best rates of prey capture.[2] Larger colonies have higher prey capture rates compared to smaller colonies and capture rates are higher for spiders at night compared to day.[1]

C. citricola generally coexist peacefully. They may exhibit aggressive behaviors if another spider tries to take their prey.[10][20][22] Colony living may have evolved because of the foraging benefits of group living for the spiders, although solitary living may be favored when prey is scarce. Conditional sociality is another evolutionary explanation for why group living evolved in this species.[15] Possibilities for this development may be protection against parasites or predators and how colonial webs allow juveniles to easily create their first webs.[2]

Some C. citricola live individually with no colony, alone without other organisms. Solitary spiders have larger webs, produce more eggs, and have more kleptoparasites than colonies. There is no difference in female size and prey capture rates when comparing colonial and solitary spiders. There are two hypotheses for the limited physical differences between solitary and colonial spiders. The first hypothesis is that spiders can move back and forth between colonial and solitary living throughout their lives. The second hypothesis is that prey capture is similar in both colonial and solitary spiders, allowing for similar physical development. Both hypotheses may explain the many similarities between solitary and colonial spiders.[2]

Territoriality edit

C. citricola exhibits territorial behavior over its orb-webs, but tent webs are communal and no aggressive behavior was documented between spiders that travel across these webs. At night there are conflicts between orb-less spiders and orb-possessing spiders. These fights occur due to competition for better feeding locations. Larger spiders typically win in fights over smaller spiders.[15] Invading spiders may come from the colony's periphery, where costs to build webs are often high due to continuous repair and diminished prey capture. Peripheral webs often experience damage from weather and predators whereas central webs remain undisturbed.[1] Conflict arises when an orb-less intruder approaches and vibrates the web. This action is a sign of attack and solicits the same response from the defending spider. The vibrations between the attacker and the defender continue for a few minutes; however, the invader rarely captures the web and instead it retreats.[1]

Parental care edit

The egg sacs of C. citricola have a diameter ranging from 12–20 millimetres (0.47–0.79 in). These egg sacs are laid in chains of up to 10 sacs in a row on the webs. The eggs are colored bluish-green. Each egg sac contains between 100 and 200 eggs and the eggs are shaped as flat ellipticals.[10][20] The number of eggs produced depends on various environmental factors, including food availability. Solitary females can produce up to 20% more eggs than females living in colonies.[2] The reduction of eggs in colonies may be due to better parasite protection and reduced predation.[20] Females with egg sacs will typically rest directly underneath the egg sac in order to guard them.[18]

Juveniles usually disperse or build their own webs off the maternal webs after four days.[23] Juveniles in larger webs are less likely to leave their mother's web. Mothers feed offspring, but when prey is scarce there is increased sibling aggression. These resource-poor conditions increase the likelihood of early dispersal from the maternal web.[23]

C. citricola prefers to select nest sites and create webs in the forks between branches and leaves.[24]

Predators and parasitoids edit

Argyrodes argyrodes, another species of spider, may steal Cyrtophora citricola's prey and eggs.[2][10] In addition, Holocnemus pluchei, also known as daddy long-legs, has been found to build their webs off of C. citricola's webs. H. pluchei exhibit aggressive behavior towards C. citricola and are observed eating C. citricola juveniles.[2] C. citricola will drop to the ground if attacked, in an attempt to camouflage.[19] C. citricola may also pull all of its legs inwards towards its abdomen.[18]

A. gibbosus often acts as a kleptoparasite to C. citricola, stealing prey that the C. citricola caught.[2] A. gibbosus is known to switch strategies depending on where the host is located. Prey is stolen when the host is in the hub of the web. A. gibbosus has been observed waiting for C. citricola to go foraging before consuming their eggs.[25]

Pediobius pyrgo is a type of wasp that lays its eggs in C. citricola egg sacs. The wasp is present in the Iberian Peninsula and in the Canary Islands.[26] Philolema palanichamyi is another type of wasp that lays its eggs in C. citricola egg sacs. The wasp affects these spiders primarily in the Canary Islands and can parasitize around 40% of egg sacs. Wasp larvae feed on the spider's eggs and each larva will devour significant portions of the egg sacs; incubation lasts approximately seven weeks. Wasp larvae often cause a large portion of parasitized spider egg-sacs to die. Parasitization decreases emerging spiderling populations by approximately 60%.[26]

Protective coloration and behavior edit

Cyrtophora citricola can change its abdomen's color to blend in with the environment.[1] The coloring of the female Floridian spiders allows them to appear as brown, dead leaves when sitting in their webs, preventing potential predators from spotting them.[9][10]

Agricultural impact edit

Ornamental trees, fruit trees, and various flowering plants in the genus Eugenia including E. coronata, have high concentrations of Cyrtophora citricola. These plants and trees may experience incomplete death when C. citricola's webs span over their leaves.[9][10] This may be due to the thickness of the webs that can restrict airflow to the leaves. As a result, some authorities have opted to use high-pressure water sprayers and chemical controls to exterminate colonies.[10]

C. citricola is problematic for many agricultural operations in South America, including coffee and citrus plantations. It is listed as an important agricultural pest in the Dominican Republic due to its devastating impact on citrus trees.[27] Additionally, it is increasingly common in the Southern states of North America. In Florida, the spider has become a common backyard nuisance.[26]

References edit

  1. ^ a b c d e f g h i j k l m n o Rypstra, Ann L. (1979). "Foraging flocks of spiders: a study of aggregate behavior in Cyrtophora citricola Forskål (Araneae; Araneidae) in West Africa". Behavioral Ecology and Sociobiology. 5 (3): 291–300. doi:10.1007/BF00293677. JSTOR 4599237. S2CID 37651094.
  2. ^ a b c d e f g h i j k l m Leborgne, R.; Cantarella, T.; Pasquet, A. (1998-05-01). "Colonial life versus solitary life in Cyrtophora citricola (Araneae, Araneidae)". Insectes Sociaux. 45 (2): 125–134. doi:10.1007/s000400050074. S2CID 12052536.
  3. ^ a b Hepper, Frank (1987). "Current research on the plant specimens from the Niebuhr and Forsskal Yemen expedition, 1761–63". Proceedings of the Seminar for Arabian Studies. 17: 81–90. JSTOR 41223044.
  4. ^ a b Forsskal, Peter (1775). Descriptiones Animalium – Avium, amphibiorum, insectorum, vermium quæ in itinere orientali observavit Petrus Forskål. ex officina Mölleri.
  5. ^ Simon, Eugène (1892). Histoire naturelle des araignées. Paris: Roret. doi:10.5962/bhl.title.51973.
  6. ^ a b c d e Elverici, Mert; Teksam, Ilyas; Özkütük, Recep Sulhi; Kunt, Kadir Bogaç (2012-12-20). "Cyrtophora citricola (Araneae: Araneidae: Cyrtophorinae), a first record for Turkey". Arachnologische Mitteilungen. 44: 7–9. doi:10.5431/aramit4402.
  7. ^ a b c d Scharff, Nikolaj; Coddington, Jonathan A. (1997-08-01). "A phylogenetic analysis of the orb-weaving spider family Araneidae (Arachnida, Araneae)". Zoological Journal of the Linnean Society. 120 (4): 355–434. doi:10.1111/j.1096-3642.1997.tb01281.x. S2CID 32855761.
  8. ^ Tremblay, Marie-Laurence; Xu, Lingling; Lefèvre, Thierry; Sarker, Muzaddid; Orrell, Kathleen E.; Leclerc, Jérémie; Meng, Qing; Pézolet, Michel; Auger, Michèle; Liu, Xiang-Qin; Rainey, Jan K. (2015-06-26). "Spider wrapping silk fibre architecture arising from its modular soluble protein precursor". Scientific Reports. 5 (1): 11502. Bibcode:2015NatSR...511502T. doi:10.1038/srep11502. ISSN 2045-2322. PMC 4481645. PMID 26112753.
  9. ^ a b c d e Levi, Herbert Walter (1997). "The American orb weavers of the genera Mecynogea, Manogea, Kapogea and Cyrtophora (Araneae: Araneidae)". Bulletin of the Museum of Comparative Zoology at Harvard College. 155: 215–255 – via biodiversitylibrary.
  10. ^ a b c d e f g h i j k "Colonial Tentweb Orbweaver Cyrtophora citricola". entnemdept.ufl.edu. Retrieved 2020-10-20.
  11. ^ "araneae - Cyrtophora citricola". araneae.nmbe.ch. Retrieved 2020-10-20.
  12. ^ Levy, Gershom (April 2013). "Twelve genera of orb-weaver spiders (Araneae, Araneidae) from Israel". Israel Journal of Zoology. 43: 311–365. doi:10.1080/00212210.1997.10688919 (inactive 31 January 2024) – via Taylor Francis Online.{{cite journal}}: CS1 maint: DOI inactive as of January 2024 (link)
  13. ^ Franzini, P.Z.N; Van der Bank, F.H.; Dippenaar-Schoemann, A.S.; Yessoufou, K. (April 29, 2013). "Combined analyses of genetic and morphological data indicate more than one species of Cyrtophora (Araneae: Araneidae) in South Africa" (PDF). International Journal of Modern Biological Research: 21–34.
  14. ^ Sewlal, Jo-Anne Nina; Starr, Christopher K. (2011-05-23). "Preliminary Survey of the Spider Fauna of Great Inagua, Bahamas, W.I." The International Journal of Bahamian Studies. 17 (2): 3. doi:10.15362/ijbs.v17i2.137.
  15. ^ a b c Yip, Eric C.; Levy, Tanya; Lubin, Yael (2017-07-28). "Bad neighbors: hunger and dominance drive spacing and position in an orb-weaving spider colony". Behavioral Ecology and Sociobiology. 71 (8): 128. doi:10.1007/s00265-017-2357-6. S2CID 23620793.
  16. ^ Peters, Hans M. (1993-10-01). "Functional organization of the spinning apparatus of Cyrtophora citricola with regard to the evolution of the web (Araneae, Araneidae)". Zoomorphology. 113 (3): 153–163. doi:10.1007/BF00394856. S2CID 44616019.
  17. ^ Brenes, Ruth Madrigal (August 2012). "Substrate selection for web-building in Cyrtophora citricola (Araneae: Araneidae)". Journal of Arachnology. 40 (2): 249–251. doi:10.1636/Hi11-30.1. S2CID 86047610.
  18. ^ a b c d e f g h i Lubin, Y. D. (1980). "The predatory behavior of Cyrtophora (Araneae: Araneidae)". Journal of Arachnology. 8 (2): 159–185. JSTOR 3705189.
  19. ^ a b "Cyrtophora citricola (Tent-web spider)". biodiversityexplorer.info. Retrieved 2020-10-20.
  20. ^ a b c d e f g Yip, Eric C.; Berner-Aharon, Na’ama; Smith, Deborah R.; Lubin, Yael (2016-06-01). "Coy males and seductive females in the sexually cannibalistic colonial spider, Cyrtophora citricola". PLOS ONE. 11 (6): e0155433. Bibcode:2016PLoSO..1155433Y. doi:10.1371/journal.pone.0155433. PMC 4889064. PMID 27249787.
  21. ^ "Tropical Tentweb Spider - Cyrtophora citricola, Gorongosa National Park, Mozambique" by Judy Gallagher is licensed under CC BY 2.0 license. Copyright
  22. ^ Lubin, YD (1974). "Adaptative advantages and the evolution of colony formation in Cyrtophora". Zoological Journal of the Linnean Society. 54: 321–339. doi:10.1111/j.1096-3642.1974.tb00806.x.
  23. ^ a b Yip, Eric C.; Rao, Dinesh; Smith, Deborah R.; Lubin, Yael (2019). "Interacting maternal and spatial cues influence natal – dispersal out of social groups". Oikos. 128 (12): 1793–1804. doi:10.1111/oik.06531. S2CID 201206535.
  24. ^ Mishra, Abhinav; Rastogi, Neelkamal (2020-09-01). "Unraveling the roles of solitary and social web-making spiders in perennial ecosystems: influence on pests and beneficials". Proceedings of the National Academy of Sciences, India Section B: Biological Sciences. 90 (3): 567–576. doi:10.1007/s40011-019-01126-5. S2CID 199369382.
  25. ^ Pasquet, Alain; Leborgne, Raymond; Cantarella, Theresa (2010-04-26). "Opportunistic egg feeding in the lleptoparasitic spider Argyrodes gibbosus". Ethology. 103 (2): 160–170. doi:10.1111/j.1439-0310.1997.tb00015.x.
  26. ^ a b c Chuang, Angela; Gates, Michael W.; Grinsted, Lena; Askew, Richard; Leppanen, Christy (2019-09-02). "Two hymenopteran egg sac associates of the tent-web orbweaving spider, Cyrtophora citricola (Forskål, 1775) (Araneae, Araneidae)". ZooKeys (874): 1–18. doi:10.3897/zookeys.874.36656. PMC 6733805. PMID 31537957.
  27. ^ Serra, C.A.; Jorge, P.E.; Abud-Antun, A.J.; Alvarez, P.; Perguero, B. (2003). "Invasive alien species in the Dominican Republic: their impact and strategies to manage introduced pests". Proceedings of the Caribbean Food Crops Society. 39: 102–118. doi:10.22004/AG.ECON.256720.
Sources
  • Álvares, É.S.S. & De Maria, M. (2004). First record of Cyrtophora citricola (Forskål) in Brazil (Araneae, Araneidae). Revista Brasileira de Zoologia 21(1):155-156 PDF doi:10.1590/S0101-81752004000100026
  • Edwards, G.B. (2012): Cyrtophora citricola (Araneae: Araneidae), a Colonial Tentweb Orbweaver Established in Florida. DPI Entomology Circular 411:.
  • Platnick, Norman I. (2009): The world spider catalog, version 10.0. American Museum of Natural History.

External links edit

 
Wikimedia Commons has media related to Cyrtophora citricola.
  • Pictures and information on C. citricola from Portugal
  • Cyrtophora citricola on the UF / IFAS Featured Creatures website.

April 12, 2024
cyrtophora, citricola, also, known, tropical, tent, spider, weaver, spider, family, araneidae, found, asia, africa, australia, costa, rica, hispaniola, colombia, southern, europe, 2000, discovered, florida, citricola, differs, from, many, close, relatives, abi. Cyrtophora citricola also known as the tropical tent web spider is an orb weaver spider in the family Araneidae It is found in Asia Africa Australia Costa Rica Hispaniola Colombia and Southern Europe and in 2000 it was discovered in Florida C citricola differs from many of its close relatives due its ability to live in a wide variety of environments In North America and South America the spider has caused extensive damage to agricultural operations Cyrtophora citricolaC citricola from PortugalScientific classificationDomain EukaryotaKingdom AnimaliaPhylum ArthropodaSubphylum ChelicerataClass ArachnidaOrder AraneaeInfraorder AraneomorphaeFamily AraneidaeGenus CyrtophoraSpecies C citricolaBinomial nameCyrtophora citricola Forskal 1775 SynonymsAranea citricolaEpeira opuntiaeEpeira cacti opuntiaeEpeira citricolaEpeira emarginataEpeira flavaEpeira purpureaEpeira dorsuosaCyrtophora sculptilisCyrtophora opuntiaeEpeira cajetanaAraneus citricolaCyrtophora dorsuosaC citricola is in the orb web spider family but its orb webs are considered atypical They have a thick silk strand barrier above the orb and a thinner barrier below the orb This gives the webs a horizontal mesh like appearance The spider has developed distinct and specific prey capturing techniques using its unconventional webs The prey flies into the upper mesh layer of the web and is deflected into the orb web The spider then collects and stores the prey in its web The difference in C citricola s web silk stems from physiological variations in its spinning apparatuses as compared to other closely related species Its webs are non adhesive and do not require daily respinning This spider is one of the few species to exhibit a variable level of sociality C citricola can be seen in colonies which may have arisen due to reduced predation Within these colonies each spider has its own web that is linked to other spiders through communal webbing The spider webs are often built in large matrices next to one another and can span entire trees The spider usually peacefully coexists with other spiders in the colony However at times the spider may have to ward off other spiders in the colony that may try and claim its web 1 C citricola is nocturnal only performing necessary tasks during the day During the day it remains idle and tries to stay out of sight from predators Most of its foraging and prey capture happen at night 2 C citricola s color and size can vary greatly Many spiders sport a black and white pattern while others are brown Males often appear black Male and female spiders have a sexual dimorphism The body length in females normally reaches 10 millimetres 0 39 in while males are only 3 millimetres 0 12 in long Contents 1 Taxonomy 1 1 Phylogeny 2 Description 3 Habitat and distribution 4 Behavior 4 1 Web 4 2 Prey 4 3 Reproduction 4 4 Sociality 4 5 Territoriality 4 6 Parental care 5 Predators and parasitoids 5 1 Protective coloration and behavior 6 Agricultural impact 7 References 8 External linksTaxonomy editPeter Forsskal discovered Cyrtophora citricola in the Arabian Peninsula during his Yemen expedition sometime between 1761 and 1763 3 He first saw the spiders in citrus trees and described their horizontal webs as nets The spider s common name tropical tent web derives from these observations 4 Unfortunately Forsskal died in Yemen in 1763 His manuscripts which included details of the spider were collected and sent back to Denmark by his friend Carsten Niebuhr 3 These records were published in 1775 as Descriptiones animalium avium amphibiorum piscium insectorum vermium the spider appeared under the name Aranea citricola 4 C citricola was classified in the Araneidae family because it creates orb webs 1 Between 1776 and 1864 the spider was classified under the genus Epeira a synonym for Aranea more commonly known as Araneus The spider was moved from the genus Aranea to the genus Cyrtophora by Eugene Simon in 1864 a decision made because its webs were so different from those constructed by other spiders in the genus Aranea 5 C citricola webs are horizontal and tent shaped similar to those of other spiders in the genus Cyrtophora Like other members of Cyrtophora C citricola s 2nd 3rd and 4th pairs of legs have a shorter combined patella and tibia length than the femurs on the same legs Additionally it shares the same eye pattern where the posterior eye row is recurved a typical genus defining trait C citricola has broader cephalic structures than other orb web spiders in the genus Manogea 6 Phylogeny edit Cyrtophora citricola falls into the family Araneidae because of three characteristics The male s palpal faces the mesial or midline of the body The male spider s palpal has an exoskeleton on their bulbous known as a radix and the spider has a thin reflective layer of tissue in the posterior set of its eyes called the tapetum 7 C citricola differs from derived araneoids which are a part of the superfamily Araneoidea such as Theridion and Linyphiidae because it lacks smaller aciniform spigots in their median spinnerets These spigots each individually produce a strand of aciniform silk the strongest type of spider silk 8 C citricola is a part of the argiopoid clade because there is a sexual dimorphism between males and females Female are larger than males The sexual dimorphism present in C citricola separates them from members of the Araneinae subfamily including Nuctenea Cyclosa and Mangora 7 C citricola is a part of the Cyrtophorinae subfamily and shares the sexual dimorphism trait with the Argiopinae Gasteracanthinae and Micratheninae subfamilies Within the argiopoid clade C citricola is a member of the argiopine clade because the upper section of its exoskeleton is hairy 7 This trait distinguishes C citricola from the Gasteracanthinae and Micratheninae subfamilies Within the argiopine clade C citricola is a member of the Cyrtophorinae family which includes the genera Cyrtophora and Manogea Cyrtophorinae s subfamily defining features are its embolus the palpal bulb s open duct running in a counterclockwise direction and its non adhesive orb webs 7 Description editCyrtophora citricola occurs in various colors and may have different colored spots on the abdomen The spider is sexually dimorphic Females may reach 10 millimetres 0 39 in long and are larger than their male counterparts who are usually 3 millimetres 0 12 in long C citricola s legs are different lengths with legs I and II being the longest 6 In Florida male spiders are black while females can change the color of their abdomens to match their surroundings and can camouflage in their webs The females have white trichobothria In Turkey they usually appear brown with grey hair C citricola has a distinctive horizontal bifurcation at the posterior abdomen 9 10 C citricola is different from its other relatives because it has two pairs of dorsal tubercles and a pair of posterior tubercles 6 C citricola typically has seven denticles The opisthosoma has two dorsal pairs of protuberances and two posterior lobes 11 C citricola has two rows of eyes The largest eyes are the two median eyes in the anterior row 12 In some places C citricola may be confused with Mecynogea lemniscata 13 Habitat and distribution editCyrtophora citricola is found in Asia Africa Australia Costa Rica Hispaniola Colombia and Southern Europe 2 The species is unable to survive in temperatures below 1 C 30 2 F 10 C citricola was also discovered in Florida in 2000 and it makes its webs on canal bridges from the east end of Everglades National Park to the east coast The spider lives in a wide range of environments but it is most prevalent in olive orchards and undergrowth 6 C citricola is also found in tropical agricultural operations 2 C citricola can be found globally unlike its close relatives that are concentrated in specific parts of the world C citricola s global presence may be a problem as seen in the Americas 14 The spider is becoming common in agricultural and urban spaces It is damaging farm operations Currently there are active efforts to remove the spider as its web is known to damage flora 9 C citricola exhibits thermoregulative behaviors This trait is common in web building spiders including Nephila clavipes N maculata and Frontinella communis During the hottest portions of the day the spider will position themselves so that as little surface area of their body is shown to the sun as possible Behavior editWeb edit Cyrtophora citricola builds tent webs that have a horizontal orb web and a network of webs above it resembling a tent 1 These webs can be built alone or as part of a colony The spiders exhibit advantages living in colonies but there is no selection towards either solitary or colonial living 15 Within colonies the horizontal orb webs are solitary and maintained by individuals 2 Other Araneidae species have a triad complex on their posterior spinnerets which produce a gluey thread material for the webs from the piriform glands C citricola lacks a triad complex and is unable to make gluey thread web material so it creates a distinct non sticky mesh like web 16 C citricola creates a thick silk strand barrier above the orb and a thinner barrier below the orb The silk above the web is used to deflect insects onto the orb web below 1 The webs above and below the horizontal orb webs are communal and maintained by the colony 2 The horizontal orb web and silk are not sticky 1 10 The orb webs appear as a fine mesh curtaining made of radii and a non adhesive structural spiral This structure is different than the typical Araneidae family webs as they lack a viscid spiral These webs are durable and may have evolved to be created outside of citrus trees The webs may be large enough to span entire trees and are found on a variety of tree species 9 10 C citricola prefers to build its webs on firm substrates rather than non firm substrates Webs built on firmer substrates tend to last for longer periods of time 17 The webs are strong enough to withstand environmental pressures such as rain and wind 18 Unlike adhesive webs which must be respun daily non adhesive webs are only repaired when damaged Most of this damage occurs at the peripheries of colony webs where the costs to create orb webs is high The center of these colonies infrequently require repairs saving the spider the constant investment of respinning the web 1 nbsp C citricola web nbsp C citricola web detailC citricola typically rests with all of its legs underneath its body when it is not watching over its egg sacs and uses various motions to detect prey and intrusions The spider sits on the hub of the web This positioning occurs during the night and day 18 C citricola also participates in web jerking an act of quickly pulling the radii with a front leg Web jerking may occur in response to movement in the web and prey capturing The behavior may allow the spider to accurately find objects in its web assist in prey location and transmit signals 18 In addition the spider engages in web shaking motions that cause sudden and rapid shaking of its webs This shaking is created by a downward motion from the spiders legs C citricola engages in web shaking to dislodge prey stuck in the upper barrier of the web It may also shake off approaching kleptoparasites 18 Prey edit C citricola captures its prey in the upper section of the web The rate of prey per capita due to web deflection is relatively low and may cause spiders to aggregate together 1 Spiders who live in social aggregates are more efficient at capturing prey than solitary spiders 1 10 The process of capturing prey includes multiple steps The first step is either biting the prey or wrapping it in silk The second step is pulling and cutting the prey out of the web The third step involves transporting the prey to the hub of the web by either carrying it in its jaws or rewrapping it and carrying it in silk In the fourth step the spider feeds on the prey in the hub of the web 18 C citricola has four attack sequences In the first variation the spider wraps its prey and bites it After biting the prey the spider removes the prey from the web rewraps it and transports it to the hub The second sequence follows the steps of the first variation but skips the biting stage The third variation starts with the spider biting its prey and wrapping its prey Later the prey is removed and rewrapped before being transported to the web hub The fourth sequence involves spiders biting and pulling or cutting the prey The prey is transported to the hub in the spider s jaws Whether the prey is bitten wrapped or both is determined by the type of prey that is captured 18 C citricola preys on moths and flies These insects are bitten and carried to the hub on silk Orthopteras are also captured and eaten by C citricola using a variety of the above sequences Other common prey include dragonflies beetles and pentatomids 18 Reproduction edit C citricola is active from the middle of summer to the beginning of fall and adults mate between June and September 6 Adult male spiders look for females 19 These spiders exhibit sexual cannibalism at high rates Female spiders will often eat males after mating 20 Females cannibalize males after most successful copulations up to 100 of the time Spider age and feeding state have no effect on whether the male will be cannibalized This sexual cannibalism encourages males to be choosy when picking a female mate Males prefer to mate younger well fed and virgin females Females are not as choosy in their male mates but may prefer well fed and older males About 50 of females re mate within ten days after their first copulation Sexual cannibalism forces monogamy on the male spiders 20 The female begins the mating process Females traditionally approach the male until they are 1 cm from the male At this point the male advances quickly towards the female and tries to insert his pedipalp If successful copulation begins and lasts for a few seconds This is the stage at which copulation most often fails 20 Unlike other cannibalizing spiders the male C citricola does not somersault into the female s chelicerae The female bends her cephalothorax and orients herself to attack the male s abdomen while the pedipalp is in the female The male is eaten and the pedipalp is detached from the female 20 Sociality edit nbsp C citricola in Gorongosa National Park 21 C citricola may exhibit aggregate social interactions with one another and live cooperatively in groups 2 This behavior is distinct amongst spiders as most spiders are solitary 1 C citricola make their own individual webs but these webs are interconnected This large network of webs with neighboring spiders creates a massive web matrix Given the large size and visibility of the colonial web prey who are visually acute may avoid approaching the colony 1 If one member of a colonial group senses a nearby predator or prey they perform a knee jerk on the web This jerk often begins a chain reaction up to 75 of nearby spiders may follow suit and jerk their webs as well 1 Within colonies there are three zones where spiders may live the outside the intermediate and the inside zones Spiders living in the intermediate zone have the best rates of prey capture 2 Larger colonies have higher prey capture rates compared to smaller colonies and capture rates are higher for spiders at night compared to day 1 C citricola generally coexist peacefully They may exhibit aggressive behaviors if another spider tries to take their prey 10 20 22 Colony living may have evolved because of the foraging benefits of group living for the spiders although solitary living may be favored when prey is scarce Conditional sociality is another evolutionary explanation for why group living evolved in this species 15 Possibilities for this development may be protection against parasites or predators and how colonial webs allow juveniles to easily create their first webs 2 Some C citricola live individually with no colony alone without other organisms Solitary spiders have larger webs produce more eggs and have more kleptoparasites than colonies There is no difference in female size and prey capture rates when comparing colonial and solitary spiders There are two hypotheses for the limited physical differences between solitary and colonial spiders The first hypothesis is that spiders can move back and forth between colonial and solitary living throughout their lives The second hypothesis is that prey capture is similar in both colonial and solitary spiders allowing for similar physical development Both hypotheses may explain the many similarities between solitary and colonial spiders 2 Territoriality edit C citricola exhibits territorial behavior over its orb webs but tent webs are communal and no aggressive behavior was documented between spiders that travel across these webs At night there are conflicts between orb less spiders and orb possessing spiders These fights occur due to competition for better feeding locations Larger spiders typically win in fights over smaller spiders 15 Invading spiders may come from the colony s periphery where costs to build webs are often high due to continuous repair and diminished prey capture Peripheral webs often experience damage from weather and predators whereas central webs remain undisturbed 1 Conflict arises when an orb less intruder approaches and vibrates the web This action is a sign of attack and solicits the same response from the defending spider The vibrations between the attacker and the defender continue for a few minutes however the invader rarely captures the web and instead it retreats 1 Parental care edit The egg sacs of C citricola have a diameter ranging from 12 20 millimetres 0 47 0 79 in These egg sacs are laid in chains of up to 10 sacs in a row on the webs The eggs are colored bluish green Each egg sac contains between 100 and 200 eggs and the eggs are shaped as flat ellipticals 10 20 The number of eggs produced depends on various environmental factors including food availability Solitary females can produce up to 20 more eggs than females living in colonies 2 The reduction of eggs in colonies may be due to better parasite protection and reduced predation 20 Females with egg sacs will typically rest directly underneath the egg sac in order to guard them 18 Juveniles usually disperse or build their own webs off the maternal webs after four days 23 Juveniles in larger webs are less likely to leave their mother s web Mothers feed offspring but when prey is scarce there is increased sibling aggression These resource poor conditions increase the likelihood of early dispersal from the maternal web 23 C citricola prefers to select nest sites and create webs in the forks between branches and leaves 24 Predators and parasitoids editArgyrodes argyrodes another species of spider may steal Cyrtophora citricola s prey and eggs 2 10 In addition Holocnemus pluchei also known as daddy long legs has been found to build their webs off of C citricola s webs H pluchei exhibit aggressive behavior towards C citricola and are observed eating C citricola juveniles 2 C citricola will drop to the ground if attacked in an attempt to camouflage 19 C citricola may also pull all of its legs inwards towards its abdomen 18 A gibbosus often acts as a kleptoparasite to C citricola stealing prey that the C citricola caught 2 A gibbosus is known to switch strategies depending on where the host is located Prey is stolen when the host is in the hub of the web A gibbosus has been observed waiting for C citricola to go foraging before consuming their eggs 25 Pediobius pyrgo is a type of wasp that lays its eggs in C citricola egg sacs The wasp is present in the Iberian Peninsula and in the Canary Islands 26 Philolema palanichamyi is another type of wasp that lays its eggs in C citricola egg sacs The wasp affects these spiders primarily in the Canary Islands and can parasitize around 40 of egg sacs Wasp larvae feed on the spider s eggs and each larva will devour significant portions of the egg sacs incubation lasts approximately seven weeks Wasp larvae often cause a large portion of parasitized spider egg sacs to die Parasitization decreases emerging spiderling populations by approximately 60 26 Protective coloration and behavior edit Cyrtophora citricola can change its abdomen s color to blend in with the environment 1 The coloring of the female Floridian spiders allows them to appear as brown dead leaves when sitting in their webs preventing potential predators from spotting them 9 10 Agricultural impact editOrnamental trees fruit trees and various flowering plants in the genus Eugenia including E coronata have high concentrations of Cyrtophora citricola These plants and trees may experience incomplete death when C citricola s webs span over their leaves 9 10 This may be due to the thickness of the webs that can restrict airflow to the leaves As a result some authorities have opted to use high pressure water sprayers and chemical controls to exterminate colonies 10 C citricola is problematic for many agricultural operations in South America including coffee and citrus plantations It is listed as an important agricultural pest in the Dominican Republic due to its devastating impact on citrus trees 27 Additionally it is increasingly common in the Southern states of North America In Florida the spider has become a common backyard nuisance 26 References edit a b c d e f g h i j k l m n o Rypstra Ann L 1979 Foraging flocks of spiders a study of aggregate behavior in Cyrtophora citricola Forskal Araneae Araneidae in West Africa Behavioral Ecology and Sociobiology 5 3 291 300 doi 10 1007 BF00293677 JSTOR 4599237 S2CID 37651094 a b c d e f g h i j k l m Leborgne R Cantarella T Pasquet A 1998 05 01 Colonial life versus solitary life in Cyrtophora citricola Araneae Araneidae Insectes Sociaux 45 2 125 134 doi 10 1007 s000400050074 S2CID 12052536 a b Hepper Frank 1987 Current research on the plant specimens from the Niebuhr and Forsskal Yemen expedition 1761 63 Proceedings of the Seminar for Arabian Studies 17 81 90 JSTOR 41223044 a b Forsskal Peter 1775 Descriptiones Animalium Avium amphibiorum insectorum vermium quae in itinere orientali observavit Petrus Forskal ex officina Molleri Simon Eugene 1892 Histoire naturelle des araignees Paris Roret doi 10 5962 bhl title 51973 a b c d e Elverici Mert Teksam Ilyas Ozkutuk Recep Sulhi Kunt Kadir Bogac 2012 12 20 Cyrtophora citricola Araneae Araneidae Cyrtophorinae a first record for Turkey Arachnologische Mitteilungen 44 7 9 doi 10 5431 aramit4402 a b c d Scharff Nikolaj Coddington Jonathan A 1997 08 01 A phylogenetic analysis of the orb weaving spider family Araneidae Arachnida Araneae Zoological Journal of the Linnean Society 120 4 355 434 doi 10 1111 j 1096 3642 1997 tb01281 x S2CID 32855761 Tremblay Marie Laurence Xu Lingling Lefevre Thierry Sarker Muzaddid Orrell Kathleen E Leclerc Jeremie Meng Qing Pezolet Michel Auger Michele Liu Xiang Qin Rainey Jan K 2015 06 26 Spider wrapping silk fibre architecture arising from its modular soluble protein precursor Scientific Reports 5 1 11502 Bibcode 2015NatSR 511502T doi 10 1038 srep11502 ISSN 2045 2322 PMC 4481645 PMID 26112753 a b c d e Levi Herbert Walter 1997 The American orb weavers of the genera Mecynogea Manogea Kapogea and Cyrtophora Araneae Araneidae Bulletin of the Museum of Comparative Zoology at Harvard College 155 215 255 via biodiversitylibrary a b c d e f g h i j k Colonial Tentweb Orbweaver Cyrtophora citricola entnemdept ufl edu Retrieved 2020 10 20 araneae Cyrtophora citricola araneae nmbe ch Retrieved 2020 10 20 Levy Gershom April 2013 Twelve genera of orb weaver spiders Araneae Araneidae from Israel Israel Journal of Zoology 43 311 365 doi 10 1080 00212210 1997 10688919 inactive 31 January 2024 via Taylor Francis Online a href Template Cite journal html title Template Cite journal cite journal a CS1 maint DOI inactive as of January 2024 link Franzini P Z N Van der Bank F H Dippenaar Schoemann A S Yessoufou K April 29 2013 Combined analyses of genetic and morphological data indicate more than one species of Cyrtophora Araneae Araneidae in South Africa PDF International Journal of Modern Biological Research 21 34 Sewlal Jo Anne Nina Starr Christopher K 2011 05 23 Preliminary Survey of the Spider Fauna of Great Inagua Bahamas W I The International Journal of Bahamian Studies 17 2 3 doi 10 15362 ijbs v17i2 137 a b c Yip Eric C Levy Tanya Lubin Yael 2017 07 28 Bad neighbors hunger and dominance drive spacing and position in an orb weaving spider colony Behavioral Ecology and Sociobiology 71 8 128 doi 10 1007 s00265 017 2357 6 S2CID 23620793 Peters Hans M 1993 10 01 Functional organization of the spinning apparatus of Cyrtophora citricola with regard to the evolution of the web Araneae Araneidae Zoomorphology 113 3 153 163 doi 10 1007 BF00394856 S2CID 44616019 Brenes Ruth Madrigal August 2012 Substrate selection for web building in Cyrtophora citricola Araneae Araneidae Journal of Arachnology 40 2 249 251 doi 10 1636 Hi11 30 1 S2CID 86047610 a b c d e f g h i Lubin Y D 1980 The predatory behavior of Cyrtophora Araneae Araneidae Journal of Arachnology 8 2 159 185 JSTOR 3705189 a b Cyrtophora citricola Tent web spider biodiversityexplorer info Retrieved 2020 10 20 a b c d e f g Yip Eric C Berner Aharon Na ama Smith Deborah R Lubin Yael 2016 06 01 Coy males and seductive females in the sexually cannibalistic colonial spider Cyrtophora citricola PLOS ONE 11 6 e0155433 Bibcode 2016PLoSO 1155433Y doi 10 1371 journal pone 0155433 PMC 4889064 PMID 27249787 Tropical Tentweb Spider Cyrtophora citricola Gorongosa National Park Mozambique by Judy Gallagher is licensed under CC BY 2 0 license Copyright Lubin YD 1974 Adaptative advantages and the evolution of colony formation in Cyrtophora Zoological Journal of the Linnean Society 54 321 339 doi 10 1111 j 1096 3642 1974 tb00806 x a b Yip Eric C Rao Dinesh Smith Deborah R Lubin Yael 2019 Interacting maternal and spatial cues influence natal dispersal out of social groups Oikos 128 12 1793 1804 doi 10 1111 oik 06531 S2CID 201206535 Mishra Abhinav Rastogi Neelkamal 2020 09 01 Unraveling the roles of solitary and social web making spiders in perennial ecosystems influence on pests and beneficials Proceedings of the National Academy of Sciences India Section B Biological Sciences 90 3 567 576 doi 10 1007 s40011 019 01126 5 S2CID 199369382 Pasquet Alain Leborgne Raymond Cantarella Theresa 2010 04 26 Opportunistic egg feeding in the lleptoparasitic spider Argyrodes gibbosus Ethology 103 2 160 170 doi 10 1111 j 1439 0310 1997 tb00015 x a b c Chuang Angela Gates Michael W Grinsted Lena Askew Richard Leppanen Christy 2019 09 02 Two hymenopteran egg sac associates of the tent web orbweaving spider Cyrtophora citricola Forskal 1775 Araneae Araneidae ZooKeys 874 1 18 doi 10 3897 zookeys 874 36656 PMC 6733805 PMID 31537957 Serra C A Jorge P E Abud Antun A J Alvarez P Perguero B 2003 Invasive alien species in the Dominican Republic their impact and strategies to manage introduced pests Proceedings of the Caribbean Food Crops Society 39 102 118 doi 10 22004 AG ECON 256720 SourcesAlvares E S S amp De Maria M 2004 First record of Cyrtophora citricola Forskal in Brazil Araneae Araneidae Revista Brasileira de Zoologia 21 1 155 156 PDF doi 10 1590 S0101 81752004000100026 Edwards G B 2012 Cyrtophora citricola Araneae Araneidae a Colonial Tentweb Orbweaver Established in Florida DPI Entomology Circular 411 PDF Platnick Norman I 2009 The world spider catalog version 10 0 American Museum of Natural History External links edit nbsp Wikimedia Commons has media related to Cyrtophora citricola Pictures of C citricola Pictures and information on C citricola from Portugal Cyrtophora citricola on the UF IFAS Featured Creatures website Retrieved from https en wikipedia org w index php title Cyrtophora citricola amp oldid 1201867853, 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