How Did the Spider Cross the River? Behavioral Adaptations for River-Bridging Webs in Caerostris darwini (Araneae: Araneidae)

Gregorič, Matjaž; Agnarsson, Ingi; Blackledge, Todd A.; Kuntner, Matjaž

doi:10.1371/journal.pone.0026847

Cited by 26 publications

(21 citation statements)

References 41 publications

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“…Recently there has been a renewed interest in the otherwise neglected area of spider neurophysiology with a number of anatomical studies on brain size and structure (Quesada et al, 2011;Park et al, 2013). Similar methods could be used to compare structures in the supraesophageal ganglion between spiders with extensive site exploration to spiders with hardly any, such as the Darwin's bark spider (Gregoric et al, 2011), in order to estimate the possible computational requirements of the behaviour. Even more promising is the potential of looking at the central nervous system of live spiders as they perform behaviours with new and more sophisticated electrophysiological and neuroimaging techniques.…”

Section: Resultsmentioning

confidence: 99%

Exploration behaviour and behavioural flexibility in orb-web spiders: A review

Hesselberg

2015

Current Zoology

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Orb-web spiders and their webs constitute an ideal model system in which to study behavioural flexibility and spatial cognition in invertebrates due to the easily quantifiable nature of the orb web. A large number of studies demonstrate how spiders are able to modify the geometry of their webs in response to a range of different conditions including the ability to adapt their webs to spatial constraints. However, the mechanisms behind this impressive web-building flexibility in these cognitively limited animals remain poorly explored. One possible mechanism though may be spatial learning during the spiders' exploration of their immediate surroundings. This review discusses the importance of exploration behaviour, the reliance on simple behavioural rules, and the use of already laid threads as guidelines for web-building in orb-web spiders. The focus is on the spiders' ability to detect and adapt their webs to space limitations and other spatial disruptions. I will also review the few published studies on how spatial information is gathered during the exploration phase and discuss the possibility of the use of 'cognitive map'-like processes in spiders. Finally, the review provides suggestions for designing experimental studies to shed light on whether spiders gather metric information during the site exploration (cognitive map hypothesis) or rely on more simple binary information in combination with previously laid threads to build their webs (stigmergy hypothesis) [Current Zoology 61 (2): 313-327, 2015].

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Section: Resultsmentioning

confidence: 99%

Exploration behaviour and behavioural flexibility in orb-web spiders: A review

Hesselberg

2015

Current Zoology

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“…The assumption that radii construction (MA silk) comes at an energetic cost that is satisfied when adequate food or food of adequate energy/nutrient quality is consumed [15], [16], [19] partially explains these findings. Nonetheless, variations in radii number in spider orb webs are often correlated with variations in other architectural parameters, for example mesh size [11], [14], [15], [41]. We found that mesh size co-varied with radii number in A. aemula but not C. mulmeinensis as a response to variations in the concentration of protein consumed.…”

Section: Discussionmentioning

confidence: 65%

Nutrient-Mediated Architectural Plasticity of a Predatory Trap

Blamires

Tso

2013

PLoS ONE

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BackgroundNutrients such as protein may be actively sought by foraging animals. Many predators exhibit foraging plasticity, but how their foraging strategies are affected when faced with nutrient deprivation is largely unknown. In spiders, the assimilation of protein into silk may be in conflict with somatic processes so we predicted web building to be affected under protein depletion.Methodology/Principal FindingsTo assess the influence of protein intake on foraging plasticity we fed the orb-web spiders Argiope aemula and Cyclosa mulmeinensis high, low or no protein solutions over 10 days and allowed them to build webs. We compared post-feeding web architectural components and major ampullate (MA) silk amino acid compositions. We found that the number of radii in webs increased in both species when fed high protein solutions. Mesh size increased in A. aemula when fed a high protein solution. MA silk proline and alanine compositions varied in each species with contrasting variations in alanine between the two species. Glycine compositions only varied in C. mulmeinensis silk. No spiders significantly lost or gained mass on any feeding treatment, so they did not sacrifice somatic maintenance for amino acid investment in silk.Conclusions/SignificanceOur results show that the amount of protein taken in significantly affects the foraging decisions of trap-building predators, such as orb web spiders. Nevertheless, the subtle differences found between species in the association between protein intake, the amino acids invested in silk and web architectural plasticity show that the influence of protein deprivation on specific foraging strategies differs among different spiders.

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“…Several araneids (genera Eriophora and Caerostris ) spin orb-webs of extraordinary size and tensile strength suspended upon bridge lines of several meters, which led to the assumption that such web gigantism might have evolved as an adaptation for capturing flying vertebrates such as bats and birds [57]–[59]. In the case of Caerostris darwini , an araneid which spins giant orb-webs of up to 2 m diameter across rivers in Madagascar suspended upon bridge lines exceeding 20 meters in length, chiropterophagy could not be evidenced so far [58]–[59]. However, in this latter study the sample size of recorded predation events was rather small [58]–[59].…”

Section: Resultsmentioning

confidence: 99%

“…In the case of Caerostris darwini , an araneid which spins giant orb-webs of up to 2 m diameter across rivers in Madagascar suspended upon bridge lines exceeding 20 meters in length, chiropterophagy could not be evidenced so far [58]–[59]. However, in this latter study the sample size of recorded predation events was rather small [58]–[59]. In the habitats of Caerostris darwini , several species of small riverine bats of the families Vespertilionidae and Emballonuridae occur who would be available as potential prey at least for a few weeks per year during which time their volant juveniles (weighing ∼2.5–4 g) are within the spiders’ prey size range (S. Goodman, pers.…”

Section: Resultsmentioning

confidence: 99%

Bat Predation by Spiders

Nyffeler

Knörnschild

2013

PLoS ONE

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In this paper more than 50 incidences of bats being captured by spiders are reviewed. Bat-catching spiders have been reported from virtually every continent with the exception of Antarctica (∼90% of the incidences occurring in the warmer areas of the globe between latitude 30° N and 30° S). Most reports refer to the Neotropics (42% of observed incidences), Asia (28.8%), and Australia-Papua New Guinea (13.5%). Bat-catching spiders belong to the mygalomorph family Theraphosidae and the araneomorph families Nephilidae, Araneidae, and Sparassidae. In addition to this, an attack attempt by a large araneomorph hunting spider of the family Pisauridae on an immature bat was witnessed. Eighty-eight percent of the reported incidences of bat catches were attributable to web-building spiders and 12% to hunting spiders. Large tropical orb-weavers of the genera Nephila and Eriophora in particular have been observed catching bats in their huge, strong orb-webs (of up to 1.5 m diameter). The majority of identifiable captured bats were small aerial insectivorous bats, belonging to the families Vespertilionidae (64%) and Emballonuridae (22%) and usually being among the most common bat species in their respective geographic area. While in some instances bats entangled in spider webs may have died of exhaustion, starvation, dehydration, and/or hyperthermia (i.e., non-predation death), there were numerous other instances where spiders were seen actively attacking, killing, and eating the captured bats (i.e., predation). This evidence suggests that spider predation on flying vertebrates is more widespread than previously assumed.

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How Did the Spider Cross the River? Behavioral Adaptations for River-Bridging Webs in Caerostris darwini (Araneae: Araneidae)

Cited by 26 publications

References 41 publications

Exploration behaviour and behavioural flexibility in orb-web spiders: A review

Exploration behaviour and behavioural flexibility in orb-web spiders: A review

Nutrient-Mediated Architectural Plasticity of a Predatory Trap

Bat Predation by Spiders

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