Spatiotemporal niche‐based mechanisms support a stable coexistence of ants and spiders in an extrafloral nectary‐bearing plant community

Lange, Denise; Calixto, Eduardo Soares; Del‐Claro, Kleber; Stefani, Vanessa

doi:10.1111/1365-2656.13477

Cited by 10 publications

(8 citation statements)

References 81 publications

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“…In some situations, nonant natural enemies can be the numerous visitors of EFN plants, which could in our setting also benefit neighbor trees. These natural enemies may attenuate the observed influence of EFN trees, for example, when spatiotemporal complementarity among enemy groups exists (Lange et al, 2021), but we could not reliably sample these mostly winged species with the applied beating method. In turn, ants could also reduce the abundance of other natural enemies.…”

Section: Facilitation May Be Driven By Efn-associated Antsmentioning

confidence: 99%

Dear neighbor: Trees with extrafloral nectaries facilitate defense and growth of adjacent undefended trees

Staab

Pietsch

Yan

et al. 2023

Ecology

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Plant diversity can increase productivity. One mechanism behind this biodiversity effect is facilitation, which is when one species increases the performance of another species. Plants with extrafloral nectaries (EFNs) establish defense mutualisms with ants. However, whether EFN plants facilitate defense of neighboring non-EFN plants is unknown. Synthesizing data on ants, herbivores, leaf damage, and defense traits from a forest biodiversity experiment, we show that trees growing adjacent to EFN trees had higher ant biomass and species richness and lower caterpillar biomass than conspecific controls without EFN-bearing neighbors. Concurrently, the composition of defense traits in non-EFN trees changed. Thus, when non-EFN trees benefit from lower herbivore loads as a result of ants spilling over from EFN tree neighbors, this may allow relatively reduced resource allocation to defense in the former, potentially explaining the higher growth of those trees. Via this mutualist-mediated facilitation, promoting EFN trees in tropical reforestation could foster carbon capture and multiple other ecosystem functions.

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Section: Facilitation May Be Driven By Efn-associated Antsmentioning

confidence: 99%

Dear neighbor: Trees with extrafloral nectaries facilitate defense and growth of adjacent undefended trees

Staab

Pietsch

Yan

et al. 2023

Ecology

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“…Spatial aggregations generally occur between species that share an ecological niche, as demonstrated by numerous studies (Azeria et al, 2012; Azeria, Fortin, Hébert, et al, 2009; Holt, 1984; Peres‐Neto, 2004; Sánchez‐Galván et al, 2018). However, studies of co‐occurrence patterns often do not include the temporal dimension (Lange et al, 2021), even when ‘true’ aggregation (i.e., where an interaction between the two species is highly likely) occurs spatially and temporally. In fact, by studying species phenology together with the spatial aggregations that resulted from statistical analyses, only 20% of the non‐random aggregation patterns, formed by species pairs A. scopolii – S. scutulatus and E. atrica – L. majus , occurred at the spatio‐temporal level.…”

Section: Discussionmentioning

confidence: 99%

“…In contrast, non‐random segregation patterns are attributed to competition phenomena (Camarota et al, 2016; Gotelli & Graves, 1996) or habitat filtering (Azeria et al, 2012; Oliveira‐Junior et al, 2021). In addition, co‐occurrence patterns can be studied at both the matrix (the whole community) and pairwise (species pairs) levels, although combining them is recommended because they provide different information (Lange et al, 2021; Oliveira‐Junior et al, 2021; Sánchez‐Galván et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Spatio‐temporal species aggregations do not rule out interspecific competition in tree hollow spider assemblages

Martínez‐Devesa,

Hernández‐Corral,

Micó

2023

Ecological Entomology

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A community's biological diversity reflects coexistence between species. This often depends, to some extent, on whether there is competition for resources and how it is dealt with. The nature of old‐growth tree hollows is confined and relatively isolated, which makes them ideal for investigating the competition phenomena between their inhabitants, such as Araneae. The existence of interspecific competition in the structuring of tree hollow spider assemblages in Mediterranean forests was inferred by spatial co‐occurrence pattern analyses with null models at both the community and pairwise levels. The analysis included 36 spider species collected monthly with emergence traps for 1 year. The distribution of four ecological traits, body size and phenology on the resulting pattern type was discussed. The analyses showed spatial segregation at the community level and spatial aggregations between species with different traits predominated at the pairwise level. Hunting strategy and body size were the main differential traits to facilitate these aggregations. In addition, only the aggregations led by Amaurobius scopolii–Scotophaeus scutulatus and Eratigena atrica–Liocranum majus also showed an overlap during their main activity period. Community segregation and spatio‐temporal aggregations of species with differential traits suggest that interspecific competition is a very likely structuring factor of tree hollow spider assemblages. Instead, segregations at the pairwise level seem to result from other factors, for example, habitat preferences.

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“…Total sugar content, which can include sucrose, is reported to be a determining factor in changes to ant foraging preferences to different EF nectars [47,48]. Typically, damage induces greater amounts of EF nectar produced, making more sugars available to foraging ants even if the concentration of sugars remains the same (e.g., [3,11,12,26,49].…”

Section: Plos Onementioning

confidence: 99%

“…Many plant species also recruit natural enemies by providing an attractive food source in the form of extrafloral (EF) nectar. EF nectar, which is typically rich in sucrose, glucose, and fructose, encourages ants, parasitoids, and other predatory arthropods such as spiders [3,4] to forage for carbohydrates on the plant (reviewed in [5]). This improves the chance of an encounter between the natural enemies and herbivores such as caterpillars that may be damaging the plant.…”

Section: Introductionmentioning

confidence: 99%

Foliar herbivory increases sucrose concentration in bracteal extrafloral nectar of cotton

et al. 2021

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Cultivated cotton, such as Gossypium hirsutum L., produces extrafloral (EF) nectar on leaves (foliar) and reproductive structures (bracteal) as an indirect anti-herbivore defense. In exchange for this carbohydrate-rich substance, predatory insects such as ants protect the plant against herbivorous insects. Some EF nectar-bearing plants respond to herbivory by increasing EF nectar production. For instance, herbivore-free G. hirsutum produces more bracteal than foliar EF nectar, but increases its foliar EF nectar production in response to herbivory. This study is the first to test for systemically induced changes to the carbohydrate composition of bracteal EF nectar in response to foliar herbivory on G. hirsutum. We found that foliar herbivory significantly increased the sucrose content of bracteal EF nectar while glucose and fructose remained unchanged. Sucrose content is known to influence ant foraging behavior and previous studies of an herbivore-induced increase to EF nectar caloric content found that it led to increased ant activity on the plant. As a follow-up to our finding, ant recruitment to mock EF nectar solutions that varied in sucrose content was tested in the field. The ants did not exhibit any preference for either solution, potentially because sucrose is a minor carbohydrate component in G. hirsutum EF nectar: total sugar content was not significantly affected by the increase in sucrose. Nonetheless, our findings raise new questions about cotton’s inducible EF nectar responses to herbivory. Further research is needed to determine whether an herbivore-induced increase in sucrose content is typical of Gossypium spp., and whether it constitutes a corollary of systemic sucrose induction, or a potentially adaptive mechanism which enhances ant attraction to the plant

show abstract

Spatiotemporal niche‐based mechanisms support a stable coexistence of ants and spiders in an extrafloral nectary‐bearing plant community

Cited by 10 publications

References 81 publications

Dear neighbor: Trees with extrafloral nectaries facilitate defense and growth of adjacent undefended trees

Dear neighbor: Trees with extrafloral nectaries facilitate defense and growth of adjacent undefended trees

Spatio‐temporal species aggregations do not rule out interspecific competition in tree hollow spider assemblages

Foliar herbivory increases sucrose concentration in bracteal extrafloral nectar of cotton

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