Climate seasonality drives ant–plant–herbivore interactions via plant phenology in an extrafloral nectary‐bearing plant community

Calixto, Eduardo Soares; Novaes, Letícia Rodrigues; Santos, Danilo Ferreira Borges dos; Lange, Denise; Moreira, Xoaquín; Del‐Claro, Kleber

doi:10.1111/1365-2745.13492

Cited by 46 publications

(60 citation statements)

References 65 publications

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“…These hypotheses are mainly based on the similarity of ants and spiders feeding behaviours, which can lead to competitive relationships and ultimately result in spatiotemporal niche segregation. Recently, we observed a significant peak of activity of ants in the rainy season at the same time as EFNs are active, considerably decreasing their activity (ants and EFNs) in the dry season (Calixto et al., 2020). Due to numerical representativeness and aggressive behaviour when on EFN‐bearing plants, ants can end up displacing spiders to other branches, and spiders can end up changing their phenological behaviours for periods of the year when there is less presence of ants in plants.…”

Section: Introductionmentioning

confidence: 85%

“…Furthermore, one may suggest that there is a temporal segregation during the day between ants and spiders, that is, ants occurring during the day and spiders at night. However, both groups are commonly present in EFN‐bearing plants in both periods of the day (Anjos et al., 2017; Calixto, Lange, Bronstein, et al., 2021; Calixto, Lange, & Del‐Claro, 2021; Calixto et al., 2020; Lange et al., 2017; Nahas et al., 2016).…”

Section: Methodsmentioning

confidence: 99%

“…Tropical savannas, such as the Brazilian Cerrado, is an advantageous environment to evaluate interspecific interactions and stabilizing mechanisms through the assessment of spatiotemporal co‐occurrence patterns. The Cerrado has two well‐defined seasons (rainy and dry season; Calixto et al., 2020; Novaes et al., 2020) and it is the most biodiverse savanna on Earth, considered a hotspot of biodiversity (Myers et al., 2000). These well‐marked climatic conditions can generate temporal partitions for the occurrence of different species.…”

Section: Introductionmentioning

confidence: 99%

“…These well‐marked climatic conditions can generate temporal partitions for the occurrence of different species. For instance, spiders and ants are among the most common predator arthropods inhabiting vegetation in this region (Calixto et al., 2018; Del‐Claro et al., 2017), which are frequently attracted by plant‐provided resources such as extrafloral nectar (Calixto et al., 2018; Calixto et al., 2020; Del‐Claro et al., 2017; Heil, 2015; Nahas et al., 2016; Taylor & Pfannenstiel, 2009). Extrafloral nectaries (EFNs) produce a sugar‐rich resource which is also composed of amino acids and other contents, works as a source of nutrient to balance the carbohydrate–protein ratio in the diet of ants and spiders (Byk & Del‐Claro, 2011; Calixto, Lange, Bronstein, et al., 2021; Lange et al., 2017; Nahas et al., 2016), and is mainly produced in the rainy season concomitantly to leaf flushing (Calixto et al., 2020; Lange et al., 2013).…”

Section: Introductionmentioning

confidence: 99%

“…To reach this goal, we assessed whether there are spatial‐ and temporal‐scale patterns of ants and spiders occurrence at both plant community and plant species level. We hypothesized that, although there is seasonal variation in resource availability (Belchior et al., 2016; Calixto et al., 2020; Lange et al., 2013), ants and spiders will coexist in plants through a spatiotemporal niche segregation. In particular, both groups could (a) occupy different branches if they are on the same plant at the same time (spatial non‐co‐occurrence patterns or spatial niche segregation); and (b) present greater abundance of individuals in different periods of the year (temporal non‐co‐occurrence patterns or temporal niche segregation).…”

Section: Introductionmentioning

confidence: 99%

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

Lange

Calixto

Del‐Claro

et al. 2021

Journal of Animal Ecology

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Mechanisms promoting stable coexistence allow multiple species to persist in the same trophic level of a given network of species interactions. One of the most common stabilizing mechanisms of coexistence is niche differentiation, such as temporal and spatial patchiness. To understand the limits of coexistence between species we have to understand the limits of competitive interactions which translate in species exclusion or patterns of non‐co‐occurrence. We evaluated spatiotemporal niche‐based mechanisms that could promote stable coexistence between ants and spiders which forage on extrafloral nectary (EFN)‐bearing plants. We observed co‐occurrence and overlapping patterns between ants and spiders in a temporal and spatial scale in nine different EFN‐bearing plant species in a Neotropical savanna, using both community and species‐level approach. Ants and spiders showed asynchrony of their abundances over the year with low temporal overlapping patterns between them (temporal niche specialization). Greater abundance of ants occurred between September and March, whereas greater abundance of spiders occurred between March and August, exactly at the time when the abundance of ants decreases on plants. However, there might also be some levels of temporal overlapping, but then individual ants and spiders occupy different branches (spatial segregation). Finally, we also observed a spatial negative effect of the abundance of ants on the presence of spiders. Our results suggest that spatiotemporal partitioning between ants and spiders may be one of the potential mechanisms behind a stable coexistence between these two groups of organisms that forage on EFN‐bearing plants in the Brazilian savanna.

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Section: Introductionmentioning

confidence: 85%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

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

Lange

Calixto

Del‐Claro

et al. 2021

Journal of Animal Ecology

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Time course of inducibility of indirect responses in an ant‐defended plant

Calixto

Del‐Claro

Lange

et al. 2023

Ecology

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Plants have evolved inducible defenses that allow them to minimize costs associated with the production of constitutive defenses when herbivores are not present. However, as a consequence, some plants might experience a period of vulnerability between damage and the onset of defense and/or between the cessation of damage and relaxation of defense. Few studies have examined the time course in the inducible protective mutualism between ants and extrafloral nectary (EFN)‐bearing plants. None has compared the inducibility of EFNs on vegetative versus reproductive parts or in response to different levels of herbivore damage. Here, we disentangle the inducibility process by evaluating extrafloral nectar production and ant attendance over time, the time course of inducibility on different plant parts, and the time course of inducibility in response to different levels of foliar damage in a Brazilian tree, Qualea multiflora (Vochysiaceae). Using simulated herbivory on leaves and flowers, we found that (a) the production of extrafloral nectar from foliar and floral EFNs, as well as ant attendance, exhibited a lag between the moment of damage and the peak of response, followed by a response peak (usually 24 h after damage) at which the defense remains at its maximum level, then declines to prestimulus levels; (b) the time course of inducibility and the peak activity did not differ between EFNs located in vegetative versus reproductive parts, except for sugar concentration, which was higher in EFNs on vegetative parts; and (c) the time course of inducibility of foliar EFNs depended on damage level. Although considered a cost‐saving strategy, inducible defenses can be disadvantageous since they can leave plants vulnerable to attack for extended periods. Our results illuminate the dynamics of the induced response and the underlying mechanisms that might mediate it, ultimately providing new insights into defense strategies employed by plants.

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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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Climate seasonality drives ant–plant–herbivore interactions via plant phenology in an extrafloral nectary‐bearing plant community

Cited by 46 publications

References 65 publications

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

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

Time course of inducibility of indirect responses in an ant‐defended plant

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

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