Nectar quality affects ant aggressiveness and biotic defense provided to plants

Pacelhe, Fábio T.; Costa, Fernanda Vieira da; Neves, Frederico S.; Bronstein, Judith L.; Mello, Marco A. R.

doi:10.1111/btp.12625

Cited by 30 publications

(34 citation statements)

References 76 publications

(99 reference statements)

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“…We can also predict that the extrafloral nectar produced on reproductive structures will be more attractive than that produced on vegetative structures, resulting in greater attraction of ants. Studies have shown that variation in extrafloral nectar production directly influences the ant community and ant foraging patterns (Bixenmann, Coley, & Kursar, 2011; Lange, Calixto, & Del‐Claro, 2017; Pacelhe, Costa, Bronstein, Mello, & Neves, 2019). Higher volumes of extrafloral nectar production attract more ants and can increase ant aggressiveness, resulting in improved plant defence (Falcão, Dáttilo, & Izzo, 2014; Pacelhe et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

“…For instance, Pacelhe et al. (2019) showed that the predatory activity of ants was higher on plants augmented with artifical extrafloral nectar composed of sugar and amino acids than in plants augmented with only sugar or amino acids or water. Thus, these studies show that more concentrated and nutritive extrafloral nectar influences ant foraging patterns.…”

Section: Introductionmentioning

confidence: 99%

“…Higher volumes of extrafloral nectar production attract more ants and can increase ant aggressiveness, resulting in improved plant defence (Falcão, Dáttilo, & Izzo, 2014;Pacelhe et al, 2019). For instance, Pacelhe et al (2019) showed that the predatory activity of ants was higher on plants augmented with artifical extrafloral nectar composed of sugar and amino acids than in plants augmented with only sugar or amino acids or water. Thus, these studies show that more concentrated and nutritive extrafloral nectar influences ant foraging patterns.…”

Section: Introductionmentioning

confidence: 99%

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Optimal Defense Theory in an ant–plant mutualism: Extrafloral nectar as an induced defence is maximized in the most valuable plant structures

et al. 2020

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Plants allocate defences in order to decrease costs and maximize benefits against herbivores. The Optimal Defense Theory (ODT) predicts that continuously expressed (i.e. constitutive) defences are expected in structures of high value, whereas defences that are expressed or that increase their expression only after damage or upon risk of damage (i.e. induced defences) are expected in structures of low value. Although there are several studies evaluating ODT predictions, few studies have successfully tested them as a way of measuring ecological investment in extrafloral nectary (EFN)‐mediated ant–plant interactions. Here we compared extrafloral nectar production and ant attractiveness to EFNs located on vegetative versus reproductive plant structures on Qualea multiflora plants subjected to different levels of simulated herbivory. We then addressed the following predictions emerging from the ODT: (a) extrafloral nectar produced in inflorescence EFNs will have higher volumes and calories and will attract more ants than extrafloral nectar produced in leaf EFNs; (b) extrafloral nectar production (volume and calories) and ant attendance will increase after simulated herbivory in leaf EFNs but not in inflorescence EFNs; (c) higher simulated leaf herbivory will induce higher extrafloral nectar production in EFNs on leaves and (d) more attractive extrafloral nectar (higher volume and calories) will attract more ants. Extrafloral nectar volume and calorie content, as well as ant abundance, were higher in EFNs of inflorescences compared to EFNs of leaves both before and after simulated herbivory, consistent with one of our predictions. However, EFNs on both leaves and inflorescences, not on leaves only, were induced by simulated herbivory, a pattern opposite to our prediction. Plants subjected to higher levels of leaf damage produced more and higher calorie extrafloral nectar, but showed similar ant abundance. Finally, more attractive extrafloral nectar attracted more ants. Synthesis. Our results show that extrafloral nectar production before and after simulated herbivory, as well as ant recruitment, varies according to the plant structure on which EFNs are located. Our study is the first to show that ant recruitment via extrafloral nectar follows predictions from Optimal Defense Theory, and that the ant foraging patterns may be shaped by the plant part attacked and the level of damage it receives.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Optimal Defense Theory in an ant–plant mutualism: Extrafloral nectar as an induced defence is maximized in the most valuable plant structures

et al. 2020

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“…Inspired by EFNs, ANs are manipulative tools designed to increase ant activity on trees by dispensing a liquid made of water and sugar to attract ants. Although a few studies have already tested the use of ANs or other food sources to attain agroecological benefits (e.g., [20,21,[97][98][99][100]), none of them have studied ant effectiveness in defending plants, focusing instead on distracting ants from mutualistic sap feeders. Thus, the aim of our study was to evaluate both the functionality of ANs and the impact of different levels of ant activity on arboreal arthropodofauna, plant health and fruit production.…”

Section: Introductionmentioning

confidence: 99%

New Tools for Conservation Biological Control: Testing Ant-Attracting Artificial Nectaries to Employ Ants as Plant Defenders

Schifani

Castracani

Giannetti

et al. 2020

Insects

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Knowledge of the role of ants in many agroecosystems is relatively scarce, and in temperate regions the possibility to exploit ants as biocontrol agents for crop protection is still largely unexplored. Drawing inspiration from mutualistic ant-plant relationships mediated by extrafloral nectaries (EFNs), we tested the use of artificial nectaries (ANs) in order to increase ant activity on pear trees and to evaluate the effects on the arthropods, plant health and fruit production. While EFNs secrete a complex solution mainly composed of sugars and amino acids, ANs were filled with water and sucrose only. The results suggest that ANs can be used as manipulative instruments to increase ant activity over long periods of time. High ant activity was significantly linked to lower incidence of the pathogen fungus Venturia pyrina (pear scab) on pear leaves, and of the presence of Cydia pomonella (codling moth) caterpillars on pear fruit production. These results further encourage exploring underrated possibilities in the development of new tools for conservation biological control (CBC).

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“…We identified eight species of ants harvesting EFN (Table 2 ), but with distinctive communities as a function of the plant genotype. This result suggests that the change in quantity, and possibly the composition and quality of EFN, can influence the ant community associated with G. hirsutum 39 – 41 .…”

Section: Discussionmentioning

confidence: 93%

Ongoing ecological and evolutionary consequences by the presence of transgenes in a wild cotton population

Vázquez-Barrios

Boege

Sosa-Fuentes

et al. 2021

Sci Rep

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After 25 years of genetically modified cotton cultivation in Mexico, gene flow between transgenic individuals and their wild relatives represents an opportunity for analysing the impacts of the presence of novel genes in ecological and evolutionary processes in natural conditions. We show comprehensive empirical evidence on the physiological, metabolic, and ecological effects of transgene introgression in wild cotton, Gossypium hirsutum. We report that the expression of both the cry and cp4-epsps genes in wild cotton under natural conditions altered extrafloral nectar inducibility and thus, its association with different ant species: the dominance of the defensive species Camponotus planatus in Bt plants, the presence of cp4-epsps without defence role of Monomorium ebeninum ants, and of the invasive species Paratrechina longicornis in wild plants without transgenes. Moreover, we found an increase in herbivore damage to cp4-epsps plants. Our results reveal the influence of transgene expression on native ecological interactions. These findings can be useful in the design of risk assessment methodologies for genetically modified organisms and the in situ conservation of G. hirsutum metapopulations.

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Nectar quality affects ant aggressiveness and biotic defense provided to plants

Cited by 30 publications

References 76 publications

Optimal Defense Theory in an ant–plant mutualism: Extrafloral nectar as an induced defence is maximized in the most valuable plant structures

Optimal Defense Theory in an ant–plant mutualism: Extrafloral nectar as an induced defence is maximized in the most valuable plant structures

New Tools for Conservation Biological Control: Testing Ant-Attracting Artificial Nectaries to Employ Ants as Plant Defenders

Ongoing ecological and evolutionary consequences by the presence of transgenes in a wild cotton population

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