# Multifunctional Roles of Extrafloral Nectaries in Shaping Plant–Insect Interactions

**Authors:** Eduardo Soares Calixto, Renan Fernandes Moura, Denise Lange, Estevao Alves Silva, Helena Maura Torezan-Silingardi, Kleber Del-Claro

PMC · DOI: 10.3390/plants15040595 · 2026-02-13

## TL;DR

Extrafloral nectaries help plants interact with ants in complex ways, balancing protection and distraction depending on context.

## Contribution

The paper introduces a nuanced framework for understanding EFNs as multifunctional structures with context-dependent roles.

## Key findings

- EFNs can serve both protective and distracting roles depending on their location and ant behavior.
- The ecological functions of EFNs shift in space and time based on plant traits and interacting species.
- A continuum-based perspective is proposed to better understand EFN evolution and plant-insect interactions.

## Abstract

Understanding the net outcomes of ecological interactions by examining the costs and benefits of organism associations is central to ecology. The mutualistic relationship between ants and plants mediated by extrafloral nectaries (EFNs) has long been viewed as protective, with ants defending plants from herbivores in exchange for nectar. However, alternative hypotheses, like the ant-distraction and flower-distraction, highlight the multifunctionality of EFNs. The flower-distraction hypothesis proposes that EFNs evolved to divert ants from flowers, reducing ant impact on pollination. Recent studies reveal that EFN interactions with ants are highly context-dependent, shaped by factors such as EFN location and ant behavior. Although EFNs often occur on vegetative tissues, they are sometimes located near flowers, raising the possibility that they serve both protective and distracting roles. This duality challenges the notion that EFNs can be categorized exclusively by location or function. Instead, their ecological roles likely shift in space and time, depending on plant growth form, pollination system, and interacting species. We propose moving beyond a dichotomous framework toward a nuanced perspective that embraces a potential continuum of functionalities. Considering multiple ecological and evolutionary factors will enhance understanding of EFN evolution, plant–animal interactions, and ecosystem dynamics.

## Full-text entities

- **Diseases:** injury to (MESH:D014947)
- **Chemicals:** lipids (MESH:D008055), EFN (-), amino acids (MESH:D000596), calcium oxalate (MESH:D002129), volatile organic compounds (MESH:D055549), sugar (MESH:D000073893)
- **Species:** Trochilidae (hummingbirds, family) [taxon 9242], Trigona sp. (species) [taxon 2907844], Neoponera villosa (species) [taxon 2037986], Camponotus renggeri (species) [taxon 605932], Bombus (bumble bees, genus) [taxon 28641], Calystegia macrostegia (species) [taxon 197361], Apis mellifera (bee, species) [taxon 7460], Chiroptera (bats, order) [taxon 9397], Qualea multiflora (species) [taxon 1892850], Formicidae (ants, family) [taxon 36668], Chamaecrista desvauxii (species) [taxon 346939], Heteropterys pteropetala (species) [taxon 1027152], Vespidae (wasps, family) [taxon 7438], Homo sapiens (human, species) [taxon 9606], Xylocopinae (carpenter bees, subfamily) [taxon 78170], Bombus (subgenus) [taxon 144708], Banisteriopsis malifolia (species) [taxon 1561743], Ectatomma tuberculatum (species) [taxon 39300], Palicourea rigida (species) [taxon 96266], Bionia coriacea (species) [taxon 584677], Camponotus crassus (species) [taxon 605092], Araneae (spiders, order) [taxon 6893], Lophocereus schottii (species) [taxon 153875], Ouratea spectabilis (species) [taxon 2072270], Turnera velutina (species) [taxon 329195], Tristerix aphyllus (species) [taxon 378718]

## Figures

2 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12944237/full.md

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Source: https://tomesphere.com/paper/PMC12944237