# Low abundance of phytophagous nematodes under invasive exotic Pinus elliottii – enemy release and plant–soil feedbacks

**Authors:** Lynda S. C. Guerrero, Erika Buscardo, Mario M. Inomoto, Laszlo Nagy

PMC · DOI: 10.1111/nph.70852 · The New Phytologist · 2025-12-28

## TL;DR

Invasive pine trees reduce nematode enemies in soil, helping them spread more easily in new ecosystems.

## Contribution

Shows invasive Pinus elliottii reduces phytophagous nematodes, supporting enemy release and altering soil feedbacks.

## Key findings

- Nematode load on pine is lower than on native species, supporting the enemy release hypothesis.
- Pine invasion depletes phytophagous nematodes and reduces overall nematode richness over time.
- Pine modifies soil organism composition, influencing plant-soil feedbacks in neotropical ecosystems.

## Abstract

According to the enemy release hypothesis (ERH), the fitness of exotic plants and their capacity to become invasive in their area of introduction may partly be attributable to the loss of their natural enemies. Invasive species may also benefit from modifying soil attributes and thereby creating a positive soil–plant feedback.We assessed the relationship between time since the establishment of the invasive Pinus elliottii and enemy release in a montane pine–nematode‐specific context within the Atlantic Forest domain, by comparing soil nematode communities/functional diversity along a virtual chronosequence of invasion.Our findings confirmed the premises of the ERH and suggest that invasion may be facilitated by a lesser nematode load on pine compared to that on native species. The impact of P. elliottii on nematode communities over time was mainly driven by changes in the trophic structure with a major depletion of phytophagous species and overall nematode richness.The findings suggest that P. elliottii after experiencing an initial reduction in natural enemy pressure in its exotic range, further changes the composition of soil organisms in its rhizosphere. This has implications for plant–soil feedbacks which, in turn, affect the dynamics of pine invasion in neotropical montane ecosystems.

According to the enemy release hypothesis (ERH), the fitness of exotic plants and their capacity to become invasive in their area of introduction may partly be attributable to the loss of their natural enemies. Invasive species may also benefit from modifying soil attributes and thereby creating a positive soil–plant feedback.

We assessed the relationship between time since the establishment of the invasive Pinus elliottii and enemy release in a montane pine–nematode‐specific context within the Atlantic Forest domain, by comparing soil nematode communities/functional diversity along a virtual chronosequence of invasion.

Our findings confirmed the premises of the ERH and suggest that invasion may be facilitated by a lesser nematode load on pine compared to that on native species. The impact of P. elliottii on nematode communities over time was mainly driven by changes in the trophic structure with a major depletion of phytophagous species and overall nematode richness.

The findings suggest that P. elliottii after experiencing an initial reduction in natural enemy pressure in its exotic range, further changes the composition of soil organisms in its rhizosphere. This has implications for plant–soil feedbacks which, in turn, affect the dynamics of pine invasion in neotropical montane ecosystems.

## Linked entities

- **Species:** Pinus elliottii (taxon 42064)

## Full-text entities

- **Chemicals:** enemy (-)
- **Species:** Pinus elliottii (American pitch pine, species) [taxon 42064]

## Full text

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## Figures

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## References

105 references — full list in the complete paper: https://tomesphere.com/paper/PMC12917447/full.md

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Source: https://tomesphere.com/paper/PMC12917447