Biotic interactions drive ecosystem responses to exotic plant invaders

Lauren P. Waller; Warwick J. Allen; L. M. Condron; B. I. P. Barratt; Filipe M. França; J. E. Hunt; N. Koele; Kate H. Orwin; G. S. Steel; Jason M. Tylianakis; S. A. Wakelin; Ian A. Dickie

doi:10.1126/science.aba2225

Biotic interactions drive ecosystem responses to exotic plant invaders

Lauren P. Waller, Warwick J. Allen, L. M. Condron, B. I. P. Barratt, Filipe M. França, J. E. Hunt, N. Koele, Kate H. Orwin, G. S. Steel, Jason M. Tylianakis, S. A. Wakelin, Ian A. Dickie

Research output: Contribution to journal › Article (Academic Journal) › peer-review

80 Citations (Scopus)

Abstract

Ecosystem process rates typically increase after plant invasion, but the extent to which this is driven by (i) changes in productivity, (ii) exotic species’ traits, or (iii) novel (non-coevolved) biotic interactions has never been quantified. We created communities varying in exotic plant dominance, plant traits, soil biota, and invertebrate herbivores and measured indicators of carbon cycling. Interactions with soil biota and herbivores were the strongest drivers of exotic plant effects, particularly on measures of soil carbon turnover. Moreover, plant traits related to growth and nutrient acquisition explained differences in the ways that exotic plants interacted with novel biota compared with natives. We conclude that novel biological interactions with exotic species are a more important driver of ecosystem transformation than was previously recognized.

Original language	English
Journal	Science
DOIs	https://doi.org/10.1126/science.aba2225
Publication status	Published - 29 May 2020

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@article{76b98c52fadb438891cf561e09299941,

title = "Biotic interactions drive ecosystem responses to exotic plant invaders",

abstract = "Ecosystem process rates typically increase after plant invasion, but the extent to which this is driven by (i) changes in productivity, (ii) exotic species{\textquoteright} traits, or (iii) novel (non-coevolved) biotic interactions has never been quantified. We created communities varying in exotic plant dominance, plant traits, soil biota, and invertebrate herbivores and measured indicators of carbon cycling. Interactions with soil biota and herbivores were the strongest drivers of exotic plant effects, particularly on measures of soil carbon turnover. Moreover, plant traits related to growth and nutrient acquisition explained differences in the ways that exotic plants interacted with novel biota compared with natives. We conclude that novel biological interactions with exotic species are a more important driver of ecosystem transformation than was previously recognized.",

author = "Waller, \{Lauren P.\} and Allen, \{Warwick J.\} and Condron, \{L. M.\} and Barratt, \{B. I. P.\} and Fran{\c c}a, \{Filipe M.\} and Hunt, \{J. E.\} and N. Koele and Orwin, \{Kate H.\} and Steel, \{G. S.\} and Tylianakis, \{Jason M.\} and Wakelin, \{S. A.\} and Dickie, \{Ian A.\}",

year = "2020",

month = may,

day = "29",

doi = "10.1126/science.aba2225",

language = "English",

journal = "Science",

issn = "0036-8075",

publisher = "American Association for the Advancement of Science",

}

TY - JOUR

T1 - Biotic interactions drive ecosystem responses to exotic plant invaders

AU - Waller, Lauren P.

AU - Allen, Warwick J.

AU - Condron, L. M.

AU - Barratt, B. I. P.

AU - França, Filipe M.

AU - Hunt, J. E.

AU - Koele, N.

AU - Orwin, Kate H.

AU - Steel, G. S.

AU - Tylianakis, Jason M.

AU - Wakelin, S. A.

AU - Dickie, Ian A.

PY - 2020/5/29

Y1 - 2020/5/29

N2 - Ecosystem process rates typically increase after plant invasion, but the extent to which this is driven by (i) changes in productivity, (ii) exotic species’ traits, or (iii) novel (non-coevolved) biotic interactions has never been quantified. We created communities varying in exotic plant dominance, plant traits, soil biota, and invertebrate herbivores and measured indicators of carbon cycling. Interactions with soil biota and herbivores were the strongest drivers of exotic plant effects, particularly on measures of soil carbon turnover. Moreover, plant traits related to growth and nutrient acquisition explained differences in the ways that exotic plants interacted with novel biota compared with natives. We conclude that novel biological interactions with exotic species are a more important driver of ecosystem transformation than was previously recognized.

AB - Ecosystem process rates typically increase after plant invasion, but the extent to which this is driven by (i) changes in productivity, (ii) exotic species’ traits, or (iii) novel (non-coevolved) biotic interactions has never been quantified. We created communities varying in exotic plant dominance, plant traits, soil biota, and invertebrate herbivores and measured indicators of carbon cycling. Interactions with soil biota and herbivores were the strongest drivers of exotic plant effects, particularly on measures of soil carbon turnover. Moreover, plant traits related to growth and nutrient acquisition explained differences in the ways that exotic plants interacted with novel biota compared with natives. We conclude that novel biological interactions with exotic species are a more important driver of ecosystem transformation than was previously recognized.

UR - https://www.research.lancs.ac.uk/portal/en/publications/biotic-interactions-drive-ecosystem-responses-to-exotic-plant-invaders(72700966-a598-4a24-a032-5306d2b1b315).html

U2 - 10.1126/science.aba2225

DO - 10.1126/science.aba2225

M3 - Article (Academic Journal)

C2 - 32467385

SN - 0036-8075

JO - Science

JF - Science

ER -

Biotic interactions drive ecosystem responses to exotic plant invaders

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