Microbial communities in semi-mature oak trees are resilient to drought, nutrient limitation, and pathogen challenge

Usman Hussain; Marine C. Cambon; Bridget Crampton; Sunitha Subramaniam; Anparasy Kajamuhan; Alejandra Ordoñez; Jim Downie; Jasen Finch; Manfred Beckmann; Nathan Brown; Amy Elison; Carrie Brady; Elena Vanguelova; Sandra Denman; James E. McDonald

doi:10.1016/j.chom.2026.01.009

Microbial communities in semi-mature oak trees are resilient to drought, nutrient limitation, and pathogen challenge

Usman Hussain
, Marine C. Cambon
, Bridget Crampton
, Sunitha Subramaniam
, Anparasy Kajamuhan
, Alejandra Ordoñez
, Jim Downie
, Jasen Finch
, Manfred Beckmann
, Nathan Brown
, Amy Elison
, Carrie Brady
, Elena Vanguelova
, Sandra Denman
, James E. McDonald^*

^*Awdur cyfatebol y gwaith hwn

Bangor University
University of the West of England
University of Birmingham
Forest Research

Allbwn ymchwil: Cyfraniad at gyfnodolyn › Erthygl › adolygiad gan gymheiriaid

2 Dyfyniadau (Scopus)

1 Wedi eu Llwytho i Lawr (Pure)

Crynodeb

Global forest biomes face increasing stressors and disease outbreaks that threaten ecosystem health. Tree-associated microbiota are vital for tree resilience, yet their responses to biotic and abiotic stressors in mature trees remain poorly understood. Using an experimental woodland plot of 144 Quercus petraea trees subjected to drought (rain exclusion), nutrient stress (ringbarking), and biotic treatments (bacterial pathogens and beetle larvae) to simulate acute oak decline, we tracked microbial communities in leaf, stem, and root/rhizosphere tissues across four time points over 2 years. Oak trees hosted distinct microbial communities across tissue types, which remained largely stable under stress. Rain exclusion significantly altered microbiota composition, though these changes explained less than 1% of total variance. Actinobacteriota , linked to drought tolerance, increased in the root/rhizosphere of rain-excluded trees. These findings reveal a surprising resilience of oak-associated microbial communities to environmental and biotic disturbances, highlighting their potential role in forest ecosystem stability.

Iaith wreiddiol	Saesneg
Tudalennau (o-i)	344-358.e5
Nifer y tudalennau	21
Cyfnodolyn	Cell Host and Microbe
Cyfrol	34
Rhif cyhoeddi	2
Dynodwyr Gwrthrych Digidol (DOIs)	https://doi.org/10.1016/j.chom.2026.01.009
Statws	Cyhoeddwyd - 11 Chwef 2026

Mynediad at Ddogfen

10.1016/j.chom.2026.01.009Trwydded: CC BY

ArticleFersiwn derfynol wedi’i chyhoeddi, 10.7 MBTrwydded: CC BY
Supplementary informationData, 27.3 MBTrwydded: CC BY

Cysylltiad parhaol

Dolen barhaus

Ffeiliau eraill a chysylltiadau

Dolen i’r cyhoeddiad yn Scopus

Bacteria: Advancement of Control and Knowledge to Save Threatened Oak and Protect them for Future Generations
Draper, J. (Arweinydd y Prosiect)
Biotechnology and Biological Sciences Research Council
01 Medi 2020 → 31 Awst 2023
Prosiect: Ymchwil a ariannwyd yn allanol

Dyfynnu hyn

Hussain, U., Cambon, M. C., Crampton, B., Subramaniam, S., Kajamuhan, A., Ordoñez, A., Downie, J., Finch, J., Beckmann, M., Brown, N., Elison, A., Brady, C., Vanguelova, E., Denman, S., & McDonald, J. E. (2026). Microbial communities in semi-mature oak trees are resilient to drought, nutrient limitation, and pathogen challenge. Cell Host and Microbe, 34(2), 344-358.e5. https://doi.org/10.1016/j.chom.2026.01.009

@article{8c8c600e3c934536b3dcaa4d583c584a,

title = "Microbial communities in semi-mature oak trees are resilient to drought, nutrient limitation, and pathogen challenge",

abstract = "Global forest biomes face increasing stressors and disease outbreaks that threaten ecosystem health. Tree-associated microbiota are vital for tree resilience, yet their responses to biotic and abiotic stressors in mature trees remain poorly understood. Using an experimental woodland plot of 144 Quercus petraea trees subjected to drought (rain exclusion), nutrient stress (ringbarking), and biotic treatments (bacterial pathogens and beetle larvae) to simulate acute oak decline, we tracked microbial communities in leaf, stem, and root/rhizosphere tissues across four time points over 2 years. Oak trees hosted distinct microbial communities across tissue types, which remained largely stable under stress. Rain exclusion significantly altered microbiota composition, though these changes explained less than 1\% of total variance. Actinobacteriota , linked to drought tolerance, increased in the root/rhizosphere of rain-excluded trees. These findings reveal a surprising resilience of oak-associated microbial communities to environmental and biotic disturbances, highlighting their potential role in forest ecosystem stability.",

keywords = "Actinobacteriota, acute oak decline, drought, forest health, microbiome, microbiome dynamics, oak, Quercus petraea, tree-associated microbiota",

author = "Usman Hussain and Cambon, \{Marine C.\} and Bridget Crampton and Sunitha Subramaniam and Anparasy Kajamuhan and Alejandra Ordo{\~n}ez and Jim Downie and Jasen Finch and Manfred Beckmann and Nathan Brown and Amy Elison and Carrie Brady and Elena Vanguelova and Sandra Denman and McDonald, \{James E.\}",

year = "2026",

month = feb,

day = "11",

doi = "10.1016/j.chom.2026.01.009",

language = "English",

volume = "34",

pages = "344--358.e5",

journal = "Cell Host and Microbe",

issn = "1931-3128",

publisher = "Elsevier",

number = "2",

}

Hussain, U, Cambon, MC, Crampton, B, Subramaniam, S, Kajamuhan, A, Ordoñez, A, Downie, J, Finch, J, Beckmann, M, Brown, N, Elison, A, Brady, C, Vanguelova, E, Denman, S & McDonald, JE 2026, 'Microbial communities in semi-mature oak trees are resilient to drought, nutrient limitation, and pathogen challenge', Cell Host and Microbe, cyfrol. 34, rhif 2, tt. 344-358.e5. https://doi.org/10.1016/j.chom.2026.01.009

TY - JOUR

T1 - Microbial communities in semi-mature oak trees are resilient to drought, nutrient limitation, and pathogen challenge

AU - Hussain, Usman

AU - Cambon, Marine C.

AU - Crampton, Bridget

AU - Subramaniam, Sunitha

AU - Kajamuhan, Anparasy

AU - Ordoñez, Alejandra

AU - Downie, Jim

AU - Finch, Jasen

AU - Beckmann, Manfred

AU - Brown, Nathan

AU - Elison, Amy

AU - Brady, Carrie

AU - Vanguelova, Elena

AU - Denman, Sandra

AU - McDonald, James E.

PY - 2026/2/11

Y1 - 2026/2/11

N2 - Global forest biomes face increasing stressors and disease outbreaks that threaten ecosystem health. Tree-associated microbiota are vital for tree resilience, yet their responses to biotic and abiotic stressors in mature trees remain poorly understood. Using an experimental woodland plot of 144 Quercus petraea trees subjected to drought (rain exclusion), nutrient stress (ringbarking), and biotic treatments (bacterial pathogens and beetle larvae) to simulate acute oak decline, we tracked microbial communities in leaf, stem, and root/rhizosphere tissues across four time points over 2 years. Oak trees hosted distinct microbial communities across tissue types, which remained largely stable under stress. Rain exclusion significantly altered microbiota composition, though these changes explained less than 1% of total variance. Actinobacteriota , linked to drought tolerance, increased in the root/rhizosphere of rain-excluded trees. These findings reveal a surprising resilience of oak-associated microbial communities to environmental and biotic disturbances, highlighting their potential role in forest ecosystem stability.

AB - Global forest biomes face increasing stressors and disease outbreaks that threaten ecosystem health. Tree-associated microbiota are vital for tree resilience, yet their responses to biotic and abiotic stressors in mature trees remain poorly understood. Using an experimental woodland plot of 144 Quercus petraea trees subjected to drought (rain exclusion), nutrient stress (ringbarking), and biotic treatments (bacterial pathogens and beetle larvae) to simulate acute oak decline, we tracked microbial communities in leaf, stem, and root/rhizosphere tissues across four time points over 2 years. Oak trees hosted distinct microbial communities across tissue types, which remained largely stable under stress. Rain exclusion significantly altered microbiota composition, though these changes explained less than 1% of total variance. Actinobacteriota , linked to drought tolerance, increased in the root/rhizosphere of rain-excluded trees. These findings reveal a surprising resilience of oak-associated microbial communities to environmental and biotic disturbances, highlighting their potential role in forest ecosystem stability.

KW - Actinobacteriota

KW - acute oak decline

KW - drought

KW - forest health

KW - microbiome

KW - microbiome dynamics

KW - oak

KW - Quercus petraea

KW - tree-associated microbiota

UR - https://www.scopus.com/pages/publications/105029358469

U2 - 10.1016/j.chom.2026.01.009

DO - 10.1016/j.chom.2026.01.009

M3 - Article

C2 - 41679285

AN - SCOPUS:105029358469

SN - 1931-3128

VL - 34

SP - 344-358.e5

JO - Cell Host and Microbe

JF - Cell Host and Microbe

IS - 2

ER -

Microbial communities in semi-mature oak trees are resilient to drought, nutrient limitation, and pathogen challenge

Crynodeb

Mynediad at Ddogfen

Cysylltiad parhaol

Ffeiliau eraill a chysylltiadau

Ôl bys

Prosiectau

Bacteria: Advancement of Control and Knowledge to Save Threatened Oak and Protect them for Future Generations

Dyfynnu hyn