Drought Tolerance Traits in Neotropical Trees Correlate with the Composition of Phyllosphere Fungal Communities

Marine C. Cambon; Dinïa Cartry; Emilie Chancerel; Camille Ziegler; Sebastien Levionnois; Sabrina Coste; Clément Stahl; Sylvain Delzon; Marc Buée; Benoit Burban; Jocelyne Cazal; Tania Fort; Jean-Yves Goret; Patrick Heuret; Patrick Léger; Elianne Louisanna; Yves Ritter; Damien Bonal; Mélanie Roy; Heidy Schimann; Corinne Vacher

doi:10.1094/PBIOMES-04-22-0023-R

Drought Tolerance Traits in Neotropical Trees Correlate with the Composition of Phyllosphere Fungal Communities

Marine C. Cambon, Dinïa Cartry, Emilie Chancerel, Camille Ziegler, Sebastien Levionnois, Sabrina Coste, Clément Stahl, Sylvain Delzon, Marc Buée, Benoit Burban, Jocelyne Cazal, Tania Fort, Jean-Yves Goret, Patrick Heuret, Patrick Léger, Elianne Louisanna, Yves Ritter, Damien Bonal, Mélanie Roy, Heidy SchimannCorinne Vacher^*

^*Corresponding author for this work

Biosciences

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Abstract

Plant-associated microorganisms have been shown to aid plants in coping with drought. However, the underlying mechanisms are poorly understood and there is uncertainty regarding which microbial taxa and functions are mostly involved. We explored these issues in Neotropical rainforests and identified foliar microorganisms that may play a role in drought tolerance of trees. Our objectives were to (i) test the relationship between drought tolerance traits in Neotropical trees and the diversity and composition of their foliar fungal and bacterial communities and (ii) identify leaf microbial taxa positively or negatively associated with drought tolerance traits. Our results showed that the composition of leaf fungal communities but not bacterial communities was related to drought tolerance. We identified 27 fungal amplicon sequence variants whose relative abundance covaried with drought tolerance traits. Most variants were assigned to fungal clades often described as plant pathogens and increased in abundance with drought susceptibility. This greater relative abundance of leaf pathogens in the most drought-susceptible trees might increase their vulnerability to climate change. Moreover, we identified the Strelitziana and Ochroconis fungal genera as potential candidates for future culture-dependent studies aimed at understanding and improving drought tolerance in Neotropical forests.

Original language	English
Pages (from-to)	244-258
Number of pages	15
Journal	Phytobiomes Journal
Volume	7
Issue number	2
Early online date	1 Jun 2022
DOIs	https://doi.org/10.1094/PBIOMES-04-22-0023-R
Publication status	Published - Sept 2023

Bibliographical note

Funding:
This study was supported by funding from the Conseil Régional Aquitaine (Athene project number 2016-1R20301-00007218) for lab equipment for C. Vacher and S. Delzon, the Agence Nationale de la Recherche (ANR) (NGB project ANR‐17‐CE32‐0011) for M. C. Cambon's post-doctoral grant, LABEX CEBA (DROUGHT project ANR-10-LABX-25-01), LABEX ARBRE (ANR-11-LABX-0002-01), LABEX COTE (Micromic project ANR-10-LABX-45) for molecular biology reagents for C. Vacher, and the Université de Bordeaux for T. Fort's Ph.D. grant.

Keywords

abiotic stressors
bacterial communities
droughttolerance
fungal communities
microbiota
phyllosphere

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CambonM2023DroughtFinal published version, 1.52 MBLicence: Creative Commons: Attribution-NonCommercial-NoDerivs (CC BY-NC-ND)

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Cambon, M. C., Cartry, D., Chancerel, E., Ziegler, C., Levionnois, S., Coste, S., Stahl, C., Delzon, S., Buée, M., Burban, B., Cazal, J., Fort, T., Goret, J.-Y., Heuret, P., Léger, P., Louisanna, E., Ritter, Y., Bonal, D., Roy, M., ... Vacher, C. (2023). Drought Tolerance Traits in Neotropical Trees Correlate with the Composition of Phyllosphere Fungal Communities. Phytobiomes Journal, 7(2), 244-258. https://doi.org/10.1094/PBIOMES-04-22-0023-R

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title = "Drought Tolerance Traits in Neotropical Trees Correlate with the Composition of Phyllosphere Fungal Communities",

abstract = "Plant-associated microorganisms have been shown to aid plants in coping with drought. However, the underlying mechanisms are poorly understood and there is uncertainty regarding which microbial taxa and functions are mostly involved. We explored these issues in Neotropical rainforests and identified foliar microorganisms that may play a role in drought tolerance of trees. Our objectives were to (i) test the relationship between drought tolerance traits in Neotropical trees and the diversity and composition of their foliar fungal and bacterial communities and (ii) identify leaf microbial taxa positively or negatively associated with drought tolerance traits. Our results showed that the composition of leaf fungal communities but not bacterial communities was related to drought tolerance. We identified 27 fungal amplicon sequence variants whose relative abundance covaried with drought tolerance traits. Most variants were assigned to fungal clades often described as plant pathogens and increased in abundance with drought susceptibility. This greater relative abundance of leaf pathogens in the most drought-susceptible trees might increase their vulnerability to climate change. Moreover, we identified the Strelitziana and Ochroconis fungal genera as potential candidates for future culture-dependent studies aimed at understanding and improving drought tolerance in Neotropical forests.",

keywords = "abiotic stressors, bacterial communities, droughttolerance, fungal communities, microbiota, phyllosphere",

author = "Cambon, {Marine C.} and Din{\"i}a Cartry and Emilie Chancerel and Camille Ziegler and Sebastien Levionnois and Sabrina Coste and Cl{\'e}ment Stahl and Sylvain Delzon and Marc Bu{\'e}e and Benoit Burban and Jocelyne Cazal and Tania Fort and Jean-Yves Goret and Patrick Heuret and Patrick L{\'e}ger and Elianne Louisanna and Yves Ritter and Damien Bonal and M{\'e}lanie Roy and Heidy Schimann and Corinne Vacher",

note = "Funding: This study was supported by funding from the Conseil R{\'e}gional Aquitaine (Athene project number 2016-1R20301-00007218) for lab equipment for C. Vacher and S. Delzon, the Agence Nationale de la Recherche (ANR) (NGB project ANR‐17‐CE32‐0011) for M. C. Cambon's post-doctoral grant, LABEX CEBA (DROUGHT project ANR-10-LABX-25-01), LABEX ARBRE (ANR-11-LABX-0002-01), LABEX COTE (Micromic project ANR-10-LABX-45) for molecular biology reagents for C. Vacher, and the Universit{\'e} de Bordeaux for T. Fort's Ph.D. grant.",

year = "2023",

month = sep,

doi = "10.1094/PBIOMES-04-22-0023-R",

language = "English",

volume = "7",

pages = "244--258",

journal = "Phytobiomes Journal",

number = "2",

}

Cambon, MC, Cartry, D, Chancerel, E, Ziegler, C, Levionnois, S, Coste, S, Stahl, C, Delzon, S, Buée, M, Burban, B, Cazal, J, Fort, T, Goret, J-Y, Heuret, P, Léger, P, Louisanna, E, Ritter, Y, Bonal, D, Roy, M, Schimann, H & Vacher, C 2023, 'Drought Tolerance Traits in Neotropical Trees Correlate with the Composition of Phyllosphere Fungal Communities', Phytobiomes Journal, vol. 7, no. 2, pp. 244-258. https://doi.org/10.1094/PBIOMES-04-22-0023-R

TY - JOUR

T1 - Drought Tolerance Traits in Neotropical Trees Correlate with the Composition of Phyllosphere Fungal Communities

AU - Cambon, Marine C.

AU - Cartry, Dinïa

AU - Chancerel, Emilie

AU - Ziegler, Camille

AU - Levionnois, Sebastien

AU - Coste, Sabrina

AU - Stahl, Clément

AU - Delzon, Sylvain

AU - Buée, Marc

AU - Burban, Benoit

AU - Cazal, Jocelyne

AU - Fort, Tania

AU - Goret, Jean-Yves

AU - Heuret, Patrick

AU - Léger, Patrick

AU - Louisanna, Elianne

AU - Ritter, Yves

AU - Bonal, Damien

AU - Roy, Mélanie

AU - Schimann, Heidy

AU - Vacher, Corinne

N1 - Funding: This study was supported by funding from the Conseil Régional Aquitaine (Athene project number 2016-1R20301-00007218) for lab equipment for C. Vacher and S. Delzon, the Agence Nationale de la Recherche (ANR) (NGB project ANR‐17‐CE32‐0011) for M. C. Cambon's post-doctoral grant, LABEX CEBA (DROUGHT project ANR-10-LABX-25-01), LABEX ARBRE (ANR-11-LABX-0002-01), LABEX COTE (Micromic project ANR-10-LABX-45) for molecular biology reagents for C. Vacher, and the Université de Bordeaux for T. Fort's Ph.D. grant.

PY - 2023/9

Y1 - 2023/9

N2 - Plant-associated microorganisms have been shown to aid plants in coping with drought. However, the underlying mechanisms are poorly understood and there is uncertainty regarding which microbial taxa and functions are mostly involved. We explored these issues in Neotropical rainforests and identified foliar microorganisms that may play a role in drought tolerance of trees. Our objectives were to (i) test the relationship between drought tolerance traits in Neotropical trees and the diversity and composition of their foliar fungal and bacterial communities and (ii) identify leaf microbial taxa positively or negatively associated with drought tolerance traits. Our results showed that the composition of leaf fungal communities but not bacterial communities was related to drought tolerance. We identified 27 fungal amplicon sequence variants whose relative abundance covaried with drought tolerance traits. Most variants were assigned to fungal clades often described as plant pathogens and increased in abundance with drought susceptibility. This greater relative abundance of leaf pathogens in the most drought-susceptible trees might increase their vulnerability to climate change. Moreover, we identified the Strelitziana and Ochroconis fungal genera as potential candidates for future culture-dependent studies aimed at understanding and improving drought tolerance in Neotropical forests.

AB - Plant-associated microorganisms have been shown to aid plants in coping with drought. However, the underlying mechanisms are poorly understood and there is uncertainty regarding which microbial taxa and functions are mostly involved. We explored these issues in Neotropical rainforests and identified foliar microorganisms that may play a role in drought tolerance of trees. Our objectives were to (i) test the relationship between drought tolerance traits in Neotropical trees and the diversity and composition of their foliar fungal and bacterial communities and (ii) identify leaf microbial taxa positively or negatively associated with drought tolerance traits. Our results showed that the composition of leaf fungal communities but not bacterial communities was related to drought tolerance. We identified 27 fungal amplicon sequence variants whose relative abundance covaried with drought tolerance traits. Most variants were assigned to fungal clades often described as plant pathogens and increased in abundance with drought susceptibility. This greater relative abundance of leaf pathogens in the most drought-susceptible trees might increase their vulnerability to climate change. Moreover, we identified the Strelitziana and Ochroconis fungal genera as potential candidates for future culture-dependent studies aimed at understanding and improving drought tolerance in Neotropical forests.

KW - abiotic stressors

KW - bacterial communities

KW - droughttolerance

KW - fungal communities

KW - microbiota

KW - phyllosphere

U2 - 10.1094/PBIOMES-04-22-0023-R

DO - 10.1094/PBIOMES-04-22-0023-R

M3 - Article

VL - 7

SP - 244

EP - 258

JO - Phytobiomes Journal

JF - Phytobiomes Journal

IS - 2

ER -

Drought Tolerance Traits in Neotropical Trees Correlate with the Composition of Phyllosphere Fungal Communities

Abstract

Bibliographical note

Keywords

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