Root metaxylem area influences drought tolerance and transpiration in pearl millet in a soil texture dependent manner

Affortit, Pablo; Faye, Awa; Jones, Dylan H.; Benson, Ezenwoko; Sine, Bassirou; Burridge, James; Ndoye, Mame Sokhatil; Barry, Luke; Moukouanga, Daniel; Barnard, Stephanie; Bhosale, Rahul; Pridmore, Tony; Gantet, Pascal; Vadez, Vincent; Cubry, Philippe; Kane, Ndjido; Bennett, Malcolm; Atkinson, Jonathan A.; Laplaze, Laurent; Wells, Darren M.; Grondin, Alexandre

doi:10.1101/2024.11.09.622826

Root metaxylem area influences drought tolerance and transpiration in pearl millet in a soil texture dependent manner

Affortit, Pablo; Faye, Awa; Jones, Dylan H.; Benson, Ezenwoko; Sine, Bassirou; Burridge, James; Ndoye, Mame Sokhatil; Barry, Luke; Moukouanga, Daniel; Barnard, Stephanie; Bhosale, Rahul; Pridmore, Tony; Gantet, Pascal; Vadez, Vincent; Cubry, Philippe; Kane, Ndjido; Bennett, Malcolm; Atkinson, Jonathan A.; Laplaze, Laurent; Wells, Darren M.; Grondin, Alexandre

Authors

Pablo Affortit

Awa Faye

Dylan H. Jones

Ezenwoko Benson

Bassirou Sine

James Burridge

Mame Sokhatil Ndoye

Luke Barry

Daniel Moukouanga

Stephanie Barnard

Dr RAHUL BHOSALE RAHUL.BHOSALE@NOTTINGHAM.AC.UK
Associate Professor

TONY PRIDMORE tony.pridmore@nottingham.ac.uk
Professor of Computer Science

Pascal Gantet

Vincent Vadez

Philippe Cubry

Ndjido Kane

MALCOLM BENNETT malcolm.bennett@nottingham.ac.uk
Professor of Plant Science

JONATHAN ATKINSON JONATHAN.ATKINSON@NOTTINGHAM.AC.UK
Assistant Professor

Laurent Laplaze

DARREN WELLS DARREN.WELLS@NOTTINGHAM.AC.UK
Principal Research Fellow

Alexandre Grondin

Abstract

Pearl millet is a key cereal for food security in drylands but its yield is strongly impacted by drought. We investigated how root anatomical traits contribute to mitigating the effects of vegetative drought stress in pearl millet.

We examined associations between root anatomical traits and agronomical performance in a pearl millet diversity panel under irrigated and vegetative drought stress treatments in field trials. The impact of associated anatomical traits on transpiration was assessed using subpanels grown in different soil within a greenhouse.

In the field, total metaxylem area was positively correlated with grain weight and its maintenance under drought. In the greenhouse, genotypes with larger metaxylem area grown in sandy soil exhibited a consumerist water use strategy under irrigation, which shifted to a conservative strategy under drought. Water savings was mediated by transpiration restriction under high evaporative demand. This mechanism was dependent on soil hydraulics as it was not observed in peat soil with higher hydraulic conductivity upon soil drying.

We propose that water savings under drought, mediated by large metaxylem area and its interaction with soil hydraulics, help mitigate vegetative drought stress. Our findings highlight the role of soil hydraulic properties in shaping plant hydraulics and drought tolerance.

Citation

Affortit, P., Faye, A., Jones, D. H., Benson, E., Sine, B., Burridge, J., Ndoye, M. S., Barry, L., Moukouanga, D., Barnard, S., Bhosale, R., Pridmore, T., Gantet, P., Vadez, V., Cubry, P., Kane, N., Bennett, M., Atkinson, J. A., Laplaze, L., Wells, D. M., & Grondin, A. (2024). Root metaxylem area influences drought tolerance and transpiration in pearl millet in a soil texture dependent manner

Working Paper Type	Preprint
Online Publication Date	Nov 11, 2024
Publication Date	Nov 11, 2024
Deposit Date	Nov 18, 2024
Publicly Available Date	Nov 19, 2024
DOI	https://doi.org/10.1101/2024.11.09.622826
Public URL	https://nottingham-repository.worktribe.com/output/41931857
Publisher URL	https://www.biorxiv.org/content/10.1101/2024.11.09.622826v1