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Chlorophyll fluorescence-based high-throughput phenotyping facilitates the genetic dissection of photosynthetic heat tolerance in African (Oryza glaberrima) and Asian (Oryza sativa) rice

Robson, Jordan K; Ferguson, John N; McAusland, Lorna; Atkinson, Jonathan A; Tranchant-Dubreuil, Christine; Cubry, Phillipe; Sabot, François; Wells, Darren M; Price, Adam H; Wilson, Zoe A; Murchie, Erik H

Chlorophyll fluorescence-based high-throughput phenotyping facilitates the genetic dissection of photosynthetic heat tolerance in African (Oryza glaberrima) and Asian (Oryza sativa) rice Thumbnail


Authors

Jordan K Robson

John N Ferguson

Christine Tranchant-Dubreuil

Phillipe Cubry

François Sabot

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

Adam H Price

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ZOE WILSON ZOE.WILSON@NOTTINGHAM.AC.UK
Pro Vice Chancellor Faculty of Science

Dr ERIK MURCHIE erik.murchie@nottingham.ac.uk
Professor of Applied Plant Physiology



Abstract

Rising temperatures and extreme heat events threaten rice production. Half of the global population relies on rice for basic nutrition, and therefore developing heat-tolerant rice is essential. During vegetative development, reduced photosynthetic rates can limit growth and the capacity to store soluble carbohydrates. The photosystem II (PSII) complex is a particularly heat-labile component of photosynthesis. We have developed a high-throughput chlorophyll fluorescence-based screen for photosynthetic heat tolerance capable of screening hundreds of plants daily. Through measuring the response of maximum PSII efficiency to increasing temperature, this platform generates data for modelling the PSII–temperature relationship in large populations in a small amount of time. Coefficients from these models (photosynthetic heat tolerance traits) demonstrated high heritabilities across African (Oryza glaberrima) and Asian (Oryza sativa, Bengal Assam Aus Panel) rice diversity sets, highlighting valuable genetic variation accessible for breeding. Genome-wide association studies were performed across both species for these traits, representing the first documented attempt to characterize the genetic basis of photosynthetic heat tolerance in any species to date. A total of 133 candidate genes were highlighted. These were significantly enriched with genes whose predicted roles suggested influence on PSII activity and the response to stress. We discuss the most promising candidates for improving photosynthetic heat tolerance in rice.

Journal Article Type Article
Acceptance Date Jun 20, 2023
Online Publication Date Jun 22, 2023
Publication Date Sep 13, 2023
Deposit Date Jun 15, 2024
Publicly Available Date Jun 18, 2024
Journal Journal of Experimental Botany
Print ISSN 0022-0957
Electronic ISSN 1460-2431
Publisher Oxford University Press
Peer Reviewed Peer Reviewed
Volume 74
Issue 17
Pages 5181-5197
DOI https://doi.org/10.1093/jxb/erad239
Keywords Plant Science; Physiology
Public URL https://nottingham-repository.worktribe.com/output/22186593
Publisher URL https://academic.oup.com/jxb/article/74/17/5181/7205185

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