Longer epidermal cells underlie a quantitative source of variation in wheat flag leaf size

Camila M. Zanella; Marilena Rotondo; Charlie McCormick-Barnes; Greg Mellers; Beatrice Corsi; Simon Berry; Giulia Ciccone; Rob Day; Michele Faralli; Alexander Galle; Keith A. Gardner; John Jacobs; Eric S. Ober; Ana Sánchez del Rio; Jeroen Van Rie; Tracy Lawson; James Cockram

doi:10.1111/nph.18676

Longer epidermal cells underlie a quantitative source of variation in wheat flag leaf size

Camila M. Zanella
, Marilena Rotondo
, Charlie McCormick-Barnes
, Greg Mellers
, Beatrice Corsi
, Simon Berry
, Giulia Ciccone
, Rob Day
, Michele Faralli
, Alexander Galle
, Keith A. Gardner
, John Jacobs
, Eric S. Ober
, Ana Sánchez del Rio
, Jeroen Van Rie
, Tracy Lawson
, James Cockram

Research output: Contribution to journal › Article › peer-review

Abstract

The wheat flag leaf is the main contributor of photosynthetic assimilates to developing grains. Understanding how canopy architecture strategies affect source strength and yield will aid improved crop design. We used an eight-founder population to investigate the genetic architecture of flag leaf area, length, width and angle in European wheat. For the strongest genetic locus identified, we subsequently created a near-isogenic line (NIL) pair for more detailed investigation across seven test environments. Genetic control of traits investigated was highly polygenic, with colocalisation of replicated quantitative trait loci (QTL) for one or more traits identifying 24 loci. For QTL QFll.niab-5A.1 (FLL5A), development of a NIL pair found the FLL5A+ allele commonly conferred a c. 7% increase in flag and second leaf length and a more erect leaf angle, resulting in higher flag and/or second leaf area. Increased FLL5A-mediated flag leaf length was associated with: (1) longer pavement cells and (2) larger stomata at lower density, with a trend for decreased maximum stomatal conductance (G_smax) per unit leaf area. For FLL5A, cell size rather than number predominantly determined leaf length. The observed trade-offs between leaf size and stomatal morphology highlight the need for future studies to consider these traits at the whole-leaf level.

Original language	English (US)
Pages (from-to)	1558-1573
Number of pages	16
Journal	New Phytologist
Volume	237
Issue number	5
Early online date	Dec 28 2022
DOIs	https://doi.org/10.1111/nph.18676
State	Published - Mar 2023
Externally published	Yes

Keywords

flag leaf morphology
haplotype analysis
maximum stomatal conductance (G)
multifounder advanced generation intercross population
quantitative trait variation
wheat (Triticum aestivum L.)

ASJC Scopus subject areas

Physiology
Plant Science

Online availability

10.1111/nph.18676License: CC BY

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Zanella, C. M., Rotondo, M., McCormick-Barnes, C., Mellers, G., Corsi, B., Berry, S., Ciccone, G., Day, R., Faralli, M., Galle, A., Gardner, K. A., Jacobs, J., Ober, E. S., Sánchez del Rio, A., Van Rie, J., Lawson, T., & Cockram, J. (2023). Longer epidermal cells underlie a quantitative source of variation in wheat flag leaf size. New Phytologist, 237(5), 1558-1573. https://doi.org/10.1111/nph.18676

Zanella, CM, Rotondo, M, McCormick-Barnes, C, Mellers, G, Corsi, B, Berry, S, Ciccone, G, Day, R, Faralli, M, Galle, A, Gardner, KA, Jacobs, J, Ober, ES, Sánchez del Rio, A, Van Rie, J, Lawson, T & Cockram, J 2023, 'Longer epidermal cells underlie a quantitative source of variation in wheat flag leaf size', New Phytologist, vol. 237, no. 5, pp. 1558-1573. https://doi.org/10.1111/nph.18676

@article{8efa58bf73fa4e1f9ce0c1fbabcc6c6f,

title = "Longer epidermal cells underlie a quantitative source of variation in wheat flag leaf size",

abstract = "The wheat flag leaf is the main contributor of photosynthetic assimilates to developing grains. Understanding how canopy architecture strategies affect source strength and yield will aid improved crop design. We used an eight-founder population to investigate the genetic architecture of flag leaf area, length, width and angle in European wheat. For the strongest genetic locus identified, we subsequently created a near-isogenic line (NIL) pair for more detailed investigation across seven test environments. Genetic control of traits investigated was highly polygenic, with colocalisation of replicated quantitative trait loci (QTL) for one or more traits identifying 24 loci. For QTL QFll.niab-5A.1 (FLL5A), development of a NIL pair found the FLL5A+ allele commonly conferred a c. 7\% increase in flag and second leaf length and a more erect leaf angle, resulting in higher flag and/or second leaf area. Increased FLL5A-mediated flag leaf length was associated with: (1) longer pavement cells and (2) larger stomata at lower density, with a trend for decreased maximum stomatal conductance (Gsmax) per unit leaf area. For FLL5A, cell size rather than number predominantly determined leaf length. The observed trade-offs between leaf size and stomatal morphology highlight the need for future studies to consider these traits at the whole-leaf level.",

keywords = "flag leaf morphology, haplotype analysis, maximum stomatal conductance (G), multifounder advanced generation intercross population, quantitative trait variation, wheat (Triticum aestivum L.)",

author = "Zanella, \{Camila M.\} and Marilena Rotondo and Charlie McCormick-Barnes and Greg Mellers and Beatrice Corsi and Simon Berry and Giulia Ciccone and Rob Day and Michele Faralli and Alexander Galle and Gardner, \{Keith A.\} and John Jacobs and Ober, \{Eric S.\} and \{S{\'a}nchez del Rio\}, Ana and \{Van Rie\}, Jeroen and Tracy Lawson and James Cockram",

note = "The 2018 and 2019 season field trials were supported by the Biotechnology and Biological Sciences Research Council (BBSRC) grant BB/N01698X/1 awarded to JC, as was a proportion of time for CMZ, ASR, GM, ESO and JC. MF and TL were supported by BBSRC grant BB/N016831/1 awarded to TL. MR and GC were supported by undergraduate ERASMUS Mobility grants awarded to the University of Messina. CM-B undertook research during a work placement at NIAB as part of an undergraduate degree at the University of Manchester. Scanning electron microscopy work was undertaken by Karin Mueller as a subcontract to the University of Cambridge, UK, using the facilities of the Cambridge Advanced Imaging Centre (CAIC). We thank NIAB colleague Sue Sporle for assistance with glasshouse NIL phenotyping, the NIAB Trials team for the sowing and agronomic care of NIAB trials and Jacob Lage at KWS UK Ltd for the KWS\_2020 trial, in caring memory of Greg Mellers, from all of his colleagues. The 2018 and 2019 season field trials were supported by the Biotechnology and Biological Sciences Research Council (BBSRC) grant BB/N01698X/1 awarded to JC, as was a proportion of time for CMZ, ASR, GM, ESO and JC. MF and TL were supported by BBSRC grant BB/N016831/1 awarded to TL. MR and GC were supported by undergraduate ERASMUS Mobility grants awarded to the University of Messina. CM‐B undertook research during a work placement at NIAB as part of an undergraduate degree at the University of Manchester. Scanning electron microscopy work was undertaken by Karin Mueller as a subcontract to the University of Cambridge, UK, using the facilities of the Cambridge Advanced Imaging Centre (CAIC). We thank NIAB colleague Sue Sporle for assistance with glasshouse NIL phenotyping, the NIAB Trials team for the sowing and agronomic care of NIAB trials and Jacob Lage at KWS UK Ltd for the KWS\_2020 trial, in caring memory of Greg Mellers, from all of his colleagues.",

year = "2023",

month = mar,

doi = "10.1111/nph.18676",

language = "English (US)",

volume = "237",

pages = "1558--1573",

journal = "New Phytologist",

issn = "0028-646X",

publisher = "Wiley-Blackwell",

number = "5",

}

TY - JOUR

T1 - Longer epidermal cells underlie a quantitative source of variation in wheat flag leaf size

AU - Zanella, Camila M.

AU - Rotondo, Marilena

AU - McCormick-Barnes, Charlie

AU - Mellers, Greg

AU - Corsi, Beatrice

AU - Berry, Simon

AU - Ciccone, Giulia

AU - Day, Rob

AU - Faralli, Michele

AU - Galle, Alexander

AU - Gardner, Keith A.

AU - Jacobs, John

AU - Ober, Eric S.

AU - Sánchez del Rio, Ana

AU - Van Rie, Jeroen

AU - Lawson, Tracy

AU - Cockram, James

N1 - The 2018 and 2019 season field trials were supported by the Biotechnology and Biological Sciences Research Council (BBSRC) grant BB/N01698X/1 awarded to JC, as was a proportion of time for CMZ, ASR, GM, ESO and JC. MF and TL were supported by BBSRC grant BB/N016831/1 awarded to TL. MR and GC were supported by undergraduate ERASMUS Mobility grants awarded to the University of Messina. CM-B undertook research during a work placement at NIAB as part of an undergraduate degree at the University of Manchester. Scanning electron microscopy work was undertaken by Karin Mueller as a subcontract to the University of Cambridge, UK, using the facilities of the Cambridge Advanced Imaging Centre (CAIC). We thank NIAB colleague Sue Sporle for assistance with glasshouse NIL phenotyping, the NIAB Trials team for the sowing and agronomic care of NIAB trials and Jacob Lage at KWS UK Ltd for the KWS_2020 trial, in caring memory of Greg Mellers, from all of his colleagues. The 2018 and 2019 season field trials were supported by the Biotechnology and Biological Sciences Research Council (BBSRC) grant BB/N01698X/1 awarded to JC, as was a proportion of time for CMZ, ASR, GM, ESO and JC. MF and TL were supported by BBSRC grant BB/N016831/1 awarded to TL. MR and GC were supported by undergraduate ERASMUS Mobility grants awarded to the University of Messina. CM‐B undertook research during a work placement at NIAB as part of an undergraduate degree at the University of Manchester. Scanning electron microscopy work was undertaken by Karin Mueller as a subcontract to the University of Cambridge, UK, using the facilities of the Cambridge Advanced Imaging Centre (CAIC). We thank NIAB colleague Sue Sporle for assistance with glasshouse NIL phenotyping, the NIAB Trials team for the sowing and agronomic care of NIAB trials and Jacob Lage at KWS UK Ltd for the KWS_2020 trial, in caring memory of Greg Mellers, from all of his colleagues.

PY - 2023/3

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N2 - The wheat flag leaf is the main contributor of photosynthetic assimilates to developing grains. Understanding how canopy architecture strategies affect source strength and yield will aid improved crop design. We used an eight-founder population to investigate the genetic architecture of flag leaf area, length, width and angle in European wheat. For the strongest genetic locus identified, we subsequently created a near-isogenic line (NIL) pair for more detailed investigation across seven test environments. Genetic control of traits investigated was highly polygenic, with colocalisation of replicated quantitative trait loci (QTL) for one or more traits identifying 24 loci. For QTL QFll.niab-5A.1 (FLL5A), development of a NIL pair found the FLL5A+ allele commonly conferred a c. 7% increase in flag and second leaf length and a more erect leaf angle, resulting in higher flag and/or second leaf area. Increased FLL5A-mediated flag leaf length was associated with: (1) longer pavement cells and (2) larger stomata at lower density, with a trend for decreased maximum stomatal conductance (Gsmax) per unit leaf area. For FLL5A, cell size rather than number predominantly determined leaf length. The observed trade-offs between leaf size and stomatal morphology highlight the need for future studies to consider these traits at the whole-leaf level.

AB - The wheat flag leaf is the main contributor of photosynthetic assimilates to developing grains. Understanding how canopy architecture strategies affect source strength and yield will aid improved crop design. We used an eight-founder population to investigate the genetic architecture of flag leaf area, length, width and angle in European wheat. For the strongest genetic locus identified, we subsequently created a near-isogenic line (NIL) pair for more detailed investigation across seven test environments. Genetic control of traits investigated was highly polygenic, with colocalisation of replicated quantitative trait loci (QTL) for one or more traits identifying 24 loci. For QTL QFll.niab-5A.1 (FLL5A), development of a NIL pair found the FLL5A+ allele commonly conferred a c. 7% increase in flag and second leaf length and a more erect leaf angle, resulting in higher flag and/or second leaf area. Increased FLL5A-mediated flag leaf length was associated with: (1) longer pavement cells and (2) larger stomata at lower density, with a trend for decreased maximum stomatal conductance (Gsmax) per unit leaf area. For FLL5A, cell size rather than number predominantly determined leaf length. The observed trade-offs between leaf size and stomatal morphology highlight the need for future studies to consider these traits at the whole-leaf level.

KW - flag leaf morphology

KW - haplotype analysis

KW - maximum stomatal conductance (G)

KW - multifounder advanced generation intercross population

KW - quantitative trait variation

KW - wheat (Triticum aestivum L.)

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UR - https://www.scopus.com/pages/publications/85145312918#tab=citedBy

U2 - 10.1111/nph.18676

DO - 10.1111/nph.18676

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SN - 0028-646X

VL - 237

SP - 1558

EP - 1573

JO - New Phytologist

JF - New Phytologist

IS - 5

ER -

Longer epidermal cells underlie a quantitative source of variation in wheat flag leaf size

Abstract

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