Physiological trait networks enhance understanding of crop growth and water use in contrasting environments

Sean M. Gleason; Dave M. Barnard; Timothy R. Green; Scott Mackay; Diane R. Wang; Elizabeth A. Ainsworth; Jon Altenhofen; Timothy J. Brodribb; Hervé Cochard; Louise H. Comas; Mark Cooper; Danielle Creek; Kendall C. DeJonge; Sylvain Delzon; Felix B. Fritschi; Graeme Hammer; Cameron Hunter; Danica Lombardozzi; Carlos D. Messina; Troy Ocheltree; Bo Maxwell Stevens; Jared J. Stewart; Vincent Vadez; Joshua Wenz; Ian J. Wright; Kevin Yemoto; Huihui Zhang

doi:10.1111/pce.14382

Physiological trait networks enhance understanding of crop growth and water use in contrasting environments

Sean M. Gleason, Dave M. Barnard, Timothy R. Green, Scott Mackay, Diane R. Wang, Elizabeth A. Ainsworth, Jon Altenhofen, Timothy J. Brodribb, Hervé Cochard, Louise H. Comas, Mark Cooper, Danielle Creek, Kendall C. DeJonge, Sylvain Delzon, Felix B. Fritschi, Graeme Hammer, Cameron Hunter, Danica Lombardozzi, Carlos D. Messina, Troy OcheltreeBo Maxwell Stevens, Jared J. Stewart, Vincent Vadez, Joshua Wenz, Ian J. Wright, Kevin Yemoto, Huihui Zhang

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

Abstract

Plant function arises from a complex network of structural and physiological traits. Explicit representation of these traits, as well as their connections with other biophysical processes, is required to advance our understanding of plant-soil-climate interactions. We used the Terrestrial Regional Ecosystem Exchange Simulator (TREES) to evaluate physiological trait networks in maize. Net primary productivity (NPP) and grain yield were simulated across five contrasting climate scenarios. Simulations achieving high NPP and grain yield in high precipitation environments featured trait networks conferring high water use strategies: deep roots, high stomatal conductance at low water potential (“risky” stomatal regulation), high xylem hydraulic conductivity and high maximal leaf area index. In contrast, high NPP and grain yield was achieved in dry environments with low late-season precipitation via water conserving trait networks: deep roots, high embolism resistance and low stomatal conductance at low leaf water potential (“conservative” stomatal regulation). We suggest that our approach, which allows for the simultaneous evaluation of physiological traits, soil characteristics and their interactions (i.e., networks), has potential to improve our understanding of crop performance in different environments. In contrast, evaluating single traits in isolation of other coordinated traits does not appear to be an effective strategy for predicting plant performance.

Original language	English (US)
Pages (from-to)	2554-2572
Number of pages	19
Journal	Plant Cell and Environment
Volume	45
Issue number	9
DOIs	https://doi.org/10.1111/pce.14382
State	Published - Sep 2022
Externally published	Yes

Keywords

breeding
crop improvement
hydraulic traits
maize
photosynthesis
plant growth
process simulation
stomata
water potential
xylem

ASJC Scopus subject areas

Physiology
Plant Science

Online availability

10.1111/pce.14382

Library availability

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Gleason, S. M., Barnard, D. M., Green, T. R., Mackay, S., Wang, D. R., Ainsworth, E. A., Altenhofen, J., Brodribb, T. J., Cochard, H., Comas, L. H., Cooper, M., Creek, D., DeJonge, K. C., Delzon, S., Fritschi, F. B., Hammer, G., Hunter, C., Lombardozzi, D., Messina, C. D., ... Zhang, H. (2022). Physiological trait networks enhance understanding of crop growth and water use in contrasting environments. Plant Cell and Environment, 45(9), 2554-2572. https://doi.org/10.1111/pce.14382

Gleason, SM, Barnard, DM, Green, TR, Mackay, S, Wang, DR, Ainsworth, EA, Altenhofen, J, Brodribb, TJ, Cochard, H, Comas, LH, Cooper, M, Creek, D, DeJonge, KC, Delzon, S, Fritschi, FB, Hammer, G, Hunter, C, Lombardozzi, D, Messina, CD, Ocheltree, T, Stevens, BM, Stewart, JJ, Vadez, V, Wenz, J, Wright, IJ, Yemoto, K & Zhang, H 2022, 'Physiological trait networks enhance understanding of crop growth and water use in contrasting environments', Plant Cell and Environment, vol. 45, no. 9, pp. 2554-2572. https://doi.org/10.1111/pce.14382

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title = "Physiological trait networks enhance understanding of crop growth and water use in contrasting environments",

abstract = "Plant function arises from a complex network of structural and physiological traits. Explicit representation of these traits, as well as their connections with other biophysical processes, is required to advance our understanding of plant-soil-climate interactions. We used the Terrestrial Regional Ecosystem Exchange Simulator (TREES) to evaluate physiological trait networks in maize. Net primary productivity (NPP) and grain yield were simulated across five contrasting climate scenarios. Simulations achieving high NPP and grain yield in high precipitation environments featured trait networks conferring high water use strategies: deep roots, high stomatal conductance at low water potential (“risky” stomatal regulation), high xylem hydraulic conductivity and high maximal leaf area index. In contrast, high NPP and grain yield was achieved in dry environments with low late-season precipitation via water conserving trait networks: deep roots, high embolism resistance and low stomatal conductance at low leaf water potential (“conservative” stomatal regulation). We suggest that our approach, which allows for the simultaneous evaluation of physiological traits, soil characteristics and their interactions (i.e., networks), has potential to improve our understanding of crop performance in different environments. In contrast, evaluating single traits in isolation of other coordinated traits does not appear to be an effective strategy for predicting plant performance.",

keywords = "breeding, crop improvement, hydraulic traits, maize, photosynthesis, plant growth, process simulation, stomata, water potential, xylem",

author = "Gleason, {Sean M.} and Barnard, {Dave M.} and Green, {Timothy R.} and Scott Mackay and Wang, {Diane R.} and Ainsworth, {Elizabeth A.} and Jon Altenhofen and Brodribb, {Timothy J.} and Herv{\'e} Cochard and Comas, {Louise H.} and Mark Cooper and Danielle Creek and DeJonge, {Kendall C.} and Sylvain Delzon and Fritschi, {Felix B.} and Graeme Hammer and Cameron Hunter and Danica Lombardozzi and Messina, {Carlos D.} and Troy Ocheltree and Stevens, {Bo Maxwell} and Stewart, {Jared J.} and Vincent Vadez and Joshua Wenz and Wright, {Ian J.} and Kevin Yemoto and Huihui Zhang",

note = "The contributions of Mark Cooper, Graeme Hammer, Timothy Brodribb and Ian Wright were supported by the Australian Research Council Centre of Excellence for Plant Success in Nature and Agriculture (CE200100015). Herv\u00E9 Cochard was supported by the ANR projects 16\u2010IDEX\u20100001 and 18\u2010CE20\u20100005. Jared Stewart and Felix Fritschi were supported by National Science Foundation grants IOS\u20101907338 and IOS\u20101444448, respectively.",

year = "2022",

month = sep,

doi = "10.1111/pce.14382",

language = "English (US)",

volume = "45",

pages = "2554--2572",

journal = "Plant Cell and Environment",

issn = "0140-7791",

publisher = "John Wiley & Sons, Ltd.",

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T1 - Physiological trait networks enhance understanding of crop growth and water use in contrasting environments

AU - Gleason, Sean M.

AU - Barnard, Dave M.

AU - Green, Timothy R.

AU - Mackay, Scott

AU - Wang, Diane R.

AU - Ainsworth, Elizabeth A.

AU - Altenhofen, Jon

AU - Brodribb, Timothy J.

AU - Cochard, Hervé

AU - Comas, Louise H.

AU - Cooper, Mark

AU - Creek, Danielle

AU - DeJonge, Kendall C.

AU - Delzon, Sylvain

AU - Fritschi, Felix B.

AU - Hammer, Graeme

AU - Hunter, Cameron

AU - Lombardozzi, Danica

AU - Messina, Carlos D.

AU - Ocheltree, Troy

AU - Stevens, Bo Maxwell

AU - Stewart, Jared J.

AU - Vadez, Vincent

AU - Wenz, Joshua

AU - Wright, Ian J.

AU - Yemoto, Kevin

AU - Zhang, Huihui

N1 - The contributions of Mark Cooper, Graeme Hammer, Timothy Brodribb and Ian Wright were supported by the Australian Research Council Centre of Excellence for Plant Success in Nature and Agriculture (CE200100015). Herv\u00E9 Cochard was supported by the ANR projects 16\u2010IDEX\u20100001 and 18\u2010CE20\u20100005. Jared Stewart and Felix Fritschi were supported by National Science Foundation grants IOS\u20101907338 and IOS\u20101444448, respectively.

PY - 2022/9

Y1 - 2022/9

N2 - Plant function arises from a complex network of structural and physiological traits. Explicit representation of these traits, as well as their connections with other biophysical processes, is required to advance our understanding of plant-soil-climate interactions. We used the Terrestrial Regional Ecosystem Exchange Simulator (TREES) to evaluate physiological trait networks in maize. Net primary productivity (NPP) and grain yield were simulated across five contrasting climate scenarios. Simulations achieving high NPP and grain yield in high precipitation environments featured trait networks conferring high water use strategies: deep roots, high stomatal conductance at low water potential (“risky” stomatal regulation), high xylem hydraulic conductivity and high maximal leaf area index. In contrast, high NPP and grain yield was achieved in dry environments with low late-season precipitation via water conserving trait networks: deep roots, high embolism resistance and low stomatal conductance at low leaf water potential (“conservative” stomatal regulation). We suggest that our approach, which allows for the simultaneous evaluation of physiological traits, soil characteristics and their interactions (i.e., networks), has potential to improve our understanding of crop performance in different environments. In contrast, evaluating single traits in isolation of other coordinated traits does not appear to be an effective strategy for predicting plant performance.

AB - Plant function arises from a complex network of structural and physiological traits. Explicit representation of these traits, as well as their connections with other biophysical processes, is required to advance our understanding of plant-soil-climate interactions. We used the Terrestrial Regional Ecosystem Exchange Simulator (TREES) to evaluate physiological trait networks in maize. Net primary productivity (NPP) and grain yield were simulated across five contrasting climate scenarios. Simulations achieving high NPP and grain yield in high precipitation environments featured trait networks conferring high water use strategies: deep roots, high stomatal conductance at low water potential (“risky” stomatal regulation), high xylem hydraulic conductivity and high maximal leaf area index. In contrast, high NPP and grain yield was achieved in dry environments with low late-season precipitation via water conserving trait networks: deep roots, high embolism resistance and low stomatal conductance at low leaf water potential (“conservative” stomatal regulation). We suggest that our approach, which allows for the simultaneous evaluation of physiological traits, soil characteristics and their interactions (i.e., networks), has potential to improve our understanding of crop performance in different environments. In contrast, evaluating single traits in isolation of other coordinated traits does not appear to be an effective strategy for predicting plant performance.

KW - breeding

KW - crop improvement

KW - hydraulic traits

KW - maize

KW - photosynthesis

KW - plant growth

KW - process simulation

KW - stomata

KW - water potential

KW - xylem

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JO - Plant Cell and Environment

JF - Plant Cell and Environment

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ER -

Physiological trait networks enhance understanding of crop growth and water use in contrasting environments

Abstract

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