Regulatory Coordination of Photophysical, Photochemical, and Biochemical Reactions in the Photosynthesis of Land Plants

Lianhong Gu; Bernard Grodzinski; Jimei Han; Telesphore Marie; Yong Jiang Zhang; Yang C Song; Ying Sun

doi:10.1002/pld3.70080

Regulatory Coordination of Photophysical, Photochemical, and Biochemical Reactions in the Photosynthesis of Land Plants

Lianhong Gu
, Bernard Grodzinski
, Jimei Han
, Telesphore Marie
, Yong Jiang Zhang
, Yang C Song
, Ying Sun

Ecosystem Processes

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

2 Scopus citations

Abstract

Balance among the sequential photophysical, photochemical, and biochemical reactions of photosynthesis is needed for converting fleeting energy in light to stable energy in chemical bonds. Any imbalance acts as either a bottleneck for limiting photosynthetic efficiency or an agent for inducing structural and functional damage to photosynthetic apparatus. Not only must each reaction be carefully regulated, but regulatory processes must also be coordinated across the reactions. However, regulations of different stages of photosynthesis have rarely been studied jointly. Non-photochemical quenching (NPQ) and stomatal conductance (g_s) are key regulators of photophysical and biochemical reactions, respectively. Existing evidence suggests that the redox state of plastoquinone regulates g_s and that the photochemical reactions are partially regulated by the ultrastructural dynamics of thylakoids induced by osmotic water fluxes in chloroplasts of land plants. To examine how these regulations are coordinated and feedback to each other, we simultaneously measured NPQ and g_s and inferred the redox state of plastoquinone and the light-induced thylakoid swelling/shrinking on numerous C₃ and C₄ species. For all species measured, NPQ and g_s covary with the redox states of the electron transport chain, particularly plastoquinone, and increase as thylakoid swelling is inferred. NPQ has the maximal sensitivity at the light intensity at which thylakoid is inferred to be fully swollen. Our findings suggest that plant energy and water use strategies are intimately linked by evolution, and studying the regulations of different photosynthetic stages as a whole can lead to new insights of the functioning of photosynthetic machinery in dynamic environments.

Original language	English
Article number	e70080
Journal	Plant Direct
Volume	9
Issue number	5
DOIs	https://doi.org/10.1002/pld3.70080
State	Published - May 2025

Funding

This work was supported by the US Department of Energy (DE‐AC05‐00OR22725), US NSF (1926488), USDA‐NIFA Hatch Fund (1014740), Cornell Initiative for Digital Agriculture Research Innovation Fund, Ontario Ministry of Agriculture, Food and Rural Affairs (UofG2016‐2732), and Food and Rural Affairs for Two OMAFRA‐Alliance‐T1 (UG‐T1‐2021‐100932). Funding: The authors benefited from discussions on photosynthetic electron transport with Drs. Joe Berry, Albert Porcar‐Castell, Christine Chang, and Xinyou Yin. Drs. Berry and Yin also contributed data to this study. Two expert reviewers provided critical and yet motivational comments and suggestions, which guided the revision of the manuscript. Dr. Jeff Wood and Ms. Jena Gu commented on the manuscript. We are grateful to the generosity of these colleagues. This research is supported by the US Department of Energy (DOE), Office of Science, Biological and Environmental Research Program. ORNL is managed by UT‐Battelle LLC for DOE under contract DE‐AC05‐00OR22725. Y.S. and J.H. acknowledge support from NSF Macrosystem Biology (Award 1926488), USDA‐NIFA Hatch Fund (1014740), and the Cornell Initiative for Digital Agriculture Research Innovation Fund. B.G. and T.M. acknowledge the support of the Ontario Ministry of Agriculture, Food and Rural Affairs for two OMAFRA‐Alliance‐T1 Awards (UofG2016‐2732 and UG‐T1‐2021‐100932). Funding: This work was supported by the US Department of Energy (DE-AC05-00OR22725), US NSF (1926488), USDA-NIFA Hatch Fund (1014740), Cornell Initiative for Digital Agriculture Research Innovation Fund, Ontario Ministry of Agriculture, Food and Rural Affairs (UofG2016-2732), and Food and Rural Affairs for Two OMAFRA-Alliance-T1 (UG-T1-2021-100932). The authors benefited from discussions on photosynthetic electron transport with Drs. Joe Berry, Albert Porcar-Castell, Christine Chang, and Xinyou Yin. Drs. Berry and Yin also contributed data to this study. Two expert reviewers provided critical and yet motivational comments and suggestions, which guided the revision of the manuscript. Dr. Jeff Wood and Ms. Jena Gu commented on the manuscript. We are grateful to the generosity of these colleagues. This research is supported by the US Department of Energy (DOE), Office of Science, Biological and Environmental Research Program. ORNL is managed by UT-Battelle LLC for DOE under contract DE-AC05-00OR22725. Y.S. and J.H. acknowledge support from NSF Macrosystem Biology (Award 1926488), USDA-NIFA Hatch Fund (1014740), and the Cornell Initiative for Digital Agriculture Research Innovation Fund. B.G. and T.M. acknowledge the support of the Ontario Ministry of Agriculture, Food and Rural Affairs for two OMAFRA-Alliance-T1 Awards (UofG2016-2732 and UG-T1-2021-100932).

Keywords

electron transport regulation
granal thylakoid
photosynthesis modeling
plant energy use strategies
plant water use strategies

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10.1002/pld3.70080

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title = "Regulatory Coordination of Photophysical, Photochemical, and Biochemical Reactions in the Photosynthesis of Land Plants",

abstract = "Balance among the sequential photophysical, photochemical, and biochemical reactions of photosynthesis is needed for converting fleeting energy in light to stable energy in chemical bonds. Any imbalance acts as either a bottleneck for limiting photosynthetic efficiency or an agent for inducing structural and functional damage to photosynthetic apparatus. Not only must each reaction be carefully regulated, but regulatory processes must also be coordinated across the reactions. However, regulations of different stages of photosynthesis have rarely been studied jointly. Non-photochemical quenching (NPQ) and stomatal conductance (gs) are key regulators of photophysical and biochemical reactions, respectively. Existing evidence suggests that the redox state of plastoquinone regulates gs and that the photochemical reactions are partially regulated by the ultrastructural dynamics of thylakoids induced by osmotic water fluxes in chloroplasts of land plants. To examine how these regulations are coordinated and feedback to each other, we simultaneously measured NPQ and gs and inferred the redox state of plastoquinone and the light-induced thylakoid swelling/shrinking on numerous C3 and C4 species. For all species measured, NPQ and gs covary with the redox states of the electron transport chain, particularly plastoquinone, and increase as thylakoid swelling is inferred. NPQ has the maximal sensitivity at the light intensity at which thylakoid is inferred to be fully swollen. Our findings suggest that plant energy and water use strategies are intimately linked by evolution, and studying the regulations of different photosynthetic stages as a whole can lead to new insights of the functioning of photosynthetic machinery in dynamic environments.",

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author = "Lianhong Gu and Bernard Grodzinski and Jimei Han and Telesphore Marie and Zhang, \{Yong Jiang\} and Yang C Song and Ying Sun",

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Regulatory Coordination of Photophysical, Photochemical, and Biochemical Reactions in the Photosynthesis of Land Plants

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