@article{e85252a0237441fb90a4b3c3e98f0e6c,
title = "Reduction of bundle sheath size boosts cyclic electron flow in C4 Setaria viridis acclimated to low light",
abstract = "When C4 leaves are exposed to low light, the CO2 concentration in the bundle sheath (BS) cells decreases, causing an increase in photorespiration relative to assimilation, and a consequent reduction in biochemical efficiency. These effects can be mitigated by complex acclimation syndromes, which are of primary importance for crop productivity but are not well studied. We unveil an acclimation strategy involving the coordination of electron transport processes. First, we characterize the anatomy, gas exchange and electron transport of C4 Setaria viridis grown under low light. Through a purposely developed biochemical model, we resolve the photon fluxes and reaction rates to explain how the concerted acclimation strategies sustain photosynthetic efficiency. Our results show that a smaller BS in low-light-grown plants limited leakiness (the ratio of CO2 leak rate out of the BS over the rate of supply via C4 acid decarboxylation) but sacrificed light harvesting and ATP production. To counter ATP shortage and maintain high assimilation rates, plants facilitated light penetration through the mesophyll and upregulated cyclic electron flow in the BS. This shade tolerance mechanism, based on the optimization of light reactions, is possibly more efficient than the known mechanisms involving the rearrangement of carbon metabolism, and could potentially lead to innovative strategies for crop improvement.",
keywords = "bundle sheath, C photosynthesis, carbon reactions, gas exchange, Kranz anatomy, light harvesting, light reactions, modelling, NADP-ME",
author = "Chandra Bellasio and Maria Ermakova",
note = "Funding Information: We are deeply grateful to Graham Douglas Farquhar for hospitality and to Suan Chin Wong, Dean Price and Susanne von Caemmerer for equipment. We thank Russell Woodford for coding in r, Balasaheb Vitthal Sonawane for data and discussion, and Riya Kuruvilla and Tegan Norley for technical assistance. We thank Florence Danila, Joanne Lee and the Centre for Advanced Microscopy at the Australian National University for preparing and imaging leaf cross sections. We thank the Australian Plant Phenomics Facility supported under the National Collaborative Research Infrastructure Strategy of the Australian Government. CB was funded by an H2020 Marie Sk{\l}odowska-Curie individual fellowship (DILIPHO, ID 702755). ME was supported by the Australian Research Council Centre of Excellence for Translational Photosynthesis (CE140100015). Funding Information: We are deeply grateful to Graham Douglas Farquhar for hospitality and to Suan Chin Wong, Dean Price and Susanne von Caemmerer for equipment. We thank Russell Woodford for coding in r , Balasaheb Vitthal Sonawane for data and discussion, and Riya Kuruvilla and Tegan Norley for technical assistance. We thank Florence Danila, Joanne Lee and the Centre for Advanced Microscopy at the Australian National University for preparing and imaging leaf cross sections. We thank the Australian Plant Phenomics Facility supported under the National Collaborative Research Infrastructure Strategy of the Australian Government. CB was funded by an H2020 Marie Sk{\l}odowska‐Curie individual fellowship (DILIPHO, ID 702755). ME was supported by the Australian Research Council Centre of Excellence for Translational Photosynthesis (CE140100015). Publisher Copyright: {\textcopyright} 2022 The Authors. The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.",
year = "2022",
month = sep,
doi = "10.1111/tpj.15915",
language = "English",
volume = "111",
pages = "1223--1237",
journal = "The Plant Journal",
issn = "0960-7412",
publisher = "Wiley-Blackwell",
number = "5",
}