The efficiency of C4 photosynthesis under low light conditions in Zea mays, Miscanthus x giganteus and Flaveria bidentis

ABSTRACT The efficiency of C4 photosynthesis in Zea mays, Miscanthus x giganteus and Flaveria bidentis in response to light was determined using measurements of gas exchange, 13CO2 photosynthetic discrimination, metabolite pools and spectroscopic assays, with models of C4 photosynthesis and leaf 13C...

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Published in:Plant, cell and environment cell and environment, 2013-02, Vol.36 (2), p.365-381
Main Authors: UBIERNA, NEREA, SUN, WEI, KRAMER, DAVID M., COUSINS, ASAPH B.
Format: Article
Language:English
Subjects:
Analysis of Variance
Biological and medical sciences
bundle‐sheath conductance
Carbon - metabolism
Carbon Dioxide - metabolism
carbon isotope discrimination
CO2 leakiness
Crosses, Genetic
Flaveria - physiology
Flaveria - radiation effects
Flaveria bidentis
Fundamental and applied biological sciences. Psychology
Light
light quantity
metabolite pools
Metabolome - radiation effects
Miscanthus
Models, Biological
Oxygen - metabolism
photorespiration
Photosynthesis - radiation effects
Plant Stomata - physiology
Plant Stomata - radiation effects
Poaceae - physiology
Poaceae - radiation effects
Spectrum Analysis
Thermodynamics
Zea mays
Zea mays - physiology
Zea mays - radiation effects
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SUN, WEI
KRAMER, DAVID M.
COUSINS, ASAPH B.
description ABSTRACT The efficiency of C4 photosynthesis in Zea mays, Miscanthus x giganteus and Flaveria bidentis in response to light was determined using measurements of gas exchange, 13CO2 photosynthetic discrimination, metabolite pools and spectroscopic assays, with models of C4 photosynthesis and leaf 13CO2 discrimination. Spectroscopic and metabolite assays suggested constant energy partitioning between the C4 and C3 cycles across photosynthetically active radiation (PAR). Leakiness (φ), modelled using C4 light‐limited photosynthesis equations (φmod), matched values from the isotope method without simplifications (φis) and increased slightly from high to low PAR in all species. However, simplifications of bundle‐sheath [CO2] and respiratory fractionation lead to large overestimations of φ at low PAR with the isotope method. These species used different strategies to maintain similar φ. For example, Z. mays had large rates of the C4 cycle and low bundle‐sheath cells CO2 conductance (gbs). While F. bidentis had larger gbs but lower respiration rates and M. giganteus had less C4 cycle capacity but low gbs, which resulted in similar φ. This demonstrates that low gbs is important for efficient C4 photosynthesis but it is not the only factor determining φ. Additionally, these C4 species are able to optimize photosynthesis and minimize φ over a range of PARs, including low light. We described the response of C4 photosynthetic efficiency to light. Zea mays, Miscanthus x giganteus and Flaveria bidentis used different strategies to optimize photosynthesis and minimize leakiness (ϕ) over a range of PARs, including low light. There was a small increase in ϕ from high (0.13) to low (0.27) PAR. Previous reports of very large ϕ (0.6 to 0.9) under limiting PARs might have originated from invalid simplifications of theoretical models of Δ.
doi_str_mv 10.1111/j.1365-3040.2012.02579.x
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Spectroscopic and metabolite assays suggested constant energy partitioning between the C4 and C3 cycles across photosynthetically active radiation (PAR). Leakiness (φ), modelled using C4 light‐limited photosynthesis equations (φmod), matched values from the isotope method without simplifications (φis) and increased slightly from high to low PAR in all species. However, simplifications of bundle‐sheath [CO2] and respiratory fractionation lead to large overestimations of φ at low PAR with the isotope method. These species used different strategies to maintain similar φ. For example, Z. mays had large rates of the C4 cycle and low bundle‐sheath cells CO2 conductance (gbs). While F. bidentis had larger gbs but lower respiration rates and M. giganteus had less C4 cycle capacity but low gbs, which resulted in similar φ. This demonstrates that low gbs is important for efficient C4 photosynthesis but it is not the only factor determining φ. Additionally, these C4 species are able to optimize photosynthesis and minimize φ over a range of PARs, including low light. We described the response of C4 photosynthetic efficiency to light. Zea mays, Miscanthus x giganteus and Flaveria bidentis used different strategies to optimize photosynthesis and minimize leakiness (ϕ) over a range of PARs, including low light. There was a small increase in ϕ from high (0.13) to low (0.27) PAR. 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Spectroscopic and metabolite assays suggested constant energy partitioning between the C4 and C3 cycles across photosynthetically active radiation (PAR). Leakiness (φ), modelled using C4 light‐limited photosynthesis equations (φmod), matched values from the isotope method without simplifications (φis) and increased slightly from high to low PAR in all species. However, simplifications of bundle‐sheath [CO2] and respiratory fractionation lead to large overestimations of φ at low PAR with the isotope method. These species used different strategies to maintain similar φ. For example, Z. mays had large rates of the C4 cycle and low bundle‐sheath cells CO2 conductance (gbs). While F. bidentis had larger gbs but lower respiration rates and M. giganteus had less C4 cycle capacity but low gbs, which resulted in similar φ. This demonstrates that low gbs is important for efficient C4 photosynthesis but it is not the only factor determining φ. 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Spectroscopic and metabolite assays suggested constant energy partitioning between the C4 and C3 cycles across photosynthetically active radiation (PAR). Leakiness (φ), modelled using C4 light‐limited photosynthesis equations (φmod), matched values from the isotope method without simplifications (φis) and increased slightly from high to low PAR in all species. However, simplifications of bundle‐sheath [CO2] and respiratory fractionation lead to large overestimations of φ at low PAR with the isotope method. These species used different strategies to maintain similar φ. For example, Z. mays had large rates of the C4 cycle and low bundle‐sheath cells CO2 conductance (gbs). While F. bidentis had larger gbs but lower respiration rates and M. giganteus had less C4 cycle capacity but low gbs, which resulted in similar φ. This demonstrates that low gbs is important for efficient C4 photosynthesis but it is not the only factor determining φ. Additionally, these C4 species are able to optimize photosynthesis and minimize φ over a range of PARs, including low light. We described the response of C4 photosynthetic efficiency to light. Zea mays, Miscanthus x giganteus and Flaveria bidentis used different strategies to optimize photosynthesis and minimize leakiness (ϕ) over a range of PARs, including low light. There was a small increase in ϕ from high (0.13) to low (0.27) PAR. Previous reports of very large ϕ (0.6 to 0.9) under limiting PARs might have originated from invalid simplifications of theoretical models of Δ.</abstract><cop>Oxford, UK</cop><pub>Blackwell Publishing Ltd</pub><pmid>22812384</pmid><doi>10.1111/j.1365-3040.2012.02579.x</doi><tpages>17</tpages></addata></record>
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source Wiley-Blackwell Read & Publish Collection
subjects Analysis of Variance
Biological and medical sciences
bundle‐sheath conductance
Carbon - metabolism
Carbon Dioxide - metabolism
carbon isotope discrimination
CO2 leakiness
Crosses, Genetic
Flaveria - physiology
Flaveria - radiation effects
Flaveria bidentis
Fundamental and applied biological sciences. Psychology
Light
light quantity
metabolite pools
Metabolome - radiation effects
Miscanthus
Models, Biological
Oxygen - metabolism
photorespiration
Photosynthesis - radiation effects
Plant Stomata - physiology
Plant Stomata - radiation effects
Poaceae - physiology
Poaceae - radiation effects
Spectrum Analysis
Thermodynamics
Zea mays
Zea mays - physiology
Zea mays - radiation effects
title The efficiency of C4 photosynthesis under low light conditions in Zea mays, Miscanthus x giganteus and Flaveria bidentis
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