RT Journal Article
SR Electronic
T1 Spatial photosynthesis modelling sets guidelines to constructing a viable single-cell cytoplasm-to-stroma C<sub>4</sub> cycle
JF bioRxiv
FD Cold Spring Harbor Laboratory
SP 274845
DO 10.1101/274845
A1 Ivan Jurić
A1 Julian M. Hibberd
A1 Mike Blatt
A1 Nigel J. Burroughs
YR 2018
UL http://biorxiv.org/content/early/2018/03/02/274845.abstract
AB It has been proposed that introducing C4 photosynthesis into C3 crops would increase yield. The simplest scheme in- volves concentrating carbon originating from the cytosol in the chloroplast stroma of mesophyll cells without altering leaf or cell anatomy. Photosynthetic efficiency would then strongly depend on the chloroplast envelope permeability to CO2. We examine the performance of this C4 cycle with a spatial model of carbon assimilation in C3 mesophyll cell geometry, conducting a thorough exploration of parameter space relevant to C4 photosynthesis. For envelope perme- abilities below 300 µm/s C4 photosynthesis has a higher quantum efficiency than C3. However, even when envelope permeability is above this threshold, the C4 pathway can provide a substantial boost to carbon assimilation with only a moderate decrease in efficiency. Depending on the available light-harvesting capacity of plastids, C4 photosynthesis could boost carbon assimilation anywhere from 20% to 100%. Gains are even more prominent under CO2 deprivation, and can be achieved in conjunction with lower investment in plastids if chloroplast surface coverage is also altered. A C4 pathway operating within individual mesophyll cells of C3 plants could hence lead to higher growth rates and better drought resistance in dry, high-sunlight climates.