Quantifying impacts of enhancing photosynthesis on crop yield (original) (raw)

References

1. Long, S. P., Marshall-Colon, A. & Zhu, X.-G. Meeting the global food demand of the future by engineering crop photosynthesis and yield potential. Cell 161, 56–66 (2015).
   Article CAS Google Scholar
2. Parry, M. A. J. et al. Raising yield potential of wheat. II. Increasing photosynthetic capacity and efficiency. J. Exp. Bot. 62, 453–467 (2011).
   Article CAS Google Scholar
3. Ray, D. K., Mueller, N. D., West, P. C. & Foley, J. A. Yield trends are insufficient to double global crop production by 2050. PLoS ONE 8, e66428 (2013).
   Article CAS Google Scholar
4. von Caemmerer, S. & Evans, J. R. Enhancing C3 photosynthesis. Plant Physiol. 154, 589–592 (2010).
   Article Google Scholar
5. von Caemmerer, S. & Furbank, R. T. Strategies for improving C4 photosynthesis. Curr. Opin. Plant Biol. 31, 125–134 (2016).
   Article Google Scholar
6. Wu, A., Doherty, A., Farquhar, G. D. & Hammer, G. L. Simulating daily field crop canopy photosynthesis: an integrated software package. Funct. Plant Biol. 45, 362–377 (2018).
   Article CAS Google Scholar
7. Sinclair, T. R., Purcell, L. C. & Sneller, C. H. Crop transformation and the challenge to increase yield potential. Trends Plant Sci. 9, 70–75 (2004).
   Article CAS Google Scholar
8. Wu, A., Song, Y., van Oosterom, E. J. & Hammer, G. L. Connecting biochemical photosynthesis models with crop models to support crop improvement. Front. Plant Sci. 7, 1518 (2016).
   PubMed PubMed Central Google Scholar
9. Evans, J. R. Nitrogen and photosynthesis in the flag leaf of wheat (Triticum aestivum L.). Plant Physiol. 72, 297–302 (1983).
   Article CAS Google Scholar
10. van Oosterom, E. J., Borrell, A. K., Chapman, S. C., Broad, I. J. & Hammer, G. L. Functional dynamics of the nitrogen balance of sorghum: I. N demand of vegetative plant parts. Field Crops Res. 115, 19–28 (2010).
    Article Google Scholar
11. van Oosterom, E. J., Chapman, S. C., Borrell, A. K., Broad, I. J. & Hammer, G. L. Functional dynamics of the nitrogen balance of sorghum. II. Grain filling period. Field Crops Res. 115, 29–38 (2010).
    Article Google Scholar
12. Hammer, G. L. et al. Adapting APSIM to model the physiology and genetics of complex adaptive traits in field crops. J. Exp. Bot. 61, 2185–2202 (2010).
    Article CAS Google Scholar
13. Robertson, M. J., Fukai, S., Ludlow, M. M. & Hammer, G. L. Water extraction by grain sorghum in a sub-humid environment. I. Analysis of the water extraction pattern. Field Crops Res. 33, 81–97 (1993).
    Article Google Scholar
14. Hammer, G. L. et al. Can changes in canopy and/or root system architecture explain historical maize yield trends in the U.S. corn belt? Crop Sci. 49, 299–312 (2009).
    Article Google Scholar
15. Farquhar, G. D., von Caemmerer, S. & Berry, J. A. A biochemical model of photosynthetic CO2 assimilation in leaves of C3 species. Planta 149, 78–90 (1980).
    Article CAS Google Scholar
16. von Caemmerer, S. Biochemical Models of Leaf Photosynthesis Vol. 2 (CSIRO Publishing, 2000).
17. Holzworth, D. P. et al. APSIM—evolution towards a new generation of agricultural systems simulation. Environ. Model. Softw. 62, 327–350 (2014).
    Article Google Scholar
18. Brown, H. E. et al. Plant modelling framework: software for building and running crop models on the APSIM platform. Env. Model. Softw. 62, 385–398 (2014).
    Article Google Scholar
19. Evans, J. R. Improving photosynthesis. Plant Physiol. 162, 1780–1793 (2013).
    Article CAS Google Scholar
20. Grant, R. F., Peters, D. B., Larson, E. M. & Huck, M. G. Simulation of canopy photosynthesis in maize and soybean. Agric. For. Meteorol. 48, 75–92 (1989).
    Article Google Scholar
21. Sinclair, T. R. & Muchow, R. C. Radiation use efficiency. Adv. Agron. 65, 215–265 (1999).
    Article Google Scholar
22. Olioso, A., Carlson, T. N. & Brisson, N. Simulation of diurnal transpiration and photosynthesis of a water stressed soybean crop. Agric. For. Meteorol. 81, 41–59 (1996).
    Article Google Scholar
23. Ghannoum, O. C4 photosynthesis and water stress. Ann. Bot. 103, 635–644 (2009).
    Article CAS Google Scholar
24. Ghannoum, O., Evans, J. R. & von Caemmerer, S. in C 4 Photosynthesis and Related CO 2 Concentrating Mechanisms (eds Raghavendra, A. S. & Sage, R. F.) 129–146 (Springer, 2011).
25. Ball, J. T., Woodrow, I. & Berry, J. in Progress in Photosynthesis Research (ed. Biggins, J.) Ch. 48 (Martinus Nijhoff Publishers, 1987).
26. Yin, X. & Struik, P. C. Can increased leaf photosynthesis be converted into higher crop mass production? A simulation study for rice using the crop model GECROS. J. Exp. Bot. 68, 2345–2360 (2017).
    Article CAS Google Scholar
27. Amir, J. & Sinclair, T. R. A model of water limitation on spring wheat growth and yield. Field Crops Res. 28, 59–69 (1991).
    Article Google Scholar
28. von Caemmerer, S. et al. Stomatal conductance does not correlate with photosynthetic capacity in transgenic tobacco with reduced amounts of Rubisco. J. Exp. Bot. 55, 1157–1166 (2004).
    Article Google Scholar
29. Fujita, T., Noguchi, K. & Terashima, I. Apoplastic mesophyll signals induce rapid stomatal responses to CO2 in Commelina communis. New Phytol. 199, 395–406 (2013).
    Article CAS Google Scholar
30. Mott, K. A. & Peak, D. Effects of the mesophyll on stomatal responses in amphistomatous leaves. Plant Cell Environ. 41, 2835–2843 (2018).
    Article CAS Google Scholar
31. McGrath, J. M. & Long, S. P. Can the cyanobacterial carbon-concentrating mechanism increase photosynthesis in crop species? A theoretical analysis. Plant Physiol. 164, 2247 (2014).
    Article CAS Google Scholar
32. Sinclair, T. R. Is transpiration efficiency a viable plant trait in breeding for crop improvement? Funct. Plant Biol. 39, 359–365 (2012).
    Article Google Scholar
33. Flexas, J. et al. Mesophyll conductance to CO2 and Rubisco as targets for improving intrinsic water use efficiency in C3 plants. Plant Cell Environ. 39, 965–982 (2016).
    Article CAS Google Scholar
34. Hammer, G. L. & Wright, G. C. A theoretical-analysis of nitrogen and radiation effects on radiation use efficiency in peanut. Aust. J. Agric. Res. 45, 575–589 (1994).
    Article Google Scholar
35. de Pury, D. G. G. & Farquhar, G. D. Simple scaling of photosynthesis from leaves to canopies without the errors of big-leaf models. Plant Cell Environ. 20, 537–557 (1997).
    Article Google Scholar
36. Duncan, W. G., Loomis, R. S., Williams, W. A. & Hanau, R. A model for simulating photosynthesis in plant communities. Hilgardia 38, 181–205 (1967).
    Article Google Scholar
37. Messina, C., Hammer, G., Dong, Z. S., Podlich, D. & Cooper, M. in Crop Physiology: Applications for Genetic Improvement and Agronomy (eds Sadras, V. & Calderini, D.) 235–265 (Elsevier, 2009).
38. Ritchie, J. T. Model for predicting evaporation from a row crop with incomplete cover. Water Resour. Res. 8, 1204–1213 (1972).
    Article Google Scholar
39. Wong, S. C., Cowan, I. R. & Farquhar, G. D. Leaf conductance in relation to assimilation in Eucalyptus pauciflora Sieb. ex Spreng—influence of irradiance and partial pressure of carbon dioxide. Plant Physiol. 62, 670–674 (1978).
    Article CAS Google Scholar
40. Wong, S. C., Cowan, I. R. & Farquhar, G. D. Stomatal conductance correlates with photosynthetic capacity. Nature 282, 424–426 (1979).
    Article Google Scholar
41. Wolz, K. J., Wertin, T. M., Abordo, M., Wang, D. & Leakey, A. D. B. Diversity in stomatal function is integral to modelling plant carbon and water fluxes. Nat. Ecol. Evol. 1, 1292–1298 (2017).
    Article Google Scholar
42. Leakey, A. D. B. et al. Photosynthesis, productivity, and yield of maize are not affected by open-air elevation of CO2 concentration in the absence of drought. Plant Physiol. 140, 779–790 (2006).
    Article CAS Google Scholar
43. Pengelly, J. J. L. et al. Functional analysis of corn husk photosynthesis. Plant Physiol. 156, 503 (2011).
    Article CAS Google Scholar
44. von Caemmerer, S. & Farquhar, G. D. Some relationships between the biochemistry of photosynthesis and the gas exchange of leaves. Planta 153, 376–387 (1981).
    Article Google Scholar
45. McPherson, H. & Slatyer, R. Mechanisms regulating photosynthesis in Pennisetum typhoides. Aust. J. Biol. Sci. 26, 329–340 (1973).
    Article CAS Google Scholar
46. Yamori, W., Nagai, T. & Makino, A. The rate-limiting step for CO2 assimilation at different temperatures is influenced by the leaf nitrogen content in several C3 crop species. Plant Cell Environ. 34, 764–777 (2011).
    Article CAS Google Scholar
47. Braune, H., Mueller, J. & Diepenbrock, W. Integrating effects of leaf nitrogen, age, rank, and growth temperature into the photosynthesis-stomatal conductance model LEAFC3-N parameterised for barley (Hordeum vulgare L.). Ecol. Model. 220, 1599–1612 (2009).
    Article CAS Google Scholar
48. Sinclair, T. R. & Horie, T. Leaf nitrogen, photosynthesis, and crop radiation use efficiency—a review. Crop Sci. 29, 90–98 (1989).
    Article Google Scholar
49. Gifford, R. M. Plant respiration in productivity models: conceptualisation, representation and issues for global terrestrial carbon-cycle research. Funct. Plant Biol. 30, 171–186 (2003).
    Article Google Scholar
50. Probert, M. E., Dimes, J. P., Keating, B. A., Dalal, R. C. & Strong, W. M. APSIM’s water and nitrogen modules and simulation of the dynamics of water and nitrogen in fallow systems. Agric. Syst. 56, 1–28 (1998).
    Article Google Scholar
51. Lin, M. T., Occhialini, A., Andralojc, P. J., Parry, M. A. J. & Hanson, M. R. A faster Rubisco with potential to increase photosynthesis in crops. Nature 513, 547–550 (2014).
    Article CAS Google Scholar
52. Simkin, A. J., McAusland, L., Lawson, T. & Raines, C. A. Overexpression of the RieskeFeS protein increases electron transport rates and biomass yield. Plant Physiol. 175, 134–145 (2017).
    Article CAS Google Scholar
53. Jahan, E., Amthor, J. S., Farquhar, G. D., Trethowan, R. & Barbour, M. M. Variation in mesophyll conductance among Australian wheat genotypes. Funct. Plant Biol. 41, 568–580 (2014).
    Article Google Scholar
54. Ubierna, N., Gandin, A., Boyd, R. A. & Cousins, A. B. Temperature response of mesophyll conductance in three C4 species calculated with two methods: 18O discrimination and in vitro V pmax. New Phytol. 214, 66–80 (2017).
    Article CAS Google Scholar
55. von Caemmerer, S. & Evans, J. R. Temperature responses of mesophyll conductance differ greatly between species. Plant Cell Environ. 38, 629–637 (2015).
    Article Google Scholar
56. Flexas, J. et al. Mesophyll diffusion conductance to CO2: an unappreciated central player in photosynthesis. Plant Sci. 193, 70–84 (2012).
    Article Google Scholar
57. Flexas, J. et al. Tobacco aquaporin NtAQP1 is involved in mesophyll conductance to CO2 in vivo. Plant J. 48, 427–439 (2006).
    Article CAS Google Scholar

Download references