Abstract
One of the crucial challenges faced by the plant research community today is in understanding the myriad processes that orchestrate growth, which is paramount to produce sufficient biomass for food and non-food applications in the future. Plant photoreceptors play important regulatory roles in developmental processes that can consequently affect productivity. The UN Food and Agriculture Organization estimates that by 2030 the world population will reach 8.3 billion. Biological approaches that can increase productivity and lower postharvest losses are thus essential for future food security. Regulating the activity of genes that can affect plant architecture, development or yield could likely be the key to increasing plant productivity. Recent advances in plant research have identified several photoreceptor genes and gene networks that play pivotal roles in these responses. The knowledge arising from such research therefore needs to be translated to the field to support programs aimed at increasing crop productivity. Given the evidence for their role in determining agricultural traits, these genes are favorably placed to become the focus of targeted breeding approaches for enhancing the agronomic value of domesticated lines.
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Acknowledgments
Financial support to E.K. from the Science and Engineering Research Board (Department of Science and Technology), New Delhi (Ref. No. SR/FT/LS-82/2011) and Italian National Agency for New Technologies, Energy, and Sustainable Development, Rome is acknowledged. Facilities provided by Prof. Giuliano Giovanni at Cassacia Research Centre, Italy to E.K. is greatly appreciated. The authors thank Soyaphi L.A.; Department of Botany, St. Edmund’s College for assisting with the artwork.
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Kharshiing, E., Sinha, S.P. Plant Productivity: Can Photoreceptors Light the Way?. J Plant Growth Regul 34, 206–214 (2015). https://doi.org/10.1007/s00344-014-9454-9
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DOI: https://doi.org/10.1007/s00344-014-9454-9