The research, published in Nature Plants, critically analyzed existing information, including the authors' own research, and found what the team believes to be crucial information for the future of agriculture production.
Professor Ruan said that as agriculture faced a massive increase in demand from a booming population and environmental deterioration, it was essential to understand the biological processes that regulate resource and energy distribution in the plant body, thereby allowing the identification of key gene targets for genetic engineering and breeding. Professor Ruan's team discovered some of the barriers that limit plant growth and reproduction, and their study's importance was due to projections that the world will need to double crop yield by 2050, feeding more people with less arable land. In addition to the enormous need to increase crop yields, global warming-associated drought, salt, and heat stresses, pathogen and pest infections mean that future proofing plants through modification to make them more productive and resilient is paramount to human survival.
Using potatoes and cassava plants, along with other species such as tomato, rice, and cotton as models, the research team identified a suite of genes and proteins that limit a leaf's ability to efficiently use solar energy to make assimilates (mainly sucrose), and the translocation to and use of the assimilates within sink organs, such as seeds, fruits, and roots. In identifying these bottlenecks, Professor Ruan's team also discovered the signaling molecules and regulatory genes that trigger or initiate the growth of sink organ – what determines how many seeds, flowers, or fruit a plant might grow.
For more details, read the article at The University of Newcastle Australia.