Ghent, Belgium
January 18, 2016
An international team of researchers, including Kun Yue, Tom Beeckman and Ive De Smet (VIB/UGent), discovered a new cell division regulator that shapes plant root systems, PROTEIN PHOSPHATASE 2A-3 (PP2A-3). Their findings, published this week in the journal ‘Proceedings of the National Academy of Sciences of the United States of America’, could lead to new techniques to improve root architecture in favor of higher crop yields.
Plant roots grow and branch out, tapping into the soil for water and nutrients. However, knowledge on the mechanisms that control root growth and development is limited. Working on the plant species Arabidopsis thaliana, De Smet and his team set out to find proteins that bind and interact with a known regulator of root systems, the ARABIDOPSIS CRINKLY 4 (ACR4) receptor kinase. Combining different biochemical methods resulted in the identification of PP2A-3 as a phosphorylation substrate of ACR4. Together with ACR4, PP2A-3 was shown to be part of a tightly controlled phosphorylation hub that orchestrates cell division and consequently root architecture. “These findings follow nicely on our previous work on ACR4, the first receptor kinase to be assigned a role in root development”, De Smet says. “Discovering a new interaction partner of ACR4 is exciting because we now have more insight in the action mechanism of this important plant growth regulator.”
Although the work took place in Arabidopsis, most crop plants have similar genes to ACR4 and PP2A-3. A better understanding of mechanisms governing root development can open the door to new tools to ensure crop productivity. For example, plants with deeper root networks thrive better because they can access more soil resources, like water and nitrogen. In contrast, more root branching in the top soil allows optimal foraging for phosphate. “More knowledge on root growth can serve as the foundation for the generation of new crop varieties with better developed root systems”, De Smet concludes.
Yue K. et al., 2016, Proceedings of the National Academy of Sciences of the United States of America
De Smet I. et al., 2008 Science
Nikonorova N. et al., 2015 Frontiers in Plant Science
VIB
Basic research in life sciences is VIB’s raison d’être. On the one hand, we are pushing the boundaries of what we know about molecular mechanisms and how they rule living organisms such as human beings, animals, plants and microorganisms. On the other, we are creating tangible results for the benefit of society. Based on a close partnership with five Flemish universities – Ghent University, KU Leuven, University of Antwerp, Vrije Universiteit Brussel and Hasselt University – and supported by a solid funding program, VIB unites the expertise of 75 research groups in a single institute. VIB’s technology transfer activities translate research results into new economic ventures which, in time, lead to new products that can be used in medicine, agriculture and other applications. VIB also engages actively in the public debate on biotechnology by developing and disseminating a wide range of science-based information about all aspects of biotechnology. More information: www.vib.be.
Ghent University
After more than twenty years of uninterrupted growth, Ghent University is now one of the most important institutions of higher education and research in the Low Countries. Ghent University yearly attracts over 41,000 students, with a foreign student population of over 2,200 EU and non-EU citizens. Ghent University offers a broad range of study programs in all academic and scientific fields. With a view to cooperation in research and community service, numerous research groups, centers and institutes have been founded over the years. For more information www.UGent.be.
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