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Finding an Off Switch in Wood Formation

The same process plants use to respond to environmental stress acts as an on/off switch for a key enzyme in wood formation, NC State researchers have found.

The discovery improves scientists’ understanding of how lignin, which gives wood its strength and ability to transport water, is formed in plants and how it can be altered for biofuel, pulp and paper production, which require costly lignin removal with harsh chemicals. The findings from the Forest Biotechnology Group, led by Vincent Chiang and Ron Sederoff, appear in Proceedings of the National Academy of Sciences.

“After two decades we confirmed a new mode of regulating an important pathway in plant development,” says lead author Jack Wang, a member of the Forest Biotechnology Group in the College of Natural Resources. “This finding gives us a better understanding of plants, especially how wood is formed, which will allow us to modify the process for economically important uses of wood.”

“Plants use a process called protein phosphorylation to rapidly respond to external stimuli, such as threats from drought, pests or diseases,” says Ling Chuang, co-lead author with the Forest Biotechnology Group. NC State chemists Philip Loziuk and David Muddiman played a critical role in developing a new mass spectrometry-based technique used in the study.

Researchers focused on an enzyme controlling six of 35 chemical reactions in the lignin biosynthesis pathway, all of which were shut down, significantly altering lignin composition in black cottonwood.

The research could be used to help modify plant properties and physical traits, including engineering plants that will be better biofuel feedstocks or modifying them to be more resistant to pests.

The study found that about 97 percent of all plant species, including pines and grasses, are equipped with sites for phosphorylation, Wang says, though more research will be needed to unravel how it works.

“Phosphorylation-mediated control of wood formation seems to be a ubiquitous process in plants,” he says. “It’s probably a very ancient mechanism.”

The current research builds on two seminal NC State studies published in 2014 that provide the equivalent of GPS directions for future research. New research findings are being incorporated into a predictive model created during that work, improving its accuracy.

The PNAS study was funded with National Science Foundation Plant Genome Research Program Grant DBI-0922391, the NC State Jordan Family Distinguished Professor Endowment, the NC State Forest Biotechnology Industrial Research Consortium and National Natural Science Foundation of China Grants 31470672 and 3140093.

Contributing authors Hao Chen, Ying-Chung Lin and Rui Shi are also members of NC State’s Forest Biotechnology Group. Guan-Zheng Qu is with the Northeast Forestry University of China.

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  1. Please don’t let this out into the world! I can just imagine forests full of trees with no strength to raise their branches, all because pollen from these GE plants drifted…I hope it’s only in my imagination, but caution is warranted. It’s not nice to fool Mother Nature! You never know what the ecological ramifications will be.