Forestry Geneticists Develop Biomass Crop to Grow on Marginal Lands

Two Virginia Tech researchers have received a $1.4 million grant to investigate the genetic regulatory networks that will allow an important bioenergy crop to be bred so it will grow in less than ideal soils and climate. Populus, a genus of fast-growing trees commonly known as cottonwoods and aspens, is being grown for bioenergy because it produces a significant amount of biomass in two years and will re-grow robustly when cut at just above ground level. Woody biomass can be converted to liquid fuels, such as ethanol.

"The goal is to develop the species so it will not become dormant in conditions that would stress other crops, such as high temperature, drought, or marginal soil nutrients," said Amy Brunner, associate professor of molecular genetics in the College of Natural Resources and Environment and an affiliate of the Fralin Life Science Institute. "It is important that bioenergy crops not require prime agricultural land."
 
"We don’t want biomass production to compete with food production," Brunner continued. "The aim is to minimize inputs, develop varieties that grow in different environments, and maximize biomass production."
 
Brunner and Jason Holliday, assistant professor of forest genetics and biotechnology in the college and a fellow Fralin Life Science Institute affiliate, received the grant from the U.S. Department of Agriculture National Institute of Food and Agriculture and the U.S. Department of Energy Office of Biological and Environmental Research. Their project is one of 10 grants awarded as part of the national strategy of sustainable biofuels production.
 
"The college made the decision to enter into the specialized and highly competitive research arena of molecular genetics, and Drs. Brunner and Holliday are making important contributions to the body of molecular genetics science of tree species," said Paul Winistorfer, dean of the college. "Developing alternative approaches to biofuel crops and their adaptation and success to a changing climate is a strategic and important contribution to our future energy needs."
 
Brunner and Holliday are experimenting with the FT2 gene, which regulates vegetative growth. "In addition to seasonal dormancy, which happens when days get shorter, a common response to stress by woody plants is to stop growing and wait for things to get better, which is important to natural populations’ ability to survive adverse conditions," said Brunner.
 
"Jason and I are melding our expertise to understand growth and dormancy transitions," Brunner noted. "We will identify specific control points that can be manipulated to maximize growth in different environments."
 
The FT2 gene integrates signals regarding environmental conditions, such as day length and drought, to control shoot growth or regrowth after harvest.
 
"If we understand the network, such as what genes are sending the signal regarding nutrient level or day length, then we can use that in a breeding program for optimal biomass production in specific climates and on marginal lands," said Brunner. "This is also relevant to how to manage the health of this species’ natural populations in light of climate change, since, for instance, temperature also impacts seasonal dormancy," she added.
 
After identifying components of the response networks to day length and nutrient level that act through FT2, five to six genes will be selected for functional analysis to validate their utility for enhancing plant growth and yield under different environmental conditions.
 
"Populus is grown for biomass in the Pacific Northwest, the lower Mississippi valley, and the Great Lakes area. There has not been a market for it in the southeastern U.S., but there could be," said Brunner. "It could also be a resource for power, pulp, and paper."

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