Once researchers identify and understand how these genes affect plant architecture, it will become possible to modify the plants so that they grow stalks, branches and leaves that are ideal for biofuel production. But tubulin also plays a significant role in controlling the movements of a special class of cells known as stomatal guard cells. As the name implies, these cells guard the tiny holes, or stoma, on the surface of plant leaves. The opening and closing of the guard cells allows the plant to take in carbon dioxide and expel oxygen, a byproduct of photosynthesis. “It would be great if we could increase biomass, but we think tubulin manipulation is more likely to affect cell wall properties,” Tsai said. “If we understand the system better, it might have the kind of properties that make it more amenable to biomass deconstruction.” In the ongoing search for cleaner, renewable energy sources, biofuels derived from trees, shrubs and grasses have emerged as a strong candidate. But creating the next generation’s energy source is not as simple as growing a few crops; extensive research is required to ensure these plants produce enough biomass and fuel per acre to make biomass farming economically viable. Her lab is particularly interested in how tubulin affects the development of Populus, a genus of woody plant that includes species like poplar, aspen and cottonwood trees. Tubulin proteins are thought to regulate wood development and, based on their recent findings, plant water use. If Tsai can modify tubulin levels, she and her team may be able to accelerate wood growth and make the trees more drought resistant. “We are interested in traits that influence biofuel production, and the number one trait is biomass volume,” Tsai said. “So wood formation is something we are very interested in.” Other collaborators on Tsai’s project include Scott Harding of Warnell, Michael Hahn at the UGA Complex Carbohydrate Research Center, Shawn Mansfield at the University of British Columbia and Gary Peter at the University of Florida. Because food crops can generate more revenue than biofuel crops, farmers will likely reserve their best land for fruits and vegetables, Paterson said. So biofuel feedstock needs to grow well in less fertile soil. But a better understanding of plant genetics also allows researchers and farmers to create plants that will survive in different environments. Like all plants, biofuel grasses alter their growing patterns based on a number of factors, such as the amount of rainfall, sunlight and soil nutrients they receive. “A plant has choices to make as to how it invests its resources,” Paterson said. “We’d like to get a handle on genes that determine how plants allocate their resources across various kinds of branches.” Ultimately, stress tolerance will be equally, if not more important than wood properties for developing perennial crops like poplars for bioenergy use. “If we better understand the genetics of plant architecture, we can try to tailor the crops to fit the land that they are going to find themselves in,” he said. “We can tailor the foot to fit the shoe, if you will.” Paterson’s research for this grant is focused on sorghum, a genus of grass that can produce high biomass yields, even under adverse conditions. However, Paterson expects to study other biofuel candidates, too. Tsai, a Georgia Research Alliance Eminent Scholar and professor in the Warnell School of Forestry and Natural Resources and the Franklin College of Arts and Sciences, received $1.496 million to study the importance of plant proteins called tubulin, which play critical roles in many basic plant functions. Manipulation of tubulin could make poplar easier to process into products like ethanol. Now, with the help of grants from the U.S. Departments of Agriculture and Energy, University of Georgia professors Andrew Paterson and Chung-Jui Tsai are conducting fundamental research to better understand the plants that may one day produce the fuel that powers our vehicles and homes. During drought, stomatal guard cells close off the openings on the leaf to prevent loss of water to the atmosphere, and the process of photosynthesis slows. Tsai’s lab found that modification of tubulin proteins could alter the behavior of guard cells to allow photosynthesis to continue at high rates even when they do not receive optimal amounts of water. Paterson, a Regents professor in the College of Agricultural and Environmental Sciences and the Franklin College of Arts and Sciences, researches grasses that show potential as high-biomass energy crops. He is particularly interested in discovering more about the genetics of what he calls “plant architecture,” the number and size of stalks or branches that plants develop as they grow. Exploratory work conducted with graduate student Wenqian Kong provided the justification for his $575,000 award. Tubulin may help regulate the deposition of cellulose, an organic compound that accounts for up to 50 percent of poplar biomass. If Tsai’s team uncovers the ways that tubulin influences the accumulation of cellulose, they may find ways to manipulate the genetic makeup to create trees that produce more cellulose, and, consequently, yield more biofuel. “This could translate into more biomass from trees grown in stressful environments, like the persistent drought many parts of the country is experiencing,” Tsai said. “Tubulin offers a rare opportunity for us to tackle both traits at the same time,” she said.