EPSCoR Biofuels Researcher Million Tadege in the News
OK EPSCoR Biofuels Researcher Million Tadege in the News
Researcher Tries to Crack Leaf Lamina Development Code
STILLWATER, Okla. – The leaves of plants are “the best solar panels ever built.” Why, you ask? Because the leaves of plants are where carbon dioxide from the atmosphere and light energy from the sun are used to produce sugars, which has rightfully given leaves their claim to fame.
With this in mind, Million Tadege, assistant professor of plant functional genomics in the department of plant and soil sciences at Oklahoma State University, has invested most of his research time into a leaf lamina development project.
Tadege hopes to create optimal plant leaf mass so the OSU bioenergy research team can increase the amount of useable material for biofuels. This research and development is funded in part by the National Science Foundation (NSF) Office of Experimental Program to Stimulate Competitive Research (EPSCoR). It will contribute greatly to OSU’s Biobased Products and Energy Center.
“From a structural point of view, broader leaves with a more planar surface area improve photosynthetic efficiency by allowing more efficient capture of solar energy and promoting gas exchange,” said Tadege. “However, such leaves would lose water rapidly, resulting in poor water use efficiency under dry conditions.”
Plants in a more moist environment may have broad and flat leaves to maximize photosynthesis, while plants that have adapted to the arid areas may produce small, thick leaves and grow slowly to avoid dehydration.
Sorghum and switchgrass are efficient in photosynthesis under high irradiance and high heat conditions and have a better water use efficiency in arid and semi arid environments attributing to the unique ability of their leaves to combine large surface area for carbon fixation to limited water loss by transpiration.
Such a strategy is what confers high biomass production capacity to most biofuels crops including switchgrass, biomass sorghum, energy cane and Miscanthus. Leaves are, therefore, the most important biomass determinant organs with adaptive ecological significance
“We set out to understand the mechanism of leaf lamina development by identifying the key genetic factors and uncovering their mode of actions. The genes we’re currently characterizing can be directly used for engineering crops to boost productivity or can be used as molecular markers to incorporate high biomass yielding traits in economically important biofuel crops such as switchgrass and sorghum,” Tadege said. “The implication is that this project will help farmers in Oklahoma and other parts of the nation to produce more biomass for lignocellulosic biofuels from a limited land area.
This reduces the competition of fuel crops with food crops for fertile land on one hand and promotes bioenergy sustainability on the other hand.
“The latter is critical for energy security of this nation and reduction of environmental pollution to preserve the habitability of our planet for future generations,” he said.
REPORTER/MEDIA CONTACT:
Sean Hubbard
Communications Specialist
Agricultural Communications Services
145 Agriculture North
Oklahoma State University
Stillwater, OK 74078-001
Phone: 405-744-4490
Fax: 405-744-5739
E-Mail: sean.hubbard@okstate.edu