NREL's Research in Bioenergy Science Gets a Boost

From the 2007 Research Review.

Photo of a man wearing a lab coat and peering into binoculars attached to a complex optical device. The main part of the device is about one foot in front of him and consists of a one foot-by-one foot platform, about two inches thick, with a 6-inch hole in its center. A metal column rises from one side of the platform to hold a lens, which is suspended above the hole. The column also supports a metal rectangular box mounted several inches above the lens, and that box has a hole in it that aligns with the lens and the hole in the platform.

Researcher Shi-you Ding images cellulosome enzymes in NREL's Compositional Analysis Laboratory.

NREL's ability to pursue new discoveries in basic bioenergy science received a major boost in 2007, when DOE announced funding for a new Bioenergy Science Center. NREL will play a major role in the new center.

For more than 30 years, NREL researchers have been working to increase our knowledge of the science underlying renewable energy technologies. But according to Mike Himmel, manager of the NREL Biomolecular Science Group, new gains in bioenergy science will have to come from a renewed focus on a deeper understanding of the fundamental science underlying biotechnologies. The DOE Bioenergy Science Center will provide that ability.

In August 2006, the DOE Office of Science Genomics: GTL (formerly, Genomes to Life) Program issued a solicitation for genomics-related investigations that will accelerate basic research in the development of cellulosic ethanol and other biofuels. To respond to the solicitation, NREL teamed with DOE's Oak Ridge National Laboratory (ORNL) and several universities, bioenergy companies, and other institutions to propose a DOE Bioenergy Science Center. In June 2007, DOE announced that the proposal was one of three successful ones among more than 20 submitted. The center will be based at ORNL and is slated to receive $25 million per year for five years from the Genomics: GTL Program.

Photo of a bacterium consisting of a cylindrical shape with a slight indent in its center, and with amorphous blobs hanging below the cylinder on both sides of the indent, with a small tendril connecting the two blobs. Hundreds of small dots cover the cylindrical part of the bacterium.

Each spherical shape on the surface of this Acetivibrio cellulolyticus bacterium is a cellulosome containing several different enzymes active in breaking cellulose down to its component sugars. With new Bioenergy Science Center funding, NREL researchers can research the overall action of the cellulosome in a way that they have not been able to before.

The new center's goal is to develop the science and technology that enables cost-effective conversion of cellulosic biomass to biofuels. To that end, the center will focus on two major research pathways, both involving recombinant genetics. For the first pathway, the center will develop plants that can be broken down more easily into their component sugars for fermentation, while the second pathway will focus on the microorganisms employed in biofuel production.

"The microorganisms we now use for biomass conversion tend to either be good at producing enzymes for breaking biomass down to sugar or good at fermenting those sugars, but not both," Himmel says.

The effort will develop new microorganisms that can do both well, so that today's multiple-step process can be carried out in a single step, called "consolidated bioprocessing." This achievement should increase process efficiency and reduce capital equipment costs.

NREL's three contributions to the work of the center will include advanced analysis and imaging, rapid analyses of large numbers of samples, and improvements in the biochemistry of cellulosomes. Cellulases are enzymes used to break cellulose down into its component sugars, and cellulosomes are complexes of cellulases that work together in the breakdown process.

"This funding will allow us to work on the entire process in a way that we have not been able to do before," Himmel says.

Illustration that shows the five steps of the R&D process: Innovation, Technology Development, Product Development, Commercial Demonstration, and Large-Scale Deployment. Innovation is highlighted.

This technology is in the Innovation phase of the R&D process. Learn more in "From Research Discoveries to Market: Five Steps to Commercialization."

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