Newswise — Scientists from Whitehead Institute and MIT have engineered yeast that can improve the speed and efficiency of ethanol production, a key component to making biofuels a significant part of the U.S. energy supply.
Currently used as a fuel additive to improve gasoline combustibility, ethanol is often touted as a potential solution to the growing oil-driven energy crisis. But there are significant obstacles to producing ethanol. One is that high ethanol levels are toxic to the yeast that ferments corn and other plant material into ethanol.
By manipulating the yeast genome, the researchers have engineered a new strain of yeast that can tolerate elevated levels of both ethanol and glucose, while producing ethanol faster than un-engineered yeast.
The work will be reported in the Dec. 8 issue of Science.
Fuels such as E85, which is 85 percent ethanol, are becoming common in states where corn is plentiful; however, their use is mainly confined to the Midwest because corn supplies are limited and ethanol production technology is not yet efficient enough.
Boosting efficiency has been an elusive goal, but the researchers, led by Hal Alper, a postdoctoral associate in the laboratories of MIT chemical engineering professor Gregory Stephanopoulos and Whitehead Member Gerald Fink, took a new approach.
The team targeted two proteins that belong to a class of proteins called transcription factors. These proteins typically control large groups of genes, regulating when these genes are turned on or shut off.
When the researchers altered a transcription factor called the TATA-binding protein, it caused the over-expression of at least a dozen genes, all of which were found to be necessary to elicit an improved ethanol tolerance. As a result, that strain of yeast was able to survive high ethanol concentrations.
In addition, this altered strain produced 50 percent more ethanol during a 21-hour period than normal yeast.
The prospect of using this approach to engineer similar tolerance traits in industrial yeast could dramatically impact industrial ethanol production, a multi-step process in which yeast plays a crucial role. First, cornstarch or another polymer of glucose is broken down into single sugar (glucose) molecules by enzymes, then yeast ferments the glucose into ethanol and carbon dioxide.
Last year, four billion gallons of ethanol were produced from 1.43 billion bushels of corn grain (including kernels, stalks, leaves, cobs, husks) in the United States, according to the Department of Energy. In comparison, the United States consumed about 140 billion gallons of gasoline.
Other co-authors on the paper are Joel Moxley, an MIT graduate student in chemical engineering, and Elke Nevoigt of the Berlin University of Technology.
The research was funded by the DuPont-MIT Alliance, the Singapore-MIT Alliance, the National Institutes of Health and the U.S. Department of Energy.
Written by David Cameron and Anne Trafton (MIT News Office)
Gerald Fink's primary affiliation is with Whitehead Institute of Biomedical Research, where his laboratory is located and all his research conducted. He also is a professor of biology at Massachusetts Institute of Technology.
To receive a copy of this paper, please contact [email protected].
Full citation
Science, Dec 8, 2006; vol 314:1565-1568
"Engineering yeast transcription machinery for improved ethanol tolerance and production"
Authors: Hal Alper(1,3), Joel Moxley(1), Elke Nevoigt(1,2), Gerald R. Fink(3), and Gregory Stephanopoulos(1)1 Department of Chemical Engineering, Massachusetts Institute of Technology, Cambridge, MA 2 Department of Microbiology and Genetics, Berlin University of Technology, Berlin, Germany3 Whitehead Institute for Biomedical Research, Cambridge, MA
Whitehead Institute for Biomedical Research is a nonprofit, independent research and educational institution. Wholly independent in its governance, finances and research programs, Whitehead shares a close affiliation with the Massachusetts Institute of Technology through its faculty, who hold joint MIT appointments.
RSS