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Contact: Layne Cameron
layne.cameron@cabs.msu.edu
517-353-8819
Michigan State University
EAST LANSING, Mich. Most organisms would die in the volcanic sulfur pools of Yellowstone and Mount Etna. Robust simple algae call it home, and their secrets to survival could advance human medicine and bioremediation.
Mike Garavito, Michigan State University professor of biochemistry and molecular biology was part of a research team that revealed how primitive red algae use horizontal gene transfer, in essence stealing useful genes from other organisms to evolve and thrive in harsh environments.
Their study, published in the current issue of Science, shows that the algae's ability to adapt to a hot and extremely acidic environment lies in part in their membrane proteins.
"The algae's membrane proteins are biologically quite interesting because they're receptors and transporters, the same classes of proteins that play key roles in energy metabolism and human immune response," said Garavito. "This has applications in human medicine because virtually all of the important pathways that contribute to disease treatment involve membrane proteins."
What makes the algae's membrane proteins attractive as a model for humans is their robustness. Other traditional candidates, such as yeast, insect cell cultures and slime mold, are fragile. The algae give researchers extra time to manipulate and examine their membrane proteins.
Garavito was part of a team of researchers led by Andreas Weber, former MSU researcher now at Heinrich-Heine-Universitat Dusseldorf (Germany). While at MSU, Weber led a team in first sequencing the algae, one of the first major genome sequencing projects at MSU.
"Weber knew that this would be a good organism from which to harvest a wide variety of genes that could be potential models for those involved in human health and disease," said Dave Dewitt, associate dean of research at MSU's College of Natural Science. "From a biotechnology standpoint, this organism is the Wal-Mart of genomes; if it doesn't have what you're looking for, you probably don't need it."
Furthering the superstore metaphor, the research team also is spending time in the Wal-Mart genome's bioremediation aisle. In this capacity, scientists are quite interested in how the organisms manage toxic chemicals and heavy metal contamination. That's because these algae are found not only near geysers, but they also populate polluted slag pools and mines.
"This organism knows how to deal with leaching loads of heavy metals in a noxious environment," Garavito said. "This research could lead to enzymes that are needed to clean up mine and heavy-metal contamination."
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MSU scientists who contributed to this paper include: Kevin Carr, information technologist, and Curtis Wilkerson, plant biologist. The team also included researchers from Oklahoma State University, Ernst Moritz Arndt Universitat Greifswald, University of Michigan, University of California-Berkeley, University of Freiburg, Universite de Lille, CyanoBiofuels GmbH, Novocymes Inc., Scripps Institution of Oceanography, University of California-San Diego and Philipps-University Marburg.
The research was funded by the National Science Foundation.
Michigan State University has been working to advance the common good in uncommon ways for more than 150 years. One of the top research universities in the world, MSU focuses its vast resources on creating solutions to some of the world's most pressing challenges, while providing life-changing opportunities to a diverse and inclusive academic community through more than 200 programs of study in 17 degree-granting colleges.
For MSU news on the Web, go to MSUToday. Follow MSU News on Twitter at twitter.com/MSUnews.
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AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert! system.
[ | E-mail | Share ]
Contact: Layne Cameron
layne.cameron@cabs.msu.edu
517-353-8819
Michigan State University
EAST LANSING, Mich. Most organisms would die in the volcanic sulfur pools of Yellowstone and Mount Etna. Robust simple algae call it home, and their secrets to survival could advance human medicine and bioremediation.
Mike Garavito, Michigan State University professor of biochemistry and molecular biology was part of a research team that revealed how primitive red algae use horizontal gene transfer, in essence stealing useful genes from other organisms to evolve and thrive in harsh environments.
Their study, published in the current issue of Science, shows that the algae's ability to adapt to a hot and extremely acidic environment lies in part in their membrane proteins.
"The algae's membrane proteins are biologically quite interesting because they're receptors and transporters, the same classes of proteins that play key roles in energy metabolism and human immune response," said Garavito. "This has applications in human medicine because virtually all of the important pathways that contribute to disease treatment involve membrane proteins."
What makes the algae's membrane proteins attractive as a model for humans is their robustness. Other traditional candidates, such as yeast, insect cell cultures and slime mold, are fragile. The algae give researchers extra time to manipulate and examine their membrane proteins.
Garavito was part of a team of researchers led by Andreas Weber, former MSU researcher now at Heinrich-Heine-Universitat Dusseldorf (Germany). While at MSU, Weber led a team in first sequencing the algae, one of the first major genome sequencing projects at MSU.
"Weber knew that this would be a good organism from which to harvest a wide variety of genes that could be potential models for those involved in human health and disease," said Dave Dewitt, associate dean of research at MSU's College of Natural Science. "From a biotechnology standpoint, this organism is the Wal-Mart of genomes; if it doesn't have what you're looking for, you probably don't need it."
Furthering the superstore metaphor, the research team also is spending time in the Wal-Mart genome's bioremediation aisle. In this capacity, scientists are quite interested in how the organisms manage toxic chemicals and heavy metal contamination. That's because these algae are found not only near geysers, but they also populate polluted slag pools and mines.
"This organism knows how to deal with leaching loads of heavy metals in a noxious environment," Garavito said. "This research could lead to enzymes that are needed to clean up mine and heavy-metal contamination."
###
MSU scientists who contributed to this paper include: Kevin Carr, information technologist, and Curtis Wilkerson, plant biologist. The team also included researchers from Oklahoma State University, Ernst Moritz Arndt Universitat Greifswald, University of Michigan, University of California-Berkeley, University of Freiburg, Universite de Lille, CyanoBiofuels GmbH, Novocymes Inc., Scripps Institution of Oceanography, University of California-San Diego and Philipps-University Marburg.
The research was funded by the National Science Foundation.
Michigan State University has been working to advance the common good in uncommon ways for more than 150 years. One of the top research universities in the world, MSU focuses its vast resources on creating solutions to some of the world's most pressing challenges, while providing life-changing opportunities to a diverse and inclusive academic community through more than 200 programs of study in 17 degree-granting colleges.
For MSU news on the Web, go to MSUToday. Follow MSU News on Twitter at twitter.com/MSUnews.
[ | E-mail | Share ]
?
AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert! system.
Source: http://www.eurekalert.org/pub_releases/2013-03/msu-hth030813.php
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