Saturday, June 18, 2011
Nitrogen-fixing bacterial symbiont promises trove of natural products
Science Daily: Soil-dwelling bacteria of the genus Frankia have the potential to produce a multitude of natural products, including antibiotics, herbicides, pigments, anticancer agents, and other useful products, according to Bradley S. Moore of the Scripps Oceanographic Institute, La Jolla, and his collaborators in an article in the June 2011 issue of the journal Applied and Environmental Microbiology.
The researchers found genetic structures in this bacterium that resemble those of various valuable natural product categories through bioinformatics and genome mining. "This tremendous biosynthetic capacity is reminiscent of many industrially important bacteria such as those belonging to the genus, Streptomyces that produce the majority of the natural antibiotics used as drugs," says Moore.
"To see this capacity in a well-known microbe not previously exploited for its chemical richness was very rewarding from both an applied and basic science point of view," says Moore. Frankia are nitrogen-fixing bacteria that live in symbiosis with actinorhizal plants (whose ranks include beech and cherry trees, and various gourd-producing plants). "Since the vast majority of the deduced [biosynthetic] pathways are unique to Frankia, it suggests that they employ a very complex and specialized communication with their plant host to establish and maintain their symbiosis. So lots to discover there."
Frankia have not previously been exploited partly because these bacteria are difficult to grow in the lab. But new genetic methods make it easier to transplant genes for promising natural products from Frankia into "more user-friendly host bacteria for production," says Moore.
Moreover, genome mining, a recent technique that involves searching for genetic sequences, was critical to the results, and "complementary to the far more laborious traditional natural product drug discovery that has gone unchanged for decades," says Moore. A greater understanding of how complex organic molecules are synthesized in nature laid additional groundwork for this, and for "a new revolution in the discovery of natural chemicals that will fuel new research into what functions these chemicals play in nature, and how they can be used to benefit society," says Moore….
Frankia alni, for all your actinorhizal needs, shot by Lebrac, Wikimedia Commons, under the Creative Commons Attribution-Share Alike 3.0 Unported
The researchers found genetic structures in this bacterium that resemble those of various valuable natural product categories through bioinformatics and genome mining. "This tremendous biosynthetic capacity is reminiscent of many industrially important bacteria such as those belonging to the genus, Streptomyces that produce the majority of the natural antibiotics used as drugs," says Moore.
"To see this capacity in a well-known microbe not previously exploited for its chemical richness was very rewarding from both an applied and basic science point of view," says Moore. Frankia are nitrogen-fixing bacteria that live in symbiosis with actinorhizal plants (whose ranks include beech and cherry trees, and various gourd-producing plants). "Since the vast majority of the deduced [biosynthetic] pathways are unique to Frankia, it suggests that they employ a very complex and specialized communication with their plant host to establish and maintain their symbiosis. So lots to discover there."
Frankia have not previously been exploited partly because these bacteria are difficult to grow in the lab. But new genetic methods make it easier to transplant genes for promising natural products from Frankia into "more user-friendly host bacteria for production," says Moore.
Moreover, genome mining, a recent technique that involves searching for genetic sequences, was critical to the results, and "complementary to the far more laborious traditional natural product drug discovery that has gone unchanged for decades," says Moore. A greater understanding of how complex organic molecules are synthesized in nature laid additional groundwork for this, and for "a new revolution in the discovery of natural chemicals that will fuel new research into what functions these chemicals play in nature, and how they can be used to benefit society," says Moore….
Frankia alni, for all your actinorhizal needs, shot by Lebrac, Wikimedia Commons, under the Creative Commons Attribution-Share Alike 3.0 Unported
Labels:
agriculture,
bacteria,
business,
economics,
science
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