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The source of this article is Science Daily: http://tinyurl.com/cbp4g

Scientists Identify Genetic Pathways Essential To RNA Interference

A research team based at Massachusetts General Hospital (MGH) has
identified 80 new genes essential to the process of RNA interference
(RNAi), a powerful new research tool for inactivating genes in plants or
animals. They used the RNAi process itself to find new genes that
participate in the gene-silencing mechanism, which someday may help to
fight human disease. The report will appear in the journal Science and is
receiving early online release on the Science Express website at
http://www.sciencexpress.org.


"The gene activation produced by RNAi is exquisitely specific, which gives
it enormous potential for therapeutic application," says Gary Ruvkun, PhD,
of the MGH Department of Molecular Biology, the study's senior author.
"Imagine short, double-stranded RNA molecules that could be synthesized
quickly and inexpensively to silence a single gene. Promising targets could
include viruses like HIV and hepatitis C or cancer-causing oncogenes. An
RNAi-based treatment for age-related macular degeneration is already in
clinical trials." Ruvkun is a professor of Genetics at Harvard Medical School.

RNAi was originally identified in the C. elegans roundworm and the
flowering plant Arabidopsis thaliana, both of which are common model
organisms for biological research. The process interrupts the usual
transfer of instructions from double-stranded DNA, through single-stranded
messenger RNA and finally into proteins. Short, double-stranded pieces of
RNA bind to the complementary messenger RNA segments, shutting down gene
expression. RNAi occurs naturally in plants and animals and may help
control resistance to viral infection, among other functions.

For the current study, lead author John Kim, PhD, and his colleagues
developed a strain of C. elegans into which they added a gene that caused
the worms to glow under ultraviolet light but also turned that gene off
using RNAi. They then used RNAi to inactivate every one of the worms'
19,000 genes by feeding the worms bacteria that produce double-stranded RNA
for each gene. Inactivation of about 90 genes caused the worms to glow,
indicating that those genes were essential to the RNAi process that had
been suppressing expression of the fluorescence gene.

Some of the identified genes -- many of which have human counterparts --
code for proteins involved with the packaging and processing of RNA, but
others may be involved with the regulation of DNA itself, including the
repair of DNA damage. "These new steps indicate there is more to RNAi than
RNA destruction," says Kim. "And the connection to DNA damage pathways,
which was totally unexpected, suggests a potential connection between RNAi
and the control of cell division in cancer."

The researchers note that better understanding the mechanisms underlying
RNAi could help transform what has been a research tool into a powerful
therapeutic tool. Although the process has worked well in studies of
cultured human cells, it has not yet been effective for experimentally
suppressing gene expression in living mammals. Identifying each step in the
RNAi process could lead to more successful inactivation of disease-related
genes. And in addition to the technique's potential for gene silencing,
controlling levels of RNAi that may underlie some cancers or be used in
viral replication may offer further clinical potential.

Along with Kim, the study's co-first authors are Harrison Gabel and Ravi
Kamath, MD, PhD, of the MGH Department of Molecular Biology. Additional
authors are Michael Dybbs and Joshua Kaplan, PhD, of MGH; Muneesh Tewari,
MD, PhD, Jean-Francois Rual, Nicolas Bertin, and Marc Vidal, PhD, of
Dana-Farber Cancer Institute; Amy Pasquinelli, PhD, of the University of
California at San Diego; and Scott Kennedy, PhD, of the University of
Wisconsin.

The research was supported by grants from the National Institutes of Health.

Editor's Note: The original news release can be found here.


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This story has been adapted from a news release issued by Massachusetts
General Hospital.

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