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Where DNA's copy machine pauses, cancer could be
next
Date:
May 5, 2014
Source:
Duke University
Summary:
A comprehensive mapping of the 'fragile sites' where
chromosomes are more likely to experience breakage shows the damage appears in
specific areas of the genome where the DNA copying machinery is slowed or
stalled during replication, either by certain sequences of DNA or by structural
elements. The study could give insight into the origins of many of the genetic
abnormalities seen in solid tumors.
...............................
Each time a human cell divides, it must first make a copy of
its 46 chromosomes to serve as an instruction manual for the new cell.
Normally, this process goes off without a hitch. But from time to time, the
information isn't copied and collated properly, leaving gaps or breaks that the
cell has to carefully combine back together.
Researchers
have long recognized that some regions of the chromosome,called "fragile
sites," are more prone to breakage and can be a breeding ground for human
cancers. But they have struggled to understand why these weak spots in the
genetic code occur in the first place.
A
comprehensive mapping of the fragile sites in yeast by a team of Duke
researchers shows that fragile sites appear in specific areas of the genome
where the DNA-copying machinery is slowed or stalled, either by certain
sequences of DNA or by structural elements. The study, which appears May 5 in Proceedings
of the National Academy of Sciences, could give insight into the origins of
many of the genetic abnormalities seen in solid tumors.
"Other
studies have been limited to looking at fragile sites on specific genes or
chromosomes," said Thomas D. Petes, Ph.D., the Minnie Geller professor of
molecular genetics and microbiology at Duke University School of Medicine.
"Ours is the first to examine thousands of these sites across the entire
genome and ask what they might have in common."
The term
"fragile sites" was first coined in the 1980s to describe the
chromosome breaks that appeared whenever a molecule called DNA polymerase --
responsible for copying DNA -- was blocked in mammalian cells. Since that
discovery, research in the yeast Saccharomyces cerevisiae has shown that
certain DNA sequences can make the polymerase slow down or pause as it makes
copies. However, none of them have shown how those delays result in fragile
sites.
In this
study, Petes wanted to find the link between the copier malfunction and its
genetic consequences on a genome-wide scale. First, he knocked down the levels
of DNA polymerase in yeast cells to ten-fold lower than normal. Then he used
microarray or "gene chip" technology to map where segments of DNA had
been rearranged, indicating that a fragile site had once been there.
After
finding those fragile sites, his laboratory spent more than a year combing
through the literature for any recurring themes among the genomic regions they
had uncovered. Eventually they showed that the fragile sites were associated
with sequences or structures that stalled DNA replication, esoteric entities
such as inverted repeats, replication termination signals, and transfer RNA
genes.
"We
only published the tip of the iceberg -- there is a lot of work you don't see
because the connections simply weren't significant enough. Even now, we didn't
find any single sequence motif that would very clearly predict a fragile
site," said Petes. "I think there are just a lot of ways to slow down
replication, so there is not just one signal to indicate that would
occur."
In addition,
Petes found that these fragile sites created a surprisingly unstable genome,
resulting in a chaotic milieu of rearrangements, duplications and deletions of
pieces of DNA or even the gain or loss of entire chromosomes.
"The
ability to analyze these sites on a genome-wide basis is an important
advance," said Gray Crouse, Ph.D., an expert unaffiliated with the new
study who is a professor of biology at Emory University. "It has been
known for a long time that many cancer cells have an abnormal number of
chromosomes, and many different chromosome rearrangements have been observed in
various tumor cells. It is likely that there are many different causes of
chromosome instability in cancer cells. The current work suggests that those
chromosomal rearrangements observed at fragile sites and found in solid tumors
may be due to breaks from perturbed replication."
Story
Source:
The above
story is based on materials provided by Duke University. Note: Materials may be edited
for content and length.
Journal
Reference:
- Wei Song, Margaret Dominska, Patricia W. Greenwell, Thomas D. Petes. Genome-wide high-resolution mapping of chromosome fragile sites in Saccharomyces cerevisiae. PNAS, May 2014 DOI: 10.1073/pnas.1406847111
Cite This
Page:
Duke University. "Where DNA's
copy machine pauses, cancer could be next." ScienceDaily. ScienceDaily, 5
May 2014. <www.sciencedaily.com/releases/2014/05/140505211420.htm>.
