The discovery, by Bradley R. Cairns, PhD, Senior Director of Basic
Science at HCI and a professor in the Department of Oncological Sciences, is
reported in this week's online issue of the journal Nature.
Cairns's research focuses on chromatin remodeling complexes
(CRCs), which are cellular protein complexes that behave like motors, expanding
or compacting different portions of DNA to either express or silence genes,
respectively. Before, scientists thought that the motor within CRCs waits at
rest until it receives instructions. Cairns and co-author Cedric R. Clapier
show that the motor within a key CRC responsible for gene packaging and
assembly is intrinsically turned on, and instead requires specific instructions
to turn it off.
"Many articles in the research literature show that CRCs are
mutated in cancer cells. They are intimately involved in regulating gene
expression -- responsible for correctly packaging genes that control growth
proliferation and for unpackaging tumor suppressors," said Cairns.
"This research reveals principles by which CRC mutations could cause cancer."
Chromosomes are made of long DNA strands compressed around nodes
of protein called nucleosomes; when DNA is compressed, the genes in that area
are turned off. Some CRCs, called disassembly CRCs, act as motors that unwind
sections of DNA chains, making genes active for a given cell process. Another
type, called assembly CRCs, rewinds the DNA chain, recompressing it when the
process is complete. The unwind-rewind cycle is repeated continuously
throughout a cell's life.
In this study, Cairns and Clapier focused on assembly CRCs.
"Before this research, we thought that the motor was off unless a protein
coming from another part of the cell turned it on," said Cairns.
"Researchers have been searching for the switch by looking at the CRC
motor to see what binds to it.
"As it turns out, we discovered that the CRC motor already
carries on its flank a 'switch' that inhibits its action until a marker
sequence, located on the nucleosome, is encountered. The marker flips the
inhibitor switch and allows the CRC to crank the DNA chain back around the
nucleosome, promoting gene packaging and silencing" Cairns said. "Our
results change where future researchers should be looking to understand how
CRCs are regulated -- not at the CRC motor itself, but at the 'switches' that
flank the motor."
The study also describes a measuring function on the CRC that
checks for the correct distance between one nucleosome and the next, telling
the motor to switch off at the proper time, a function needed for gene
silencing.
Cairns's lab will now examine this same switching concept in
disassembly remodelers. "There are additional remodeler families with
alternative functions, like DNA repair," said Cairns. "We think this
concept will apply to them as well."
This research was supported by funding from the National
Institutes of Health (GM60415 and CA042014) and from the Howard Hughes Medical
Institute.
Journal Reference:
1. Cedric R. Clapier, Bradley R. Cairns. Regulation
of ISWI involves inhibitory modules antagonized by nucleosomal epitopes. Nature,
2012; DOI:10.1038/nature11625
Source:
The above story is reprinted from materials provided
by University of Utah Health Sciences.
Note: Materials may be edited for content and length.
For further information, please contact the source cited above.
Disclaimer: This article is not intended to provide medical advice, diagnosis or treatment. Views expressed here do not necessarily reflect those of Eagle Group or its staff.
Disclaimer: This article is not intended to provide medical advice, diagnosis or treatment. Views expressed here do not necessarily reflect those of Eagle Group or its staff.
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