Long-standing research efforts have been focused on understanding how
stem cells, cells capable of transforming into any type of cell in the
body, are capable of being programmed down a defined path to contribute
to the development of a specific organ like a heart, lung, or kidney.
Research from the University of North Carolina at Chapel Hill School of
Medicine has shed new light on how epigenetic signals may function
together to determine the ultimate fate of a stem cell.
The study, published December 27, 2012 by the journal Molecular Cell,
implicates a unique class of proteins called polycomb-like proteins, or
PCL's, as bridging molecules between the "on" and "off" state of a
gene. While all of these specialized types of cells share the same
genetic information encoded in our DNA, it is becoming increasingly
clear that information outside the genome, referred to as epigenetics,
plays a central role in orchestrating the reprogramming of a stem cell
down a defined path.
Although it is understood that epigenetics is responsible for turning
genes "on" and "off" at defined times during cellular development, the
precise mechanisms controlling this delicate process are less well
understood.
"This finding has important implications for both stem cell biology
and cancer development, as the same regulatory circuits controlled by
PCL's in stem cells are often misregulated in tumors," said Dr. Greg
Wang, senior author of the study and Assistant Professor of Biochemistry
and Biophysics in the UNC School of Medicine and a member of UNC
Lineberger Comprehensive Cancer Center.
The study, led by postdoctoral research fellows Drs. Ling Cai and Rui
Lu in the Wang lab, and Dr. Scott Rothbart, a Lineberger postdoctoral
fellow in the lab of Dr. Brian Strahl, Associate Professor of
Biochemistry and Biophysics in the UNC School of Medicine and a member
of UNC Lineberger Comprehensive Cancer Center, identified that PCL's
interact with an epigenetic signal associated with genes that are turned
on to recruit a group of proteins called the PRC2 complex which then
turn genes off.
"In stem cells, the PRC2 complex turns genes off that would otherwise
promote reprogramming into specialized cells of organs like the heart
or lungs," said Wang.
In addition to its fundamental role in cellular development, elevated
levels of PRC2 have been found in cancers of the prostate, breast,
lung, and blood, and pharmaceutical companies are already developing
drugs to target PRC2. Wang and colleagues determined that the same
mechanisms controlling PRC2 function in stem cells also applies in human
cancers.
"The identification of a specific PCL in controlling PRC2 in cancer
cells suggests we may be able to develop drugs targeting this PCL to
regulate PRC2 function in a more controlled manner that may maintain
PRC2 function in stem cells while inhibiting it in the tumor," said
Wang.
This research was funded by the National Institutes of Health grants
(GM085394 and GM068088), the Department of Defense, the V Foundation for
Cancer Research, and the University Cancer Research Fund, and was
performed in collaboration with scientists at the University of
California at Riverside, Rockefeller University, Memorial
Sloan-Kettering Cancer Center, and the Albert Einstein College of
Medicine. Study co-authors from UNC also included Bowen Xu, a student in
the Wang Lab, and Ashutosh Tripathy, a Research Professor in the
Department of Biochemistry and Biophysics.
Story Source:
The above story is reprinted from materials provided by University of North Carolina Health Care.
Courtesy: ScienceDaily
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