UT Southwestern Medical Center scientists collaborating with University of
Michigan researchers have found a previously unidentified mechanism that helps
explain why stem cells undergo self-renewing divisions but their offspring do
not.
Adult stem cells provide a ready supply of new cells needed for tissue
homeostasis throughout the life of an organism. Specialized environments called
"niches" help to maintain stem cells in an undifferentiated and self-renewing
state. Cells that comprise the niche produce signals and growth factors
essential for stem cell maintenance. The mechanisms that allow for reception of
these signals exclusively by stem cells and not their more specialized progeny
remain poorly understood.
"This finding stands to change the way we think about how stem cells and
their neighbors communicate with one another," said Dr. Michael Buszczak,
Associate Professor in the Department of Molecular Biology and with the Hamon
Center for Regenerative Science and Medicine.
The findings are presented in the journal Nature.
Scientists have been working to understand how the signaling between niches
and stem cells works.
"These signals act over a short range, so only stem cells ? but not their
differentiating progeny ? receive the self-renewing signals," said Dr. Buszczak,
E.E. and Greer Garson Fogelson Scholar in Medical Research. "The mechanics of
this communication were not known. What we discovered was that the stem cells
form microtubule-based nanotubes, which extend into the niche. These threadlike
nanotubes act like straws to tap into the niche and allow signaling to occur
specifically in the stem cell."
The findings emanate from an active collaboration between the Buszczak lab
at UT Southwestern and the lab of Dr. Yukiko Yamashita at the University of
Michigan. Dr. Yamashita is an Associate Professor of Cell and Developmental
Biology at the University of Michigan Life Sciences Institute and a Howard
Hughes Medical Institute (HHMI) Investigator.
First author Dr. Mayu Inaba, a Postdoctoral Research Fellow at the Life
Sciences Institute and a visiting Senior Fellow in Molecular Biology at UT
Southwestern in the Buszczak lab, noticed thin projections linking individual
stem cells back to a central hub in the stem cell "niche." Dr. Yamashita looked
through her old image files and identified the same connections in numerous
images. "I had seen them, but I wasn't seeing them," Dr. Yamashita said. Dr.
Inaba worked to further develop the project as a senior research fellow in the
Buszczak lab over the last several years.
The findings are important groundwork for understanding how stem cells
reproduce and how miscommunication between cells can result in diseases like
cancer. Too much stem cell production, for example, can lead to cancerous
growth. Too little reproduction can result in inadequate renewal of cells and
underlies the aging process.
The long-term goal of Dr. Buszczak's lab is to determine the complete
regulatory network that controls both the maintenance of Drosophila stem cells
and the differentiation of their daughters. "We hope to use this information as
a foundation for understanding how perturbations in normal gene expression
programs cause disease," Dr. Buszczak said.
The mission of the Hamon Center for Regenerative Science and Medicine is to
impact human health through discoveries of the fundamental mechanisms of tissue
formation and repair, and to use this knowledge to develop transformative
strategies and medicines to enhance tissue regeneration. The Center is led by
Dr. Eric Olson, Chair of Molecular Biology at UT Southwestern.
The research was supported by the HHMI and the MacArthur Foundation.
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