New roles emerge for non-coding RNAs
in directing embryonic development
Monday, 29 August 2011
Scientists at the Broad Institute of
MIT and Harvard have discovered that a mysterious class of large RNAs plays a
central role in embryonic development, contrary to the dogma that proteins
alone are the master regulators of this process. The research, published online
August 28 in the journal Nature, reveals that these RNAs orchestrate the fate
of embryonic stem (ES) cells by keeping them in their fledgling state or
directing them along the path to cell specialization.
lincRNAs orchestrate the fate of
embryonic
stem cells (shown here) by keeping them
in
their fledgling state or directing them
along
the path to cell specialization.
Image courtesy of Alex Meissner. |
Broad scientists discovered several years ago that the human and mouse genomes encode thousands of unusual RNAs — termed large, intergenic non-coding RNAs (lincRNAs) — but their role was almost entirely unknown. By studying more than 100 lincRNAs in ES cells, the researchers now show that these RNAs help regulate development by physically interacting with proteins to coordinate gene expression and suggest that lincRNAs may play similar roles in most cells.
“There’s
been a lot of debate about what lincRNAs are doing,” said Eric Lander, director of the Broad Institute and the senior
author of the paper.
“It’s
now clear that they play critical roles in regulating developmental decisions —
that is, cell fate. This was a big surprise, because specific types of proteins
have been thought to be the master controls of development.”
“This
is the first global study of lincRNAs,” said
Mitchell Guttman, first author of the paper and a graduate student at MIT and
the Broad Institute.
“We
picked embryonic stem cells in particular because they are so important to
development and so well understood. This allowed us to dissect the role of
lincRNAs within the circuitry of a cell.”
The researchers used genetic tools to
inhibit more than 100 lincRNAs and found that the vast majority — more than 90
percent — had a significant impact on embryonic stem cells, indicating that the
RNAs play a key role in the cells’ circuitry.
Embryonic stem cells can follow one of
two main routes. They can either differentiate, becoming cells of a specific
lineage such as blood cells or neurons, or they can stay in a pluripotent
state, duplicating themselves without losing the ability to become any cell in
the body. When the researchers turned off each lincRNA in turn, they found
dozens that suppress genes that are important only in specific kinds of cells.
They also found dozens of lincRNAs that cause the stem cells to exit the
pluripotent state.
“It’s
a balancing act,” said Guttman.
“To
maintain the pluripotent state, you need to repress differentiation genes.”
The researchers also uncovered a
critical clue about how lincRNAs carry out their important job. Through
biochemical analysis, they found that lincRNAs physically interact with key
proteins involved in influencing cell fate to coordinate their responses.
“The
lincRNAs appear to play an organizing role, acting as a scaffold to assemble a
diverse group of proteins into functional units,”
said John Rinn, an author on the paper, an assistant professor at Harvard
University and Medical School, and a senior associate member of the Broad Institute.
“lincRNAs
are like team captains, bringing together the right players to get a job done.”
“By
understanding how these interactions form, we may be able to engineer these
RNAs to do what we want them to do,” said Guttman.
“This
could make it possible to target key genes that are improperly regulated in
disease.”
Aviv Regev, an author on the paper, a
core member of the Broad Institute, and associate professor at MIT, sees the
team’s approach to studying the lincRNAs as important for the field.
“Many
people are interested in lincRNAs, but they need a comprehensive view of the
whole collection of lincRNAs,” said Regev.
“The
large-scale data and technology from this study will be useful for scientists
worldwide in studying both lincRNAs as well as many other RNAs in the cell.”
This project marks a collaborative
effort involving experts in embryonic stem cells and lincRNAs as well as
computational biologists and researchers in the Broad’s RNAi Platform, which
developed the tools needed to systematically silence lincRNAs. Other
researchers who contributed to this work include Julie Donaghey, Bryce W.
Carey, Manuel Garber, Jennifer K. Grenier, Glen Munson, Geneva Young, Anne
Bergstrom Lucas, Robert Ach, Xiaoping Yang, Ido Amit, Alexander Meissner, and
David E. Root. This work was funded by the National Human Genome Research
Institute, the Richard Merkin Foundation for Stem Cell Research at the Broad
Institute, and funds from the Broad Institute of MIT and Harvard.
Source:
Broad Communications
Contact:
Haley Bridger
Reference:
lincRNAs act in the circuitry
controlling pluripotency and differentiation Mitchell Guttman, Julie Donaghey, Bryce W. Carey, Manuel Garber, Jennifer K. Grenier, Glen Munson, Geneva Young, Anne Bergstrom Lucas, Robert Ach, Laurakay Bruhn, Xiaoping Yang, Ido Amit, Alexander Meissner, Aviv Regev, John L. Rinn, David E. Root & Eric S. Lander
Nature. August 28, 2011 DOI: 10.1038/nature10398
See also:
LincRNAs
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