Whitehead Institute researchers have found that increased expression of a
specific set of genes is strongly associated with metastasis and death
in patients with breast, colon, and lung cancers. Not only could this
finding help scientists identify a gene profile predictive of patient
outcomes and response to treatment, it could also guide the development
of therapeutics to target multiple cancer types.
The genes identified are activated by a transcription factor called
heat-shock factor 1 (HSF1) as part of a transcriptional program distinct
from HSF1's well-known role in mediating the response of normal cells
to elevated temperature.
In normal cells, a variety of stressors, including heat, hypoxia, and
toxins, activate HSF1 leading to increased expression of so-called
heat-shock or chaperone proteins that work to maintain protein
homeostasis in stressed cells. Scientists have known for some time that
many cancer cells have higher levels of chaperones and that elevation of
these proteins is important for survival and proliferation of tumor
cells.
Now, however, researchers in the lab of Whitehead Member Susan
Lindquist report that HSF1 supports cancers not only by increasing
chaperones, but by unexpectedly regulating a broad range of cellular
functions that are important for the malignant behavior of tumor cells.
This activity allows for the development of the most aggressive forms of
three of the most prevalent cancers -- breast, lung, and colon. The
findings, published this week in the journal Cell, build on
earlier research from the Lindquist lab showing that elevated levels of
HSF1 are associated with poorer prognosis in some forms of breast
cancer.
"This work shows that HSF1 is fundamentally important across a broad
range of human cancers, cancers of various types from all over the body
turn on this response," says Sandro Santagata, a postdoctoral researcher
in the Lindquist lab. "That's very interesting. It suggests how
important HSF1 must be for helping tumors become their very worst."
In addition to confirming that this gene activation program differs
from that associated with heat shock, the researchers found that in many
tumors, it becomes active in virtually all of the tumor's cells.
"This demonstrates it isn't simply regions of microenvironmental
stress within a tumor that drive HSF1 activity, but rather that HSF1
activation is wired into the core circuitry of cancer cells,
orchestrating a distinct gene regulatory program that enables
particularly aggressive phenotypes," says Marc Mendillo, a postdoctoral
researcher in the Lindquist lab. "This suggests HSF1 itself could be a
great therapeutic target."
Luke Whitesell, an oncologist and senior research scientist in the
Lindquist lab, concurs that HSF1 is a conceptually appealing target for
therapeutic intervention, noting that suppressing HSF1 for short periods
of time should have minimal consequences on normal cells. However, he
adds, actually developing such a drug could be problematic.
"Coming up with a drug that disrupts HSF1's interaction with DNA,
which is how it activates all of these genes, that is going to be really
tough," says Whitesell. "No one has come up with a clinically useful
drug that directly interrupts a transcription factor's interaction with
DNA yet. But there are ways to disrupt a transcription factor's function
indirectly, as opposed to directly targeting the protein itself. What
we have now from this research is a new view of the landscape and the
possibilities for drug discovery and development that are out there."
This research was supported by the Johnson & Johnson Focused
Funding Program, the Marble Fund, the American Cancer Society New
England Division-SpinOdyssey, the National Institutes of Health (NIH),
the Brain Science Foundation, the V Foundation, GlaxoSmithKline, the
National Cancer Institute (NCI), Department of Health and Human Services
(HHS), the Breast Cancer Research Foundation, and the Department of
Defense (DoD).
Journal Reference:
- Marc L. Mendillo, Sandro Santagata, Martina Koeva, George W. Bell, Rong Hu, Rulla M. Tamimi, Ernest Fraenkel, Tan A. Ince, Luke Whitesell, Susan Lindquist. HSF1 Drives a Transcriptional Program Distinct from Heat Shock to Support Highly Malignant Human Cancers. Cell, 2012; 150 (3): 549 DOI: 10.1016/j.cell.2012.06.031
Courtesy: ScienceDaily
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