Researchers headed by Maria Macias an ICREA researcher at the Institute
for Research in Biomedicine (IRB Barcelona) and Joan Massagué, a Howard
Hughes Medical Institute investigator at Memorial Sloan-Kettering Cancer
Center (MSKCC) in New York, have identified a new molecular mechanism
that plays a crucial role in the control of the activation of certain
genes associated with cancer.
Through detailed structural and biochemical studies, the researchers
identified a key domain present in a family of proteins called Smads,
whose binding determines whether the transcription of genes controlled
by the TGF-beta and BMP signaling cascades will be bound by activators
or labeled for degradation. These processes are critical to the correct
development and maintenance of tissues and organisms.
When looking at inhibitory Smads , the researchers found that the
specific domain binds directly and constitutively to their targets. This
is in contrast to what happens with receptor-activated Smads, where the
proteins must first undergo processing by phosphorylation -- a chemical
change whereby the proteins are first activated and then labeled for
degradation after completing their transcriptional function. The study
appears online August 23 in the journal Structure.
Smads are key proteins in the signaling pathways of the hormones
TGF-beta and BMP, which are known to participate in the control of stem
cell pluripotency and differentiation and in the development and
maintenance of metazoan organisms. In this study, the researchers looked
at the interactions of Smad7 -- a protein inhibitor of TGF-beta
signaling -- with molecules implicated in the cascade, including three
ubiquitin ligases and YAP, a transcription coactivator. They identified
the domains in the four proteins that interact with the same region of
Smad7 and quantified these interactions in terms of affinity values.
Previous work by the groups on a similar type of protein, called
receptor-activated Smads, has shown that in order for transcription to
take place, these Smads undergo the process of phosphorylation. In this
study, which focuses on inhibitory Smads, the researchers found that
this step of molecular processing was not necessary and that the four
proteins bind constitutively and directly to the targets.
The TGF-beta pathway is tightly regulated. Its regulation includes a
feedback process whereby the two sets of Smads play complementary roles
in the same signaling cascade, as they can either inhibit or trigger
gene transcription, depending on cell type and the physiological needs
of the tissue or organism. As with most biological processes, achieving a
fine balance between the two is key, since uncontrolled gene
transcription is a hallmark of serious diseases such as cancer. This
latest discovery helps to shed light on how organisms achieve this
balance.
One of the keys to success of this project was the unique combination
of perspectives and methodologies that the partners contributed.
Macias' team at IRB Barcelona used a mixture of biophysical and
molecular biology techniques to decipher the minute structures of
subdomains within the proteins at the atomic level. "The problem," she
says, "is that we are looking at small sections of the full proteins in vitro,
isolated from their cellular environment. Using techniques such as
nuclear magnetic resonance, we are able to see the details down to the
atoms in the binding sites. But because we zoom in so closely, we can
lose sight of what the interactions we characterize can actually mean
for the function of the entire protein in the cell."
Massagué's group at MSKCC was able to take each of Macias' detailed
conformational changes and, using mammalian cells and full length
proteins, see the effects these changes had in the cells. "Merging the
detailed and bigger pictures is a difficult but key step to
understanding the nature of biological processes, and to identifying
what happens in disease," he says. "Detailed information on the
structures of molecules involved in fundamental processes, such as that
provided by this study, can tell us where to look to take to control
when things go wrong."
- Eric Aragón, Nina Goerner, Qiaoran Xi, Tiago Gomes, Sheng Gao, Joan Massagué, Maria J. Macias. Structural Basis for the Versatile Interactions of Smad7 with Regulator WW Domains in TGF-β Pathways. Structure, 2012; DOI: 10.1016/j.str.2012.07.014
Courtesy: ScienceDaily
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