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(Received for publication, September 11, 1995; and in revised form, December 28, 1995) Terminal differentiation of muscle cells results in opposite
effects on gene promoters: muscle-specific promoters, which are
repressed during active proliferation of myoblasts, are turned on,
whereas at least some proliferation-associated promoters, such as
c-fos, which are active during cell division, are turned off.
MyoD and myogenin, transcription factors from the
basic-helix-loop-helix (bHLH) family, are involved in both processes,
up-regulating muscle genes and down-regulating c-fos. On the
other hand, the serum response factor (SRF) is involved in the
activation of muscle-specific genes, such as c-fos, as well as
in the up-regulation of a subset of genes that are responsive to
mitogens. Upon terminal differentiation, the activity of these various
transcription factors could be modulated by the formation of distinct
protein-protein complexes. Here, we have investigated the hypothesis
that the function of SRF and/or MyoD and myogenin could be modulated by
a physical association between these transcription factors. We show
that myogenin from differentiating myoblasts specifically binds to SRF. In vitro analysis, using the glutathione S-transferase pull-down assay, indicates that SRF-myogenin
interactions occur only with myogenin-E12 heterodimers and not with
isolated myogenin. A physical interaction between myogenin, E12, and
SRF could also be demonstrated in vivo using a triple-hybrid
approach in yeast. Glutathione S-transferase pull-down
analysis of various mutants of the proteins demonstrated that the bHLH
domain of myogenin and that of E12 were necessary and sufficient for
the interaction to be observed. Specific binding to SRF was also seen
with MyoD. In contrast, Id, a natural inhibitor of myogenic bHLH
proteins, did not bind SRF in any of the situations tested. These data
suggest that SRF, on one hand, and myogenic bHLH, on the other, could
modulate each other's activity through the formation of a
heterotrimeric complex.
Volume 271,
Number 9,
Issue of March 1, 1996 pp. 5258-5264
©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
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