Molecular basis for the unique regulation of the c-myb promoter through its E2F element.
Campanero MR, Armstrong M, Flemington E
Harvard University and Dana-Farber Cancer Institute, Boston, Massachusetts
02115, USA.
Mol Cell Biol 1999; 19:8442-8450
Abstract
Most E2F-driven promoters are transiently activated around the G(1)/S
transition. Although the promoter for the c-myb proto-oncogene harbors an
E2F element, it is induced early in G(1) following entry into the cell
cycle. Furthermore, this promoter remains active throughout subsequent cell
cycles. Since E2F sites function as repressor elements during G(1) (due to
the association of pRb with E2F factors), we investigated whether the E2F
element in the c-myb promoter is regulated differently than E2F elements in
promoters that are repressed during G(1). By gel shift analysis, the E2F
element from the c-myb promoter was found to form a unique complex, referred
to as E2Fmyb-sp, which was not observed with E2F elements from several other
promoters. Antibodies to DP-1, E2F1 to -5, p107, or pRb failed to either
supershift or block E2Fmyb-sp complex formation. Methylation interference
experiments indicate that the DNA contact residues for the E2Fmyb-sp complex
are distinct from but overlapping with residues required for the binding of
E2F proteins. In addition to the identification of E2Fmyb-sp, we have found
that SP-1 binds to the c-myb E2F element. Functional studies revealed that
E2Fmyb-sp and/or SP-1 are required to achieve full activation of the c-myb
promoter in different cell types and to maintain elevated expression of the
c-myb promoter during G(1) in NIH 3T3 cells. These studies demonstrate that
E2F elements can be regulated differently through the binding of unique sets
of proteins.