MEF-2 and Oct-1 bind to two homologous promoter sequence elements and participate in the expression of a skeletal muscle-specific gene.

The murine adult IIB myosin heavy chain (IIB MyHC) gene is expressed only in certain skeletal muscle fibers. Within the proximal promoter are two A + T-rich motifs, mAT1 and mAT2, which greatly enhance muscle-specific transcription; myogenic cells contain proteins that bind to these sequences. MEF-2 binds to both mAT1 and mAT2; a mutation abolishing its binding to mAT1 greatly diminishes the activity of the promoter. Both mAT motifs also form complexes with a protein requiring a target sequence typical of POU domain proteins, which migrate in electrophoretic mobility shift assays to the same position as a complex containing purified Oct-1 and which are supershifted by an antibody specific to Oct-1; this protein is therefore probably Oct-1. Footprinting experiments demonstrate that mAT1 is preferentially occupied by MEF-2 and mAT2 by Oct-1 and that these two proteins appear to bind cooperatively to their respective sites. Although the two mAT motifs have sequences that are very similar, they nonetheless exhibit distinct behaviors and perform differently in the activation of the promoter. The contribution of the IIB MyHC gene to specification of the myogenic phenotype is thus at least in part regulated by MEF-2 and Oct-1.

Myogenic regulatory factors can activate TATA-containing promoter elements via an E-box independent mechanism.

We have studied the effect of several myogenic regulatory factors on the activity of the promoter for a mouse gene encoding a skeletal myosin heavy chain (MyHC) expressed in adult (type IIB) muscle fibers. Co-transfection of myogenic factors is necessary for activity of the IIB promoter in mouse C2 myotubes in culture but not in quail myotubes in culture. Although this promoter contains one E-box within the first 192 base pairs upstream of the transcriptional start site, mutations in this motif demonstrate that it is not required for the transactivation effect of the myogenic factors. Analysis of other mutants suggests that the MEF2 and MHox DNA-binding factor binds to an evolutionarily conserved AT-rich motif. In addition, the IIB promoter appears to require the conserved TATA motif (CTATAAAAG) in order to be activated by the AT-rich sequences. The IIB promoter constructs produce RNA transcripts which begin at the natural site of transcriptional initiation in quail myotubes and in mouse C2 myotubes after co-transfection with myogenic factors; a second, minor, start site is also used in the co-transfected C2 myotubes. Results obtained after transfection of the mouse IIB promoter constructs in quail myotube cultures suggest that the overexpression of myogenic factors in C2 cultures does not result in an environment in which the control of IIB MyHC promoter activity is aberrant. Therefore, either the myogenic factors themselves, or other proteins induced by them, seem to interact directly with the basal transcription seem to interact directly with the basal transcription machinery to allow muscle-specific gene expression.

A possible regulatory role for conserved promoter motifs in an adult-specific muscle myosin gene from mouse.

The mouse gene encoding a myosin heavy chain (MHC) protein expressed in type IIB fibers of adult skeletal muscle has been cloned and its promoter isolated. A number of DNA sequence motifs are found within the first 2.5 kilobases of the promoter which are similar to motifs present in the promoters of other muscle-specific genes. One sequence located at approximately -940 base pairs corresponds to the motif called MEF1 which has been shown in other muscle genes to bind the myogenic regulatory factors of which MyoD is one example. The MEF1 site of this adult IIB MHC promoter does indeed bind MyoD although this factor is normally thought to be involved in early muscle cell differentiation. The IIB MHC promoter also has several motifs located in the first 200 base pairs which are strikingly conserved between this mouse gene and several chicken skeletal MHC genes. Of these evolutionarily conserved sequences, two motifs rich in A and T residues appear to be major contributors to the muscle-specific transcriptional activity of the mouse IIB MHC promoter when transfected into quail myogenic and non-myogenic cells. These observations suggest an important functional role for these AT-rich sequence motifs in the regulation of genes of the MHC family.

Evolutionarily conserved promoter motifs and enhancer organization in the mouse gene encoding the IIB myosin heavy chain isoform expressed in adult fast skeletal muscle.

We have isolated the mouse gene for the MHC isoform expressed in adult type IIB (fast-contracting, glycolytic) skeletal muscle fibers, and determined the DNA sequence of the promoter region. This sequence represents the first example of a promoter for a gene encoding an adult-specific isoform of a mammalian skeletal MHC. The proximal 200 bp of the promoter contains several sequence motifs which are identical or very similar to homologous motifs found in the promoters of a family of chicken skeletal MHC genes. Of these, two novel AT-rich sequences may be important for regulation of the promoter. A second feature of the mouse IIB MHC promoter sequence concerns a number of sequence motifs located at ca. -1,000 bp which are organized in a similar fashion in the IIB MHC promoter and a homologous region of promoter of the mouse muscle creatine kinase gene.