Multiple 5'-flanking regions of the human alpha-skeletal actin gene synergistically modulate muscle-specific expression.

Transfection into myogenic and nonmyogenic cell lines was used to investigate the transcriptional regulation of the human alpha-skeletal actin gene. We demonstrated that 1,300 base pairs of the 5'-flanking region directed high-level transient expression of the bacterial chloramphenicol acetyltransferase gene in differentiated mouse C2C12 and rat L8 myotubes but not in mouse nonmuscle L.TK- and HuT-12 cells. Unidirectional 5' deletion analysis and heterologous promoter stimulation experiments demonstrated that at least three transcription-regulating subdomains lie in this 1,300-base-pair region. A proximal cis-acting transcriptional element located between positions -153 and -87 relative to the start of transcription at +1 was both sufficient and necessary for muscle-specific expression and developmental regulation during myogenesis in the two myogenic cell systems. The region 3' of position -87 interacted with factors present in both myogenic and fibroblastic cells and appeared to define, or to be a major component of, the basal promoter. In C2C12 myotubes, but not in L8 myotubes, a distal sequence domain between positions -1300 and -626 and the proximal sequence domain between positions -153 and -87 each induced transcription about 10-fold and synergistically increased CAT expression 100-fold over levels achieved by the sequences 3' of position -87. Furthermore, these cis-acting elements independently and synergistically modulated an enhancerless, heterologous simian virus 40 promoter in a tissue-specific manner. DNA fragments which included the proximal domain displayed classical enhancerlike properties. The central region between positions -626 and -153, although required in neither cell line, had a positive, two- to threefold, additive role in augmenting expression in L8 cells but not in C2C12 cells. This suggests that certain elements between positions -1300 and -153 appear to be differentially utilized for maximal expression in different myogenic cells and that the particular combination of domains used is dependent on the availability, in kind or amount, of trans-acting, transcription-modulating factors present in each cell type. Thus, multiple myogenic factors that vary qualitatively and quantitatively may be responsible for the different and complex modulatory programs of actin gene expression observed during in vivo muscle differentiation.