Myostatin is a negative regulator of myogenesis, and inactivation of myostatin leads to heavy muscle growth. Here we have cloned and characterized the bovine myostatin gene promoter. Alignment of the upstream sequences shows that the myostatin promoter is highly conserved during evolution. Sequence analysis of 1.6 kb of the bovine myostatin gene upstream region revealed that it contains 10 E-box motifs (E1 to E10), arranged in three clusters, and a single MEF2 site. Deletion and mutation analysis of the myostatin gene promoter showed that out of three important E boxes (E3, E4, and E6) of the proximal cluster, E6 plays a significant role in the regulation of a reporter gene in C 2 C 12 cells. We also demonstrate by band shift and chromatin immunoprecipitation assay that the E6 E-box motif binds to MyoD in vitro and in vivo. Furthermore, cotransfection experiments indicate that among the myogenic regulatory factors, MyoD preferentially upregulates myostatin promoter activity. Since MyoD expression varies during the myoblast cell cycle, we analyzed the myostatin promoter activity in synchronized myoblasts and quiescent "reserve" cells. Our results suggest that myostatin promoter activity is relatively higher during the G 1 phase of the cell cycle, when MyoD expression levels are maximal. However, in the reserve cells, which lack MyoD expression, a significant reduction in the myostatin promoter activity is observed. Taken together, these results suggest that the myostatin gene is a downstream target gene of MyoD. Since the myostatin gene is implicated in controlling G 1 -to-S progression of myoblasts, MyoD could be triggering myoblast withdrawal from the cell cycle by regulating myostatin gene expression.Myostatin is a newly identified member of the transforming growth factor  superfamily, and myostatin-null mice have been found to show a two-to threefold increase in skeletal muscle mass due to an increase in the number of muscle fibers (hyperplasia) and the size of the fibers (hypertrophy) (21). Subsequently, we (15) and others (9, 22) reported that Belgian Blue and Piedmontese breeds of cattle, which are characterized by heavy muscling, have mutations in the myostatin gene coding sequence. Hence, myostatin is considered a negative regulator of muscle growth.Earlier studies have indicated that myostatin gene expression appears to be transcriptionally regulated during development (15, 21). Initially myostatin gene expression is detected in myogenic precursor cells of the myotome compartment of developing somites, and the expression is continued in adult axial and paraxial muscles (21). Different axial and paraxial muscles have been shown to express different levels of myostatin (15). Recent publications have shown that myostatin protein is also detected in heart (33) and mammary gland (14). In addition, myostatin is present in human skeletal muscle, and its expression is increased in the muscles of human immunodeficiency virus-infected men with muscle wasting compared to that in healthy men (8). Recently Wehling ...
