Abstract. The myosin light chain 1F/3F locus contains two independent promoters, MLC1F and MLC3F, which are differentially activated during skeletal muscle development. Transcription at this locus is regulated by a 3' skeletal muscle enhancer element, which directs correct temporal and tissuespecific expression from the MLC1F promoter in transgenic mice. To investigate the role of this enhancer in regulation of the MLC3F promoter in vivo, we have analyzed reporter gene expression in transgenic mice containing lacZ under transcriptional control of the mouse MLC3F promoter and 3' enhancer element. Our results show that these regulatory elements direct strong expression of lacZ in skeletal muscle; the transgene, however, is activated 4-5 d before the endogenous MLC3F promoter, at the time of initiation of MLC1F transcription. In adult mice, transgene activity is downregulated in muscles that have reduced contributions of type 1/13 fibers (soleus and diaphragm). The rostrocaudal positional gradient of transgene expression documented for MLC1F transgenic mice (Donoghue, M., J. P. Merlie, N. Rosenthai, and J. R. Sanes. 1991. Proc. Natl. Acad. Sci. USA. 88:5847-5851) is not seen in MLC3F transgenic mice. Although MLC3F was previously thought to be restricted to skeletal striated muscle, the MLC3F-lacZ transgene is expressed in cardiac muscle from 7.5 d of development in a spatially restricted manner in the atria and left ventricular compartments, suggesting that transcriptional differences exist between cardiomyocytes in left and right compartments of the heart. We show here that transgene-directed expression of the MLC3F promoter reflects low level expression of endogenous MLC3F transcripts in the mouse heart. URING striated muscle development, a dynamic and complex pattern of structural gene expression generates the diversity of muscle types found in the adult vertebrate. Regulation of the majority of sarcomeric genes is under transcriptional control mediated by several families of regulatory proteins, including those of the MyoD and MEF2 transcription factors (Weintraub, 1993;Yu et al., 1992). Through interactions with cis-acfing regulatory elements, these factors ensure the expression of specific genes whose products are required in particular subsets of cardiac and skeletal musculature. A large number of muscle-specific promoter and enhancer elements have been identified as important in tissue culture (see Rosenthal, 1989); dissection, however, of the complex spatial and temporal control of muscle-specific gene expression in vivo, which is not recapitulated in vitro, requires direct analysis of putative regulatory regions in transgenic mice. Transgenic studies have demonstrated the complexity of cis-acflng elements controlling the expression of particular muscle-specific genes in different striated muscle types, for example, the Address correspondence to M. Buckingham, CNRS URA 1947,
