Expression and DNA sequence analysis of a human embryonic skeletal muscle myosin heavy chain gene.

Vertebrate myosin heavy chains (MHC) are represented by multiple genes that are expressed in a spatially and temporally distinct pattern during development. In order to obtain molecular probes for developmentally regulated human MHC isoforms, we used monoclonal antibodies to screen an expression cDNA library constructed from primary human myotube cultures. A 3.4 kb cDNA was isolated that encodes one of the first MHCs to be transcribed in human skeletal muscle development. A portion of the corresponding gene encoding this isoform has also been isolated. Expression of this embryonic MHC is a hallmark of muscle regeneration after birth and is a characteristic marker of human muscular dystrophies. During normal human development, expression is restricted to the embryonic period of development prior to birth. In primary human muscle cell cultures, devoid of other cell types, mRNA accumulation begins as myotubes form, reaches a peak 2 days later and declines to undetectable levels within 10 days. The expression of the protein encoded by the embryonic skeletal MHC gene follows a similar time course, lagging behind the mRNA by approximately two days. Thus, expression of the human embryonic gene is efficiently induced and then repressed in cultured muscle cells, as it is in muscle tissue. The study of the regulation of a human MHC isoform with a central role in muscle development and in muscle regeneration in disease states is therefore amendable to analysis at a molecular level.     

Human embryonic myosin heavy chain cDNA. Interspecies sequence conservation of the myosin rod, chromosomal locus and isoform specific transcription of the gene

A 3.6 kilobase cDNA clone coding for the human embryonic myosin heavy chain has been isolated and characterized from an expression library prepared from human fetal skeletal muscle. The derived amino acid sequence for the entire rod part of myosin shows 97% sequence homology between human and rat and a striking interspecies sequence conservation among the charged amino acid residues. The single copy gene is localized to human chromosome 17 and its expression in fetal skeletal muscle is developmentally regulated. The sequence information permits the design of isoform-specific probes for studies on the structure of the gene and its role in normal and defective human myogenesis.     

Characterization of cDNA and genomic sequences corresponding to an embryonic myosin heavy chain

We report here the isolation and characterization of cDNA and genomic sequences corresponding to a rat embryonic myosin heavy chain (MHC) protein. This gene, which is present as a single copy in the rat genome, comprises about 25 kilobase pairs of DNA and contains approximately 80% intronic sequences. The embryonic MHC gene belongs to a highly conserved multigene family, and exhibits a high degree of nucleotide and amino acid sequence conservation with other sarcomeric MHC genes from nematode to man. S1 nuclease mapping experiments using cDNA and genomic probes show that this MHC gene is transiently expressed during skeletal muscle development. Its mRNA is detected in fetal skeletal muscle during early development and persists up to 2 weeks after birth with the overlapping expression of neonatal and adult skeletal MHC mRNAs. However, this MHC is not expressed in the adult skeletal muscle with the exception of extraocular muscle fibers. The transient expression during muscle development of the isoform produced by this gene and its sequential replacement by other MHCs raises interesting questions about the mechanism controlling MHC isozyme transitions and the physiological significance of the individual MHCs in muscle fibers.     

Nucleotide sequence and organization of full length human U4 RNA pseudogenes

Two loci encoding human U4 RNA, designated U4/7 and U4/14, have been isolated and sequenced. Both are pseudogenes in that their sequences do not match any identified human U4 RNA species perfectly. The U4/7 locus harbours a full-length pseudogene of 144 bp with eight base substitutions in the structural region. This pseudogene might be derived from a hitherto unidentified human U4 RNA gene. The second locus, U4/14, has a complex structure; the structural sequence of a U4 gene has apparently been integrated into an Alu sequence.