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.     

Plasma membrane Ca(2+) pump isoform 3f is weakly stimulated by calmodulin

Isoform 3f of the plasma membrane Ca(2+) pump is a major isoform of this pump in rat skeletal muscle. It has an unusual structure, with a short carboxyl-terminal regulatory region of only 33 residues when compared with the 77 to 124 residues found in the other isoforms. Also, whereas the regulatory regions of the other isoforms, downstream of the alternative splice, consist of two homologous groups, the sequence of 3f is not related to either group. A synthetic peptide representing the calmodulin binding domain of isoform 3f had a much lower calmodulin affinity (with a K(d) of 15 nM) than the corresponding peptide of isoform 2b (K(d) value was 0.2 nM). The characteristics of this domain were further studied by making chimeras of the 3f regulatory region with the catalytic core of isoform 4 and by making the full-length isoform 3f. Both constructs bound to calmodulin-Sepharose. The chimera was fully active without calmodulin, showing no stimulation of activity when calmodulin was added. The full-length isoform 3f was slightly activated by calmodulin. These data show that the regulatory region of isoform 3f is only a weak autoinhibitor of the enzyme, in contrast to the properties of all the other isoforms studied so far. Rather, this isoform is a special-purpose, constitutively active form of the enzyme, expressed primarily in skeletal muscle and as a minor isoform in brain.     

Denervation enhances the expression of SHPS-1 in rat skeletal muscle

SHPS-1 (Src homology 2 domain containing protein tyrosine phosphatase substrate 1) is a transmembrane glycoprotein containing three immunoglobulin-like motifs in its extracellular domain and immunoreceptor tyrosine-based inhibitory motifs (ITIM) that interact with SHP-2 (Src homology 2 domain containing protein tyrosine phosphatase-2) in its cytoplasmic region. SHPS-1 is highly expressed in brain, but at much lower levels in skeletal muscle. In this study, we found that the level of the SHPS-1 mRNA increases in rat skeletal muscle after denervation. Western blot analysis also confirmed the increase of SHPS-1 in denervated muscle. Moreover, it was found that the glycosylation of SHPS-1 is N-linked in a muscle-specific manner, and that this is altered upon innervation or denervation. Immunohistochemistry revealed SHPS-1 immunoreactivity at neuromuscular junctions (NMJs) under innervation, whereas immunoreactivity was observed extrasynaptically in muscle fibers after denervation. Our results indicate that the expression, glycosylation, and localization of SHPS-1 are strongly regulated by the nervous system, and that SHPS-1 may play an important role in denervated skeletal muscle.     

N-terminal amino acid sequences of three functionally different troponin T isoforms from rabbit fast skeletal muscle

The different isoforms of fast skeletal muscle troponin T (TnT) are generated by alternative splicing of several 5' exons in the fast TnT gene. In rabbit skeletal muscle this process results in three major fast TnT species, TnT1f, TnT2f and TnT3f, that differ in a region of 30 to 40 amino acid residues near the N terminus. Differential expression of these three isoforms modulates the activation of the thin filament by calcium. To establish a basis for further structure-function studies, we have sequenced the N-terminal region of these proteins. TnT2f is the fast TnT sequenced by Pearlstone et al. The larger species TnT1f contains six additional amino acid residues identical in sequence and position to those encoded by exon 4 in the rat fast skeletal muscle TnT gene. TnT3f also contains that sequence but lacks 17 amino acid residues spanning the region encoded by exons 6 and 7 of the rat gene. These three TnTs appear to be generated by discrete alternative splicing pathways, each differing by a single event. Comparison of these TnT sequences with those from chicken fast skeletal muscle and bovine heart shows that the splicing pattern resulting in the excision of exon 4 is evolutionarily conserved and leads to a more calcium-sensitive thin filament.     

Primary structure of myosin heavy chain from fast skeletal muscle of Chum salmon Oncorhynchus keta

The nucleotide sequence of the cDNA encoding myosin heavy chain of chum salmon Oncorhynchus keta fast skeletal muscle was determined. The sequence consists of 5,994 bp, including 5,814 bp of translated region deducing an amino acid sequence of 1,937 residues. The deduced sequence showed 79% homology to that of rabbit fast skeletal myosin and 84-87% homology to those of fast skeletal myosins from walleye pollack, white croaker and carp. The putative binding-sites for ATP, actin and regulatory light-chains in the subfragment-1 region of the salmon myosin showed high homology with the fish myosins (78-100% homology). However, the Loop-1 and Loop-2 showed considerably low homology (31-60%). On the other hand, the deduced sequences of subfragment-2 (533 residues) and light meromyosin (564 residues) showed 88-93% homology to the corresponding regions of the fish myosins. It becomes obvious that several specific residues of the rabbit LMM are substituted to Gly in the salmon LMM as well as the other fish LMMs. This may be involved in the structural instability of the fish myosin tail region.     

Molecular characterization of myostatin in black seabream, Acanthopagrus schlegelii.

Myostatin is a negative regulator of skeletal muscle growth and has a potential application in aquaculture. The black seabream myostatin gene was cloned and sequenced. It had three exons encoding a protein of 382 amino acids. A 90 bp 5'-untranslated region (UTR) and a 536 bp 3'-UTR were obtained by RACE. Four microsatellite sequences, a (CAG)9, a (TC)12, a (CA)16 repeat and an "imperfect" (CA)25 microsatellite, were found in the myostatin. Two introns were 329 and 742 bp in length, respectively. The deduced amino acid sequence of the myostatin had a putative amino terminal signal sequence, a TGF-beta propeptide domain, a RXXR proteolytic processing site, a TGF-beta domain, and 12 conserved cysteine residues. The myostatin gene was expressed in four of the examined ten tissues and organs. The expression of myostatin was the strongest in the skeletal muscle and brain, intermediate in the eye, and low in the heart.     

cDNA cloning of an alternative splicing variant of protein kinase C delta (PKC deltaIII), a new truncated form of PKCdelta, in rats

Recently, an alternative splicing variant of mouse protein kinase C delta (PKC deltaII, GenBank Accession No. AB011812) has been reported which has a 78 bp (26 amino acid) insertion at the caspase-3 recognition sequence in the V3 region of PKC delta (PKC deltaI). We isolated a cDNA encoding a new variant of PKC delta (PKC deltaIII, AF219629), which has a 83 bp insertion at the same site in the V3 region, by RT-PCR using rat testis RNA as a template. In rats, the 83 bp insertion causes inframe termination, and rat PKC deltaIII protein is expressed as a truncated form, having only the regulatory domain without a catalytic domain. Genomic DNA analysis revealed that the difference between mouse PKC deltaII and rat PKC deltaIII is derived from the different sequence at the 5'-splicing donor sites. To investigate the potential functions of the truncated form of PKC delta, rat PKC deltaIII fused to green fluorescent protein (GFP) was expressed in CHO-K1 cells. PKC deltaIII-GFP was localized in the cytoplasm with dot-like accumulation and highly expressed on the plasma membrane, whereas PKC deltaI-GFP is localized homogeneously throughout the cytoplasm, including the nucleoplasm. Stimulation by phorbol ester caused weak translocation of deltaIII-GFP from the cytosol to the plasma membrane. These results suggest that PKC deltaIII may show a dominant negative effect against PKC deltaI, and that the modulation of signal transduction by alternative splicing variant may play a crucial role in the physiological and/or pathological conditions, and the pathogenesis of disease.