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.     

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.     

Molecular genetic characterization of a developmentally regulated human perinatal myosin heavy chain

We have isolated a human cDNA which corresponds to a developmentally regulated sarcomeric myosin heavy chain. RNA hybridization and DNA sequence analysis indicate that this cDNA, called SMHCP, encodes a perinatal myosin heavy chain isoform. The nucleotide and deduced amino acid sequences of the 3.4-kb cDNA insert show strong homology with other sarcomeric myosin heavy chains. The strongest homology is to a previously described 970-bp cDNA encoding a rat perinatal isoform (Periasamy, M., D. F. Wieczorek, and B. Nadal-Ginard. 1984. J. Biol. Chem. 259:13573-13578). The homology between the analogous human and rat perinatal myosin heavy chain cDNAs is maintained through the highly isoform-specific final 20 carboxyl-terminal amino acids, as well as the 3' untranslated region. Ribonuclease protection studies show that the mRNA encoding this isoform is expressed at high levels in 21-wk fetal skeletal tissue and not in fetal cardiac muscle. In contrast to the rat perinatal isoform, which was not found to be expressed in adult hind-leg tissue, the gene encoding SMHCP continues to be expressed in adult human skeletal tissue, but at lower levels relative to fetal skeletal tissue.     

Characterization of diverse forms of myosin heavy chain expressed in adult human skeletal muscle.

In an attempt to define myosin heavy chain (MHC) gene organization and expression in adult human skeletal muscle, we have isolated and characterized genomic sequences corresponding to different human sarcomeric MHC genes (1). In this report, we present the complete DNA sequence of two different adult human skeletal muscle MHC cDNA clones, one of which encodes the entire light meromyosin (LMM) segment of MHC and represents the longest described MHC cDNA sequence. Additionally, both clones provide new sequence data from a 228 amino acid segment of the MHC tail for which no protein or DNA sequence has been previously available. One clone encodes a "fast" form of skeletal muscle MHC while the other clone most closely resembles a MHC form described in rat cardiac ventricles. We show that the 3' untranslated region of skeletal MHC cDNAs are homologous from widely separated species as are cardiac MHC cDNAs. However, there is no homology between the 3' untranslated region of cardiac and skeletal muscle MHCs. Isotype-specific preservation of MHC 3' untranslated sequences during evolution suggests a functional role for these regions.     

Co-expression of multiple myosin heavy chain genes, in addition to a tissue-specific one, in extraocular musculature

We have investigated the developmental transitions of myosin heavy chain (MHC) gene expression in the rat extraocular musculature (EOM) at the mRNA level using S1-nuclease mapping techniques and at the protein level by polypeptide mapping and immunochemistry. We have isolated a genomic clone, designated lambda 10B3, corresponding to an MHC gene which is expressed in the EOM fibers (recti and oblique muscles) of the adult rat but not in hind limb muscles. Using cDNA and genomic probes for MHC genes expressed in skeletal (embryonic, neonatal, fast oxidative, fast glycolytic, and slow/cardiac beta-MHC), cardiac (alpha-MHC), and EOM (lambda 10B3) muscles, we demonstrate the concomitant expression at the mRNA level of at least six different MHC genes in adult EOM. Protein and immunochemical analyses confirm the presence of at least four different MHC types in EOM. Immunocytochemistry demonstrates that different myosin isozymes tend to segregate into individual myofibers, although some fibers seem to contain more than one MHC type. The results also show that the EOM fibers exhibit multiple patterns of MHC gene regulation. One set of fibers undergoes a sequence of isoform transitions similar to the one described for limb skeletal muscles, whereas other EOM myofiber populations arrest the MHC transition at the embryonic, neonatal/adult, or adult EOM-specific stage. Thus, the MHC gene family is not under the control of a strict developmental clock, but the individual genes can modify their expression by tissue-specific and/or environmental factors.     

Regulation of myosin heavy-chain gene expression during skeletal-muscle hypertrophy.

Changes in the myosin phenotype of differentiated muscle are a prominent feature of the adaptation of the tissue to a variety of physiological stimuli. In the present study the molecular basis of changes in the proportion of myosin isoenzymes in rat skeletal muscle which occur during compensatory hypertrophy caused by the combined removal of synergist muscles and spontaneous running exercise was investigated. The relative amounts of sarcomeric myosin heavy (MHC)- and light (MLC)-chain mRNAs in the plantaris (fast) and soleus (slow) muscles from rats was assessed with cDNA probes specific for different MHC and MLC genes. Changes in the proportion of specific MHC mRNA levels were in the same direction as, and of similar magnitude to, changes in the proportion of myosin isoenzymes encoded for by the mRNAs. No significant changes in the proportion of MLC proteins or mRNA were detected. However, high levels of MLC3 mRNA were measured in both normal and hypertrophied soleus muscles which contained only trace amounts of MLC3 protein. Small amounts of embryonic and neonatal MHC mRNAs were induced in both muscles during hypertrophy. We conclude that the change in the pattern of myosin isoenzymes during skeletal-muscle adaptation to work overload is a consequence of changes in specific MHC mRNA levels.     

Analysis of the tissue-specific expression, developmental regulation, and linkage relationships of a rodent gene encoding heart fatty acid binding protein

The rat contains at least three homologous cytosolic proteins that bind long chain fatty acids, termed liver (L-), intestinal (I-), and heart (H-) fatty acid binding protein (FABP). I-FABP mRNA is confined to the gastrointestinal tract while L-FABP mRNA is abundantly represented in hepatocytes as well as enterocytes. We have isolated a rat heart FABP cDNA clone and determined the pattern of H-FABP mRNA accumulation in a wide variety of tissues harvested from late fetal, suckling, weaning, and adult rats. RNA blot hybridizations and primer extension analysis disclosed that the distribution of H-FABP mRNA in adult rat tissues is different from that of I- or L-FABP mRNA. H-FABP mRNA is most abundant in adult heart. This mRNA was also present in an adult slow twitch (type I) skeletal muscle (soleus, 63% of the concentration in heart), testes (28%), a fast twitch skeletal muscle (psoas, 17%), brain (10%), kidney (5%), and adrenal gland (5%). H-FABP mRNA was not detected in adult small intestine, colon, spleen, lung, or liver RNA. Distinct patterns of developmental change in H-FABP mRNA accumulation were documented in heart, placenta, brain, kidney, and testes. Myocardial H-FABP mRNA levels rise rapidly during the 48 h prior to and after birth, reaching peak levels by the early weaning period. The postnatal increase in myocardial H-FABP mRNA concentration and its relative distribution in adult fast and slow twitch skeletal muscle are consistent with its previously proposed function in facilitating mitochondrial beta-oxidation of fatty acids. However, the presence of H-FABP mRNA in brain, a tissue which does not normally significantly oxidize fatty acids in late postnatal life, suggests that H-FABP may play a wider role in fatty acid metabolism than previously realized. Mouse-hamster somatic cell hybrids were utilized to map H-FABP. Using stringencies which did not produce cross-hybridization between L-, I-, and H-FABP DNA sequences, we found at least three loci in the mouse genome, each located on different chromosomes, which reacted with our cloned H-FABP cDNA. None of these H-FABP-related loci were linked to the gene which specifies a highly homologous adipocyte-specific protein termed aP2 or to genes encoding two other members of this protein family, cellular retinol binding protein and cellular retinol binding protein II.(ABSTRACT TRUNCATED AT 400 WORDS)     

Establishment of cell lines from somite stage mouse embryos and expression of major histocompatibility class I genes in these cells

To study the regulation of MHC class I gene expression during embryonic development, we have characterized a number of clonal cell lines derived from somite stage mouse embryos that were established with or without infection by several transforming retroviruses in combination with murine leukemia viruses. Unlike embryonal carcinoma (EC) cells that have been used as a model for early embryos, the cell lines derived from somite stage embryos are negative for stage specific embryonic Ag-1 and do not appear to differentiate after retinoic acid treatment. Morphology varies from clone to clone and is distinct from that of F9 and other EC cells. In agreement with previous findings in in vivo embryos, expression of surface MHC class I antigen in 57 new clones is either undetectable or low (with variability). All of the clones respond to the addition of interferons and express MHC class I antigens at high levels, but the kinetics of mRNA accumulation vary considerably. To examine the basis of the generally low or absent MHC class I gene expression in these cells, we tested promoter activity of a MHC class I gene by CAT assay after transient DNA transfection. Regardless of the basal levels of mRNA or surface Ag, CAT activity directed by various portions of the 5' flanking region of the MHC class I gene was uniformly low. The cells showed neither the negative nor the positive regulation of MHC class I genes that had been noted respectively for EC cells and for cells expressing the Ag constitutively. The pattern seen in the new cell lines suggests that there is an intermediate stage in the developmental regulation of MHC class I gene expression that may operate during the middle to late stage of fetal development.     

Cloning and sequencing of myosin heavy chain isoform cDNAs in golden-mantled ground squirrels: effects of hibernation on mRNA expression.

The golden-mantled ground squirrel is a small rodent hibernator that demonstrates unusual myosin heavy chain (MHC) isoform plasticity during several months of torpor, punctuated by bouts of rewarming and shivering thermogenesis. We measured MHC mRNA levels to determine whether pretranslational control mechanisms were responsible for differences in MHC2x protein expression, as we previously observed between active and hibernating ground squirrels. We first cloned cDNA using the 3' rapid amplification of cDNA ends (3' RACE) technique and identified three sequences corresponding to MHC1, MHC2x, and MHC2b. A DNA control fragment was developed to be used in conjunction with a coupled RT-PCR reaction to simultaneously measure MHC mRNA levels for each isoform in the skeletal muscle of ground squirrels. MHC mRNA and protein expression were strongly correlated, and type IIx and IIb mRNA levels were significantly different between active and hibernating ground squirrels. Pretranslational control of MHC protein is apparently an important process during hibernation, although the exact stimulus is not known. The techniques presented can be used to obtain MHC cDNA sequences and to measure mRNA expression in many vertebrate groups.     

Discovery of new human beta-defensins using a genomics-based approach

Epithelial beta-defensins are broad-spectrum cationic antimicrobial peptides that also act as chemokines for adaptive immune cells. In the human genome, all known defensin genes cluster to a <1 Mb region of chromosome 8p22-p23. To identify new defensin genes, the DNA sequence from a contig of large-insert genomic clones from the region containing human beta-defensin-2 (HBD-2) was analyzed for the presence of defensin genes. This sequence survey identified a novel beta-defensin, termed HBD-3. The HBD-3 gene contains two exons, is located 13 kb upstream from the HBD-2 gene, and it is transcribed in the same direction. A partial HBD-3 cDNA clone was amplified from cDNA derived from IL-1beta induced fetal lung tissue. The cDNA sequence encodes for a 67 amino acid peptide that is approximately 43% identical to HBD-2 and shares the beta-defensin six cysteine motif. By PCR analysis of two commercial cDNA panels, HBD-3 expression was detected in adult heart, skeletal muscle, placenta and in fetal thymus. From RT-PCR experiments, HBD-3 expression was observed in skin, esophagus, gingival keratinocytes, placenta and trachea. Furthermore, in fetal lung explants and gingival keratinocytes, HBD-3 mRNA expression was induced by IL-1beta. Additional sequence analysis identified the HE2 (human epididymis secretory protein) gene 17 kb upstream from the HBD-3 gene. One splice variant of this gene (HE2beta1) encodes a beta-defensin consensus cysteine motif, suggesting it represents a defensin gene product. HE2beta1 mRNA expression was detected in gingival keratinocytes and bronchial epithelia using RT-PCR analysis. The discovery of these novel beta-defensin genes may allow further understanding of the role of defensins in host immunity at mucosal surfaces.