Regulated expression of repetitive sequences including the identifier sequence during myotube formation in culture.

We have isolated and characterized a cDNA of 1183 bp, pL6-411, from rat L6 muscle cells. This cDNA contains repetitive sequences - including two inverted copies of the previously described identifier sequence - as shown by sequence analysis. Repetitive sequences from pL6-411 characterize a family of RNAs which is specifically induced during L6 myotube formation. Another part of the pL6-411 sequence, existing at low-copy number per haploid rat genome, hybridized to two RNAs of 5 kb and 2 kb from L6 myoblasts as well as from L6 myotubes. A third pL6-411-related RNA of 150 bases was detected which hybridized with the repetitive sequence but did not hybridize with the low-copy number part of pL6-411. It appears that the 'identifier' sequence in this population of small RNAs is complementary to one of the 'identifier' copies in the pL6-411-related RNA. Finally, we identified on cDNA pL6-411 the recognition site for the TGGCA-binding protein and in both orientations a total of four putative promoters for RNA polymerase III.     

Relationship between single-stranded DNA isolated from cultured muscular cells during differentiation and the transcription of messenger RNA.

Single-stranded DNA (ssDNA), equivalent to about 2% of the total nuclear DNA, was isolated by an improved method of hydroxyapatite chromatography from native nuclear DNA of rat myoblast cells and myotubes of the L6 line. Small quantities of 125I-labelled ssDNA were annealed with a large excess of unlabelled DNA, cytoplasmic RNA and mRNA from myoblasts or myotubes. The results indicated that ssDNA belongs to the non-repetitious portion of the cell genome and is formed of two distinct molecular fractions. The major ssDNA fractions (75%) consist of non-self-reassociating DNA sequences and the minor fraction (25%) consists of self-reassociating DNA sequences. About 30--32% and 25--26% of ssDNA from myoblast represent DNA sequences complementary to total cytplasmic RNAs and polyadenylated RNAs respectively. Hybridizations of ssDNA with an excess of RNA from myoblasts and/or myotubes show differences in the abundance and the diversity of mRNA during mascular differentiation. These differences were confirmed by DNA-driven reactions between 125I-labelled polyadenylated RNA and ssDNA in great excess.     

Regulated expression of nuclear protein(s) in myogenic cells that binds to a conserved 3'' untranslated region in pro alpha 1 (I) collagen cDNA.

We describe the identification and DNA-binding properties of nuclear proteins from rat L6 myoblasts which recognize an interspecies conserved 3' untranslated segment of pro alpha 1 (I) collagen cDNA. Levels of the two pro alpha 1 (I) collagen RNAs, present in L6 myoblasts, decreased drastically between 54 and 75 h after induction of myotube formation in serum-free medium. Both mRNAs contained a conserved sequence segment of 135 nucleotides (termed tame sequence) in the 3' untranslated region that had 96% homology to the human and murine pro alpha 1 (I) collagen genes. The cDNA of this tame sequence was specifically recognized by nuclear protein(s) from L6 myoblasts, as judged by gel retardation assays and DNase I footprints. The tame-binding protein(s) was able to recognize its target sequence on double-stranded DNA but bound also to the appropriate single-stranded oligonucleotide. Protein that bound to the tame sequence was undetectable in nuclear extracts of L6 myotubes that did not accumulate the two collagen mRNAs. Therefore, the activity of this nuclear protein seems to be linked to accumulation of the sequences that it recognizes in vitro. The collagen RNAs and the nuclear tame-binding proteins reappeared after a change of medium, which further suggests that the RNAs and the protein(s) are coordinately regulated.     

The multiple ADP/ATP translocase genes are differentially expressed during human muscle development.

The expression of the genes encoding the three isoforms of the human ADP/ATP translocase (T1, T2, and T3) has been analyzed at different stages of myogenic differentiation in an in vitro muscle cell system and compared with that in mature muscle. The results indicate that the three stages of muscle differentiation corresponding to myoblast proliferation, myotube formation, and mature muscle fibers are characterized by a different pattern of expression of the ADP/ATP translocase genes. In particular, the two T2-specific mRNAs are present at high, similar levels in myoblasts and myotubes and markedly decrease in amount in mature adult muscle. By contrast, the T3-specific mRNA is present in high amount in growing myoblasts, decreases markedly in myotubes, and is barely detectable in adult muscle. Finally, the T1-specific mRNA is present at a high level in adult muscle and is not detectable in either myoblasts or myotubes. Therefore, T1 gene expression appears to be a marker of a late stage in myogenesis. A parallel investigation of expression of the myosin heavy chain mRNA revealed absence of hybridization with the specific probe in RNA from proliferating myoblasts, a significant hybridization in myotube RNA, and a strong signal in adult muscle RNA.     

Translation of an mRNA in rat L6 muscle cells is regulated within the cell cycle

In muscle cells two populations of mRNA are present in the cytoplasm. The majority of mRNA is associated with ribosomes and active in protein synthesis. A small population of cytoplasmic mRNA occur as free mRNA-protein complex and is not associated with ribosomes. This apparently repressed population of mRNA from rat L6 myoblast cells was used to construct a cDNA library. Radioactively labeled cDNA preparations of polysomal and free (or repressed) mRNA populations showed that at least ten recombinant clones preferentially annealed to the cDNA from repressed mRNA. One of these clones was extensively studied. The DNA from a recombinant plasmid D12 hybridized to a 1.3-kb poly(A)-rich mRNA. In proliferating myoblast cells, the 1.3-kb mRNA was more abundant in the polysomal fraction and mostly free in the non-dividing myotubes. In contrast to this mRNA, 90% of alpha and beta actin mRNAs were translated in both myoblasts and myotubes. Further analysis of distribution of the 1.3-kb RNA in the polysomal (active) and free (repressed) fractions in fusion-arrested postmitotic myotubes suggested that fusion of myoblasts was not necessary for the control of translation of this mRNA. Withdrawal of muscle cells from the cell cycle appeared to be involved in regulating translation of this mRNA. The presence of this mRNA was not, however, limited to muscle cells. This mRNA was also present in the repressed state in rat liver and kidney cells. These results, therefore, suggest that the 1.3-kb mRNA is probably translated during a particular phase of the cell cycle and is not translated in terminally differentiated non-dividing cells. Messenger RNA homologous to the 600-base-pair insert of the recombinant plasmid D12 was isolated by hybrid selection procedure from both polysomal mRNA of myoblasts and free mRNA of myotubes. Translation of the hybrid selected mRNAs from both myoblasts and myotubes in rabbit reticulocyte lysate cell-free system synthesized a 40-kDa polypeptide. These results suggest that the repressed population of 1.3-kb mRNA can be translated in vitro. The hybridization pattern of DNA from the recombinant plasmid D12 with rat genomic DNA suggested that the 1.3-kb mRNA is derived from moderately repetitive rat DNA with a repetition frequency of approximately 100 copies per haploid genome.     

Cellular titers and subcellular distributions of abundant polyadenylate-containing ribonucleic acid species during early development in the frog Xenopus laevis.

The distribution of cytoplasmic messenger ribonucleic acids (RNAs) in translationally active polysomes and inactive ribonucleoprotein particles changes during early development. Cellular levels and subcellular distributions have been determined for most messenger RNAs, but little is known about how individual sequences change. In this study, we used hybridization techniques with cloned sequences to measure the titers of 23 mitochondrial and non-mitochondrial polyadenylate-containing [poly(A)+]RNA species during early development in the frog Xenopus laevis. These RNA species were some of the most abundant cellular poly(A)+ RNA species in early embryos. The concentrations of most of the non-mitochondrial (cytoplasmic) RNAs remained constant in embryos during the first 10 h of development, although the concentrations of a few species increased. During neurulation, we detected several new poly(A)+ RNA sequences in polysomes, and with one possible exception the accumulation of these sequences was largely the result of new synthesis or de novo polyadenylation and not due to the recruitment of nonpolysomal (free ribonucleoprotein) poly(A)+ RNA. We measured the subcellular distributions of these RNA species in polysomes and free ribonucleoproteins during early development. In gastrulae, non-mitochondrial RNAs were distributed differentially between the two cell fractions; some RNA species were represented more in free ribonucleoproteins, and others were represented less. By the neurula stage this differential distribution in polysomes and free ribonucleoproteins was less pronounced, and we found species almost entirely in polysomes. Some poly(A)+ RNA species transcribed from the mitochondrial genome were localized within the mitochondria and were mapped to discrete fragments of the mitochondrial genome. Much of this poly(A)+ RNA was transcribed from the ribosomal locus. Nonribosomal mitochondrial poly(A)+ RNA species became enriched in polysome-like structures after fertilization, with time courses similar to the time course of mobilization of cytoplasmic poly(A)+ RNA.     

Transient induction of poly(A)-short myosin heavy chain messenger RNA during terminal differentiation of L6E9 myoblasts

The rat myoblast L₆E₉ cell line under appropriate culture conditions is a uniform population of cycling cells which can be induced to differentiate into a pure population of myotubes. The pattern and kinetics of myogenic differentiation of this cell line are similar to those of primary skeletal muscle myoblasts. We have used this cell line to investigate the controls regulating the synthesis and accumulation of myosin heavy chain during myogenic development. From pulse labeling studies of total cellular protein synthesis, we observed that activation of MHC⁴ synthesis is temporally correlated with cell fusion and myotube formation. MHC synthesis is transiently induced from <1% up to 25% of the total protein synthesized. After MHC has accumulated to the steady-state level characteristic of fully differentiated myotubes, MHC synthesis decreases very rapidly to almost basal levels. To determine whether this transient induction of MHC synthesis was due to parallel changes in MHC messenger RNA levels, the accumulation and compartmentalization of MHC mRNA during L₆E₉ cell differentiation was followed by complementary DNA/RNA hybridization using cDNA prepared against MHC mRNA purified from L₆E₉ cells. We demonstrate that the level of MHC synthesis closely parallels the level of cytoplasmic MHC mRNA. The induction of MHC mRNA accumulation is initiated at least 36 hours prior to cell fusion and at a time when all cells in the population are still uncommitted to terminal differentiation as tested by cell cloning. The level of cytoplasmic MHC mRNA is increased from ~200 molecules per cell in the growing state to ~50,000 molecules at the peak of induction (day 6 after plating). Subsequently the levels of MHC mRNA decrease very rapidly and at day 10 after plating there are only ~3000 molecules per myotube nucleus. A striking feature of this regulation is the behavior of MHC mRNA on oligo(dT) columns. Most (~90%) of the MHC mRNA transiently induced during differentiation has a very short poly(A) tail (<20 nucleotides). We conclude that the striking induction followed by deinduction of MHC synthesis is controlled primarily by the induction and deinduction of cytoplasmic MHC mRNA accumulation. The relationship of our observations to muscle physiology is discussed.     

Molecular cloning and nucleotide sequence of a human renin cDNA fragment.

We have studied human renin messenger RNA by hybridization with the mouse submaxillary gland (SMG) renin cDNA probe. The human kidney messenger RNA is about 1.6 kilobase (kb) long, similarly to the mouse SMG renin mRNA. A kidney renin cDNA clone of 1.1 kb length was obtained. A comparison of nucleotide sequences of mouse and human cDNA clones reveals conservation of residues involved in catalytic mechanisms and a potential glycosylation site. The human renin molecular probe allowed us to study renin expression in human chorionic tissue. The chorionic and kidney renin messenger RNAs are similar in length. The Southern blot analysis reveals the presence of a single renin gene in human DNA.     

Identification of a high molecular weight presumptive precursor to albumin mRNA in the nucleus of rat liver and hepatoma cell line H4AZC2.

Nuclear RNAs prepared from rat liver and rat hepatoma cell line H4AZC2 have been fractionated and examined for albumin mRNA sequences by annealing to specific albumin [3H]cDNA. In both instances, sucrose gradient analysis revealed nuclear RNA molecules containing albumin RNA sequences which sedimented at 26 S (26 S albumin RNA). In contrast, cytoplasmic albumin messenger RNA sediments exclusively at 17 S. 26 S albumin RNA is resistant to both heat denaturation (65 degrees C X 5 min) and denaturation in 85% formamide (v/v), and 75% of these molecules are polyadenylated. These results provide evidence for the existence of an intact, high molecular weight, polyadenylated nuclear RNA which contains albumin mRNA sequences.     

New Method of Studying the Precursor-product Relationship between High Molecular Weight RNA and Messenger RNA

THREE principal methods have been used to test whether giant heterogeneous RNA is a precursor to cytoplasmic messenger RNA in animal cells. First, competition-hybridization to DNA has shown that there is certainly a degree of similarity between the two types of molecule^1–5. The conditions used in most of these experiments allowed only the hybridization of the reiterated fraction of DNA or RNA. It is possible therefore that the competing sequences are similar, but not identical and in any case may represent only a small fraction of the total sequences. Scherrer et al.⁶, using conditions which might allow the hybridization of some of the slow sequences of DNA and which would give meaningful competition, conclude that there is a precursor-product relationship between giant heterogeneous RNA and cytoplasmic messenger RNA. Darnell, following the uptake of labelled nucleotides into the two fractions⁷, has shown that a precursor product relationship is possible although not proven. Third, the differential inhibition of synthesis of the two fractions by cordycepin⁸ has been taken to show that the giant heterogeneous RNA cannot be a precursor to the cytoplasmic messenger RNAs. Although these data would confirm previous observations on the rate of uptake and decay of label in nucleoplasmic and cytoplasmic RNA in the presence of actinomycin⁹, this type of experiment is rather indirect and open to other interpretations because the inhibitors might not act exclusively and directly on one step of the overall metabolic pathway. A relationship has been clearly established between high molecular weight precursors and the final RNA produced only for SV40 transformed cells¹⁰. In this case the hybridization experiments were much simplified because SV40 DNA, which is very small in comparison with animal DNA, is readily available. In this communication we describe a direct and general way of approaching the problem which makes novel use of molecular hybridization and can be applied to messenger RNAs which are not easily labelled. The method also overcomes the difficulty of hybridizing to the extremely complex DNA of higher organisms.     

Myoblast proliferation and syncytial fusion both depend on connexin43 function in transfected skeletal muscle primary cultures

Muscles are formed by fusion of individual postmitotic myoblasts to form multinucleated syncytial myotubes. The process requires a well-coordinated transition from proliferation, through migratory alignment and cycle exit, to breakdown of apposed membranes. Connexin43 protein and cell-cycle inhibitor levels are correlated, and gap junction blockers can delay muscle regeneration, so a coordinating role for gap junctions has been proposed. Here, wild-type and dominant-negative connexin43 variants (wtCx43, dnCx43) were introduced into rat myoblasts in primary culture through pIRES-eGFP constructs that made transfected cells fluoresce. GFP-positive cells and vitally-stained nuclei were counted on successive days to reveal differences in proliferation, and myotubes were counted to reveal differences in fusion. Individual transfected cells were injected with Cascade Blue, which permeates gap junctions, mixed with FITC-dextran, which requires cytoplasmic continuity to enter neighbouring cells. Myoblasts transfected with wtCx43 showed more gap-junctional coupling than GFP-only controls, began fusion sooner as judged by the incidence of cytoplasmic coupling, and formed more myotubes. Myoblasts transfected with dnCx43 remained proliferative for longer than either GFP-only or wtCx43 myoblasts, showed less coupling, and underwent little fusion into myotubes. These results highlight the critical role of gap-junctional coupling in myotube formation.     

The origin of secondary myotubes in mammalian skeletal muscles: ultrastructural studies

The distribution of secondary myotubes and undifferentiated mononucleated cells (presumed to be myoblasts) within foetal IVth lumbrical muscles of the rat was analyzed with serial section electron microscopy. In all myotube clusters for which the innervation zone was located, every secondary myotube overlapped the end-plate region of the primary myotube. No secondary myotubes were ever demonstrated to occur at a distance from the primary myotube innervation zone. This indicates that new secondary myotubes begin to form only in the innervation zone of the muscle. Some young secondary myotubes made direct contact with a nerve terminal, but we cannot say if this is true for all developing secondary myotubes. Myoblasts were not clustered near the innervation zone, but were uniformly distributed throughout the muscle. Myoblasts were frequently interposed between a primary and a secondary myotube, in equally close proximity to both cell membranes. We conclude that specificity in myoblast-myotube fusion does not depend on restrictions in the physical distribution of myoblasts within the muscle, and therefore must reflect more subtle mechanisms for intercellular recognition.     

Isolation of myosin-synthesizing polysomes from cultures of embryonic chicken myoblasts before fusion.

Mononucleated myoblasts and multinucleated myotubes were obtained by culturing embryonic chicken skeletal muscle cells. Comparison of total polysomes isolated from these mononucleated and multinucleated cell cultures by density gradient centrifugation and electron microscopy revealed that mononucleated myoblasts contain polysomes similar to those contained by multinucleated myotubes and large enough to synthesize the 200,000-dalton subunit of myosin. When placed in an in vitro protein-synthesizing assay containing [³H]leucine, total polysomes from both mononucleated and multinucleated myogenic cultures were active in synthesizing polypeptides indistinguishable from myosin heavy chains as detected by measurement of radioactivity in slices through the myosin band on sodium dodecyl sulfate (SDS)-polyacrylamide gels. Fractionation of total polysomes on sucrose density gradients showed that myosin-synthesizing polysomes from mononucleated myoblasts may be slightly smaller than myosin-synthesizing polysomes from myotubes. Multinucleated myotubes contain approximately two times more myosin-synthesizing polysomes per unit of DNA than mononucleated myoblasts, and the proportion of total polysomes constituted by myosin polysomes is only 1.2 times higher in multinucleated myotubes than it is in mononucleated myoblasts. The results of this study suggest that mononucleated myoblasts contain significant amounts of myosin messenger RNA before the burst of myosin synthesis that accompanies muscle differentiation and that a portion of this messenger RNA is associated with ribosomes to form polysomes that will actively translate myosin heavy chains in an in vitro protein-synthesizing assay.     

Regulation of tropomyosin gene expression during myogenesis.

In skeletal muscle, tropomyosin has a critical role in transduction of calcium-induced contraction. Presently, little is known about the regulation of tropomyosin gene expression during myogenesis. In the present study, qualitative and quantitative changes in the nucleic acid populations of differentiating chicken embryo muscle cells in culture have been examined. Total nucleic acid content per nucleus increased about fivefold in fully developed myotubes as compared to mononucleated myoblasts. The contribution of deoxyribonucleic acid to the total nucleic acid population decreased from 24% in myoblasts to 5% of total nucleic acid in myotubes. Concomitant with the decrement in deoxyribonucleic acid contribution to total nucleic acid was an increase in polyadenylated ribonucleic acid (RNA) content per cell which reached levels in myotubes that were 17-fold higher than those of myoblasts. Specific changes in the RNA population during myogenesis were further investigated by quantitation of the synthetic capacity (messenger RNA levels) per cell for alpha- and beta-tropomyosin. Cell-free translation and immunoprecipitation demonstrated an approximately 40-fold increase in messenger RNA levels per nucleus for alpha- and beta-tropomyosin after fusion in the terminally differentiated myotubes. Indirect immunofluorescence with affinity-purified tropomyosin antibodies demonstrated the presence of tropomyosin-containing filaments in cells throughout myogenesis. Thus, the tropomyosin genes are constitutively expressed during muscle differentiation through the production of tropomyosin messenger RNA and translation into tropomyosin protein.