A new muscle phenotype is expressed by subcultured quail myoblasts isolated from future fast and slow muscles

The transcriptional activity of a muscle-specific promoter depends critically on the structure of the TATA element and its binding protein

We have previously characterized the proximal promoter of the mouse IIB myosin heavy chain (MyHC) gene, which is expressed only in fast-contracting glycolytic skeletal muscle fibers. We show here that the substitution into this promoter of a non-canonical TATA sequence from the IgH gene results in inactivity in muscle cells, even though TATA-binding protein (TBP) can bind strongly to this mutated promoter. Chemical foot-printing data show, however, that TBP makes different DNA contacts on this heterologous TATA sequence. The inactivity of such a non-canonical TATA motif in the IIB promoter context appears to be caused by a non-functional conformation of the bound TBP-DNA complex that is incapable of sustaining transcription. The conclusions imply that the precise sequence of the promoter TATA motif needs to be matched with the specific functional class of upstream activator proteins present in a given cell type in order for the gene to be transcriptionally active.

Myogenic regulatory factors can activate TATA-containing promoter elements via an E-box independent mechanism

We have studied the effect of several myogenic regulatory factors on the activity of the promoter for a mouse gene encoding a skeletal myosin heavy chain (MyHC) expressed in adult (type IIB) muscle fibers. Co-transfection of myogenic factors is necessary for activity of the IIB promoter in mouse C2 myotubes in culture but not in quail myotubes in culture. Although this promoter contains one E-box within the first 192 base pairs upstream of the transcriptional start site, mutations in this motif demonstrate that it is not required for the transactivation effect of the myogenic factors. Analysis of other mutants suggests that the MEF2 and MHox DNA-binding factor binds to an evolutionarily conserved AT-rich motif. In addition, the IIB promoter appears to require the conserved TATA motif (CTATAAAAG) in order to be activated by the AT-rich sequences. The IIB promoter constructs produce RNA transcripts which begin at the natural site of transcriptional initiation in quail myotubes and in mouse C2 myotubes after co-transfection with myogenic factors; a second, minor, start site is also used in the co-transfected C2 myotubes. Results obtained after transfection of the mouse IIB promoter constructs in quail myotube cultures suggest that the overexpression of myogenic factors in C2 cultures does not result in an environment in which the control of IIB MyHC promoter activity is aberrant. Therefore, either the myogenic factors themselves, or other proteins induced by them, seem to interact directly with the basal transcription seem to interact directly with the basal transcription machinery to allow muscle-specific gene expression.

Denervated chicken breast muscle displays discoordinate regulation and differential patterns of expression of alpha f and beta tropomyosin genes

The expression of the alpha fast (alpha f) and beta tropomyosin (TM) genes has been analysed with muscle-specific and common cDNA probes after unilateral nerve section of the pectoralis major muscle (PM) in 4-week-old chickens. The following were observed in denervated muscles. (1) The beta TM mRNA, which was repressed during development, reaccumulates in a biphasic curve with the increase in the beta TM protein lagging behind the changes in its mRNA. Accordingly, no beta TM is seen in products translated in vitro from total and polyA+ RNA obtained 1 week after denervation. No such translation block is seen with RNA obtained from control or muscles denervated for 6 weeks. (2) No changes in the alpha fTM mRNA and corresponding protein are observed. (3) RNA processing of the two genes is not changed. (4) In the contralateral muscles, transitory increases in alpha f and beta TM mRNAs are observed while the corresponding proteins remain unchanged. Our data suggest that muscle fibres display early and long-term responses to the loss of neural input which might result from a combination of changes produced by regenerative processes and reprogramming of existing fibres. Moreover, in contrast to normal development, no reciprocal changes of alpha f and beta TM expression are seen in denervated muscles.

Myogenic cell lineages

For many years the mechanisms by which skeletal muscles in higher vertebrates come to be composed of diverse fiber types distributed in distinctive patterns has interested cell and developmental biologists. The fiber composition of skeletal muscles varies from class to class and from muscle to muscle within the vertebrates. The developmental basis for these events is the subject of this review. Because an individual multinucleate vertebrate skeletal muscle fiber is formed by the fusion of many individual myoblasts, more attention, in recent times, has been directed toward the origins and differences among myoblasts, and more emphasis has been placed on the lineal relationship of myoblasts to fibers. This is a review of studies related to the concepts of myogenic cell lineage in higher vertebrate development with emphases on some of the most challenging problems of myogenesis including the embryonic origins of myogenic precursor cells, the mechanisms of fiber type diversity and patterning, the distinctions among myoblasts during myogenesis, and the current hypotheses of how a variety of factors, intrinsic and extrinsic to the myoblast, determine the definitive phenotype of a muscle fiber.

Skeletal muscle satellite cell diversity: satellite cells form fibers of different types in cell culture

Following skeletal muscle injury, new fibers form from resident satellite cells which reestablish the fiber composition of the original muscle. We have used a cell culture system to analyze satellite cells isolated from adult chicken and quail pectoralis major (PM; a fast muscle) and anterior latissimus dorsi (ALD; a slow muscle) to determine if satellite cells isolated from fast or slow muscles produce one or several types of fibers when they form new fibers in vitro in the absence of innervation or a specific extracellular milieu. The types of fibers formed in satellite cell cultures were determined using immunoblotting and immunocytochemistry with monoclonal antibodies specific for avian fast and slow myosin heavy chain (MHC) isoforms. We found that satellite cells were of different types and that fast and slow muscles differed in the percentage of each type they contained. Primary satellite cells isolated from the PM formed only fast fibers, while up to 25% of those isolated from ALD formed fibers that were both fast and slow (fast/slow fibers), the remainder being fast only. Fast/slow fibers formed from chicken satellite cells expressed slow MHC1, while slow MHC2 predominated in fast/slow fibers formed from quail satellite cells. Prolonged primary culture did not alter the relative proportions of fast to fast/slow fibers in high density cultures of either chicken or quail satellite cells. No change in commitment was observed in fibers formed from chicken satellite cell progeny repeatedly subcultured at high density, while fibers formed from subcultured quail satellite cell progeny demonstrated increasing commitment to fast/slow fiber type formation. Quail satellite cells cloned from high density cultures formed colonies that demonstrated a similar change in commitment from fast to fast/slow, as did serially subcloned individual satellite cell progeny, indicating that the observed change from fast to fast/slow differentiation resulted from intrinsic changes within a satellite cell. Thus satellite cells freshly isolated from adult chicken and quail are committed to form fibers of at least two types, satellite cells of these two types are found in different proportions in fast and slow muscles, and repeated cell proliferation of quail satellite cell progeny may alter satellite cell progeny to increasingly form fibers of a single type.

Myogenic stem cell commitment probability remains constant as a function of organismal and mitotic age

Chicken myogenic stem cells can undergo symmetric and asymmetric cell divisions. Symmetric divisions produce two stem cells or two cells committed to terminal muscle differentiation. Asymmetric divisions produce one stem cell and one committed cell. Committed cells undergo four divisions, and their progeny differentiate into postmitotic, biochemically distinct muscle cells, which can be identified immunocytochemically. The control of stem cell commitment was investigated in vitro by means of cell cloning and subcloning experiments, and computer modeling. We found that stem cell commitment is a process which can be modeled as a stochastic event, with a central tendency or probability of 0.2 +/- 0.1. This value is independent of organismal or mitotic age of the stem cells, cell density, or growth in a mitogen-poor environment. Myogenic stem cells stop dividing after approximately 30 divisions in vitro. Since the probability of commitment to terminal differentiation remains below 0.5, clonal senescence and terminal differentiation are separate processes in this system.

Control of myogenic differentiation by cellular oncogenes

The establishment of a differentiated phenotype in skeletal muscle cells requires withdrawal from the cell cycle and termination of DNA synthesis. Myogenesis can be inhibited by serum components, purified mitogens, and transforming growth factors, but the intracellular signaling pathways utilized by these molecules are unknown. Recent studies have confirmed a role for proteins encoded by cellular proto-oncogenes in transduction of growth factor effects that lead to cell proliferation. To test the contrasting hypothesis that cellular oncogenes might also regulate tissue-specific gene expression in developing muscle cells, myoblasts have been modified by incorporation of the cognate viral oncogenes, the corresponding normal or oncogenic cellular homologs, and chimeric oncogenes, whose expression can be induced reversibly. Regulation of the endogenous cellular oncogenes also has been examined in detail. Down-regulation of c-myc is not obligatory for myogenesis; rather, inhibitory effects of myc on muscle differentiation are contingent on sustained proliferation. In contrast, activated src and ras genes block myocyte differentiation directly, through a mechanism that is independent of DNA synthesis and is rapidly reversible, resembling the effects of inhibitory growth factors. The coordinate regulation of diverse tissue-specific gene products including muscle creatine kinase, nicotinic acetylcholine receptors, sarcomeric proteins, and voltage-gated ion channels, raises the hypothesis that inhibitors such as transforming growth factor-beta and ras proteins might exert their effects through a transacting transcriptional signal shared by multiple muscle-specific genes.

Evidence for distinct phosphorylatable myosin light chains in avian heart and slow skeletal muscle

In mammalian organisms the regulatory or phosphorylatable myosin light chains in heart and slow skeletal muscle have been shown to be identical and presumable constitute the product of a single gene. We analyzed the expression of the avian cardiac myosin light chain (MLC) 2-A in heart and slow skeletal muscle by a combination of experimental approaches, e.g., two-dimensional gel electrophoresis of the protein and hybridization of mRNA to specific MLC 2-A sequences cloned from chicken. The investigations have indicated that, unlike in mammals, in avian organisms the phosphorylatable myosin light chains from heart and slow skeletal muscle are distinct proteins and therefore products of different genes. The expression of MLC 2-A is restricted to the myocardium and no evidence was found that it is shared with slow skeletal muscle.

Chick and quail limb bud myoblasts, isolated at different times during muscle development, express stage-specific phenotypes when differentiated in culture

Evidence is presented which shows that myoblasts, isolated at different stages during chick and quail limb bud development, will form, in culture, myotubes which can be distinguished with a combination of morphological as well as biochemical criteria. Hind limb bud myoblasts isolated from 5-day-old embryos form very short myotubes which synthesize a myosin, the light chains of which are predominantly LC1F and LC2S. Myoblasts isolated from the limb buds of 7-8-day-old embryos form large myotubes which synthesize a myosin the light chains of which are predominantly LC1F, LC2S and LC2F. Myoblasts isolated from the thigh muscle of embryos older than 10 days form large myotubes which synthesize a myosin the light chains of which are predominantly LC1F and LC2F. These results have been confirmed by hybridization of the cellular mRNA with a molecular probe specific for LC2F. These results lead us to suggest the existence of at least two classes of myoblasts which appear at different times during limb bud development. The first class, or 'early' myoblasts, is present in the limb buds of 5-day-old embryos, whereas the second class, or 'late' myoblasts, is present in the muscles of embryos older than 8 days. This result, however, is also compatible with the hypothesis that all muscle cells are the same at all times during development, and that the different phenotypes simply reflect differences in the environmental conditions.

Rous sarcoma virus SRC gene expression on the growth of quail embryo skin fibroblasts and the establishment of permanent cell lines

Permanent cell lines of Quail embryo fibroblasts appear in cultures of cells infected with a wild type strain of Rous sarcoma virus (SR-RSV) or with its temperature sensitive transformation mutants (ts-T) (NYts68 and PA101) following a three step process. In step one, infected cells grow twice as fast as the control. The second step consists of a crisis during which the cell population is stationary for four to five weeks. Towards the fourth week several foci of cell growth are observed in the flasks. Respreading of the content of these flasks yields permanent lines. This constitutes the third step of the population evolution. In step one the growth rate of the infected cells is the same irrespective of the incubation temperature (36 degrees C or 41 degrees C) whereas the level of the pp60v-src activity is considerably depressed at 41 degrees C for NYts68 and PA101. Foci do not appear at restrictive temperature in the ts infected population and permanent lines are not recovered under that condition. These lines grow ony at 36 degrees C. It can be shown that the virus which they produce is not modified with respect to the temperature sensitivity of the src gene expression since newly infected fibroblasts grow equally well in step one at both 36 degrees C and 41 degrees C, and stop after the same number of generations. This finding suggests that the events which, during the crisis period, lead to the establishment of permanent lines, take place at the cellular level but depend on the activity of the pp60v-src protein for their occurrence or their expression.

Changes in ganglioside metabolism during in vitro differentiation of quail embryo myoblasts

The metabolism of gangliosides was studied during the in vitro differentiation of both normal quail myoblasts and myoblasts which have been transformed by a temperature-sensitive mutant of Rous sarcoma virus (RSV). These transformed cells can be maintained undifferentiated if incubated at 35 degrees C, but they will differentiate when shifted to 41 degrees C. (D. Montarras and M. Y. Fiszman (1983) J. Biol. Chem. 258, 3882-3888). The analysis of [14C]Glucosamine-labeled gangliosides by two-dimensional thin-layer chromatography reveals variations in the metabolism of the gangliosides during the process of differentiation. During the formation of myotubes, it was observed that the accumulation of GD1a is reduced, while the accumulation of GD3 is increased. Therefore, this results in the variation of the ratio GD3/GD1a which increases from 1.8 to 25 in the case of clones of transformed myoblasts, and from 0.5 to 1.7 in the case of uninfected myoblasts. These variations which have been observed seem to be specific of the myogenic differentiation since they cannot be reproduced when differentiation is inhibited by BUdR treatment or when fibroblasts reach confluency and are blocked in the G1 phase of cell cycle. Furthermore, the transformed myoblasts in vitro are shown to be a good model system since their gangliosides composition is very similar to that of muscle cells in vivo.