(J-CM) S U M M A R Y Given the importance of the myogenic regulatory factors (MRFs) for myoblast differentiation during development, the aims of this work were to clarify the spatial and temporal expression pattern of the four MRF mRNAs during soleus regeneration in mouse after cardiotoxin injury, using in situ hybridization, and to investigate the influence of innervation on the expression of each MRF during a complete degeneration/regeneration process. For this, we performed cardiotoxin injury-induced regeneration experiments on denervated soleus muscle. Myf-5, MyoD, and MRF4 mRNAs were detected in satellite cell-derived myoblasts in the first stages of muscle regeneration analyzed (2-3 days P-I). The Myf-5 transcript level dramatically decreased in young multinucleated myotubes, whereas MyoD and MRF4 transcripts were expressed persistently throughout the regeneration process. Myogenin mRNA was transiently expressed in forming myotubes. These results are discussed with regard to the potential relationships between MyoD and MRF4 in the satellite cell differentiation pathway. Muscle denervation precociously (at 8 days P-I) upregulated both the Myf-5 and the MRF4 mRNA levels, whereas the increase of both MyoD and myogenin mRNA levels was observed later, in the late stages of regeneration (30 days P-I). This significant accumulation of each differentially upregulated MRF during soleus regeneration after denervation suggests that each myogenic factor might have a distinct role in the regulatory control of muscle gene expression. This role is discussed in relation to the expression of the nerve-regulated genes, such as the nAChR subunit gene family.
The data show that exposure to hypoxic conditions (1% O(2)) of rat and human myoblasts altered their proliferation and differentiation processes. They also show that Epo is not an efficient growth factor to counteract this deleterious effect.
Anemia and hypoxia in rats result in an increase in factors potentially involved in cerebral angiogenesis. Therefore, the aim of this study was to assess the effect of chronic anemia and/or chronic hypoxia on cerebral cellular responses and angiogenesis in wild-type and anemic transgenic mice. These studies were done in erythropoietin-deficient mice (Epo-TAg(h)) in normoxia and following acute (one day) and chronic (14 days, barometric pressure = 420 mmHg) hypoxia. In normoxia, Epo-TAg(h) mice showed an increase in transcript and protein levels of hypoxia-inducible factor 1alpha (HIF-1alpha), vascular endothelial growth factor (VEGF), erythropoietin receptors (EpoR), phospho-STAT-5/STAT-5 ratio, and neuronal neuronal nitric oxide synthase (nNOS) along with a higher cerebral capillary density. In wild-type (WT) mice, acute hypoxia increased all of the studied factors, while in chronic hypoxia, HIF-1alpha, EpoR, phospho-STAT-5/STAT-5 ratio, nNOS, and inducible NOS remained elevated, with an increase in capillary density. Surprisingly, in Epo-TAg(h) mice, chronic hypoxia did not further increase any factor except the nitric oxide metabolites, while HIF-1alpha, EpoR, and phospho-STAT-5/STAT-5 ratio were reduced. Normoxic Epo-TAg(h) mice developed cerebral angiogenesis through the HIF-1alpha/VEGF pathway. In acute hypoxia, WT mice up-regulated all of the studied factors, including cerebral NO. Polycythemia and angiogenesis occurred with acclimatization to chronic hypoxia only in WT mice. In Epo-TAg(h), the decrease in HIF-1alpha, VEGF proteins, and phospho-STAT-5 ratio in chronic hypoxia suggest that neuroprotective and angiogenesis pathways are altered.
Among the myogenic regulatory factors, myogenin is a transcriptional activator situated at a crucial position for terminal differentiation in muscle development. It is unclear at present whether myogenin exhibits unique specificities to transactivate late muscular markers. During Xenopus development, the accumulation of myogenin mRNA is restricted to secondary myogenesis, at the onset of the appearance of adult isoforms of -tropomyosin and myosin heavy chain. To determine the role of myogenin in the isoform switch of these contractile proteins, we characterized and directly compared the functional properties of myogenin with other myogenic regulatory factors in Xenopus embryos. Two distinct cDNAs related to myogenin, XmyogU1 and XmyogU2, were differentially expressed during myogenesis and in adult tissues, in which they preferentially accumulated in oxidative myofibers. Animal cap assays in Xenopus embryos revealed that myogenin, but not the other myogenic regulatory factors, induced expression of embryonic/larval isoforms of the -tropomyosin and myosin heavy chain genes. Only XmyogU1 induced expression of the adult fast isoform of the myosin heavy chain gene. This is the first demonstration of a specific transactivation of one set of muscle structural genes by myogenin.The members of the MyoD gene family, including myoD (1), myogenin (2), myf5 (3), and MRF4 (4, 5), encode myogenic transcription factors (MRFs) 1 able to convert non-muscle cells to a muscle phenotype in culture (6, 7). First identified in mammals, all four proteins share a highly conserved central region related to the basic helix-loop-helix domain of the c-Myc superfamily. The MRFs are specifically expressed in skeletal muscle, with non-identical patterns of expression (8), and form a regulatory network controlling muscle determination and/or differentiation. Experiments using various MRF knockout mice have progressively elucidated the hierarchical relationships among the MRFs and established that functional redundancy is a feature of the MRF regulatory network. Thus, MyoD and Myf5 play overlapping roles in myoblast specification, whereas myogenin and either MyoD or MRF4 are required for differentiation (9). However, the redundant functions of MyoD and MRF4 appear not to overlap with those of myogenin (10). Knockout mice lacking the myogenin gene die at birth due to severe muscle deficiency, despite normal levels of MyoD and Myf5 (11,12). Recent studies have shown that the role of myogenin in muscle formation is distinct from that of MyoD and that this difference is due to functional specialization, and not just regulation of expression (13,14).Surprisingly little is known about the identity of muscle genes that are selectively activated by myogenin and that cannot be activated by the other myogenic regulators. Indeed, all the MRFs can transactivate muscle-specific gene expression by interacting with the consensus nucleotide motif, CANNTG, also called the E box, and they are all believed to bind to their target sequences as heterodimers with ...
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