Expression of the Na(+)/Ca(2+) exchanger in skeletal muscle.

The expression of the Na(+)/Ca(2+) exchanger was studied in differentiating muscle fibers in rats. NCX1 and NCX3 isoform (Na(+)/Ca(2+) exchanger isoform) expression was found to be developmentally regulated. NCX1 mRNA and protein levels peaked shortly after birth. Conversely, NCX3 isoform expression was very low in muscles of newborn rats but increased dramatically during the first 2 wk of postnatal life. Immunocytochemical analysis showed that NCX1 was uniformly distributed along the sarcolemmal membrane of undifferentiated rat muscle fibers but formed clusters in T-tubular membranes and sarcolemma of adult muscle. NCX3 appeared to be more uniformly distributed along the sarcolemma and inside myoplasm. In the adult, NCX1 was predominantly expressed in oxidative (type 1 and 2A) fibers of both slow- and fast-twitch muscles, whereas NCX3 was highly expressed in fast glycolytic (2B) fibers. NCX2 was expressed in rat brain but not in skeletal muscle. Developmental changes in NCX1 and NCX3 as well as the distribution of these isoforms at the cellular level and in different fiber types suggest that they may have different physiological roles.

Staging of the commitment of murine cardiac cell progenitors.

The staging of murine cardiomyocyte specification and determination was investigated in cultures of tissue explants from pre- and postgastrulated embryos and after transplantation of cardiac or cardiogenic tissues from mouse embryos into 2-day-old chick embryos in different locations. The development of transplanted and cultured cells in cardiomyocytes was evaluated by testing the expression of several cardiac transcription factor genes (Nkx 2.5, eHAND, dHAND, GATA-4), alpha-cardiac actin mRNA, and beta-myosin heavy chain protein. In vitro analyses showed that cells with the potential to form cardiac muscle were present prior to gastrulation in 6.5-day postconception (dpc) epiblasts, as indicated by the expression of Nkx 2.5, eHAND, dHAND, and GATA-4 cardiac transcription factors; desmin transgene; alpha-cardiac actin; and beta-myosin heavy chain. Conversely, epiblasts transplanted into the chicken somitic environment did not exhibit full cardiogenic cell differentiation. It was determined that chick host axial structures did not influence cardiogenesis in transplants. Mesoderm from late streak explants was capable of differentiating into the cardiac phenotype in the avian heterotopic environment, indicating that the specification of cardiac precursors (under way by 6.5 dpc) became irreversible at around the late streak stage in mouse embryo. Although in vitro analyses showed that interaction with endoderm is not required for the specification of murine cardiac cells, the presence of endoderm in explant cultures between mid- and late streak stages stimulated emerging mesodermal cells to adopt a myocardial pathway, whereas ectoderm had no influence on cardiomyogenesis.

The expression of the homeobox gene Msx1 reveals two populations of dermal progenitor cells originating from the somites.

Experimental manipulation in birds has shown that trunk dermis has a double origin: dorsally, it derives from the somite dermomyotome, while ventrally, it is formed by the somatopleure. Taking advantage of an nlacZ reporter gene integrated into the mouse Msx1 locus (Msx1(nlacZ) allele), we detected segmental expression of the Msx1 gene in cells of the dorsal mesenchyme of the trunk between embryonic days 11 and 14. Replacing somites from a chick host embryo by murine Msx1(nlacZ )somites allowed us to demonstrate that these Msx1-(beta)-galactosidase positive cells are of somitic origin. We propose that these cells are dermal progenitor cells that migrate from the somites and subsequently contribute to the dorsalmost dermis. By analysing Msx1(nlacZ) expression in a Splotch mutant, we observed that migration of these cells does not depend on Pax3, in contrast to other migratory populations such as limb muscle progenitor cells and neural crest cells. Msx1 expression was never detected in cells overlying the dermomyotome, although these cells are also of somitic origin. Therefore, we propose that two somite-derived populations of dermis progenitor cells can be distinguished. Cells expressing the Msx1 gene would migrate from the somite and contribute to the dermis of the dorsalmost trunk region. A second population of cells would disaggregate from the somite and contribute to the dermis overlying the dermomyotome. This population never expresses Msx1. Msx1 expression was investigated in the context of the onset of dermis formation monitored by the Dermo1 gene expression. The gene is downregulated prior to the onset of dermis differentiation, suggesting a role for Msx1 in the control of this process.

Mouse-chick chimera: an experimental system for study of somite development.

As the mammalian embryo is implanted in the uterus and not readily accessible to direct observation or manipulation, much of our understanding of mammalian somite development is based on findings in lower vertebrates. One means of overcoming the difficulties raised by intrauterine development is to engraft mouse tissue in ovo. The experiments described in this chapter relate to the unilateral replacement of somites in chick embryo with those from mouse fetus. Mouse somites differentiate in ovo in dermis, cartilage, and skeletal muscle and are able to migrate into chick host limb. A LacZ transgenic mouse strain was used to ascertain the role of the implanted somites in forming epaxial and hypaxial muscle in the chick embryo. Myogenesis occurred normally in in ovo developing mouse somites, and muscle cells from mouse myotome formed neuromuscular contacts with chick motor axons. After fragments of fetal mouse neural primordium were transplanted into chick embryo, mouse neural tube contributed to the mechanism maintaining myogenesis in the somites of the host embryo. A recently developed double-grafting procedure involving neural tube and somites from knockout mouse strains should elucidate the molecular events involved in early somitogenesis.

The homeobox gene Msx1 is expressed in a subset of somites, and in muscle progenitor cells migrating into the forelimb.

In myoblast cell cultures, the Msx1 protein is able to repress myogenesis and maintain cells in an undifferentiated and proliferative state. However, there has been no evidence that Msx1 is expressed in muscle or its precursors in vivo. Using mice with the nlacZ gene integrated into the Msx1 locus, we show that the reporter gene is expressed in the lateral dermomyotome of brachial and thoracic somites. Cells from this region will subsequently contribute to forelimb and intercostal muscles. Using Pax3 gene transcripts as a marker of limb muscle progenitor cells as they migrate from the somites, we have defined precisely the somitic origin and timing of cell migration from somites to limb buds in the mouse. Differences in the timing of migration between chick and mouse are discussed. Somites that label for Msx1(nlacZ )transgene expression in the forelimb region partially overlap with those that contribute Pax3-expressing cells to the forelimb. In order to see whether Msx1 is expressed in this migrating population, we have grafted somites from the forelimb level of Msx1(nlacZ )mouse embryos into a chick host embryo. We show that most cells migrating into the wing field express the Msx1(nlacZ )transgene, together with Pax3. In these experiments, Msx1 expression in the somite depends on the axial position of the graft. Wing mesenchyme is capable of inducing Msx1 transcription in somites that normally would not express the gene; chick hindlimb mesenchyme, while permissive for this expression, does not induce it. In the mouse limb bud, the Msx1(nlacZ )transgene is downregulated prior to the activation of the Myf5 gene, an early marker of myogenic differentiation. These observations are consistent with the proposal that Msx1 is involved in the repression of muscle differentiation in the lateral half of the somite and in limb muscle progenitor cells during their migration.

Blood borne macrophages are essential for the triggering of muscle regeneration following muscle transplant.

The transplantation of satellite cells may constitute a strategy for rebuilding muscle fibres in inherited myopathies. However, its development requires a great understanding of the role of environmental signals in the regenerative process. It is therefore essential to identify the key events triggering and controlling this process in vivo. We investigated whether macrophages play a key role in the course of the regenerative process using skeletal muscle transplants from transgenic pHuDes-nls-LacZ mice. Before grafting, transplants were conditioned with macrophage inflammatory protein 1-beta (MIP 1-beta; stimulating the macrophages infiltration or vascular endothelial growth factor (VEGF) stimulating angiogenesis). Treatment of transplants with MIP 1-beta and VEGF both accelerated and augmented monocyte-macrophage infiltration and satellite cell differentiation and/or proliferation, as compared to controls. In addition, VEGF treatment enhanced the number of newly formed myotubes. When a complete depletion of host monocyte-macrophages was experimentally induced, no regeneration occurred in transplants. Our data suggest that the presence of blood borne macrophages is required for triggering the earliest events of skeletal muscle regeneration. The understanding of macrophage behaviour after muscle injury should allow us to develop future strategies of satellite cell transplantation as a treatment for muscular dystrophies.

MyoD, myogenin, and desmin-nls-lacZ transgene emphasize the distinct patterns of satellite cell activation in growth and regeneration.

Although satellite cell differentiation is involved in postnatal myogenesis from growth to posttrauma regeneration, the early stages of this process remain unclear. This study investigated pHuDes-nls-lacZ transgene activity, as revealed by X-gal staining and the accumulation of MyoD, myogenin, endogenous desmin, and myosin, in order to determine whether satellite cells share the same activation program during growth and regeneration. After birth, skeletal myonuclei in which myogenin expression was limited were briefly characterized by transgene activity. Satellite cells were only evidenced by MyoD and slow myosin accumulation, but failed to initiate transgene expression. After freeze trauma, satellite cell activation led to MyoD, myogenin, and desmin expression. Subsequently, when myosin expression occurred, transgene activation was apparent in regenerating structures, with more intense X-gal staining in mononucleated cells than regenerating myotubes. After the second week posttrauma, only desmin and myogenin expression were maintained in regenerating structures. In culture, the behavior of satellite cells showed that desmin expression was committed before transgene activation occurred, i.e., concurrently with MyoD, myogenin, myosin expression, and the first fusion events. Quantitative analysis confirmed the discrepancy between endogenous desmin and transgene expression and demonstrated the close correlation between transgene activation and the fusion index. Our results strongly suggest that satellite cells promote distinct pathways of myogenic response during growth and regeneration.

Comparative analysis of satellite cell properties in heavy- and lightweight strains of turkey.

The growth of muscle during postnatal development results partly from the proliferation of satellite cells and their fusion with muscle fibres. We analysed the properties of satellite cells in a heavyweight (HW) turkey strain characterized by high body weight and a fast growth rate, and in a lightweight farm strain (LW) characterized by low body weight and a slow growth rate. Satellite cell activation was then examined in stretched-overloaded anterior latissimus dorsi (ALD) muscle by weighting one wing in young turkeys from both strains. As early as day 1 of stretching for HW and day 2 for LW, small embryonic-like fibres expressing ventricular cardiac myosin heavy chain (MHC) isoform were observed. Following four days of stretching, the number of nascent fibres had increased in both strains but was significantly greater in HW than LW ALD muscle. The proliferation and differentiation capacities of satellite cells from HW and LW strains were investigated in culture. As judged by in vitro measurements of 3H-thymidine incorporation and DNA content, satellite cells of HW turkey exhibited a greater proliferative capability than those of LW turkey. No differences in the temporal appearance of muscle markers (desmin, MHC isoforms) were noted in vitro between the two strains. These data confirm our in vivo observations indicating that selection based on growth rate does not modify muscle fibre maturation. Our in vivo and in vitro observations suggest that variations in the postnatal muscle growth pattern between HW and LW strains may be related to a difference in the capacity of their satellite cells to proliferate.

Acetylcholine receptor formation in mouse-chick chimera.

This study investigated possible interactions between motoneurons and somitic-derived muscle cells in the formation of neuromuscular synapses in the myotome. The peculiarities of the neuromuscular synaptic pattern in chick and mouse embryos provided a model for studying the achievement of synaptogenesis between chick motoneurons and mouse muscle cells. In chick embryo, initial AChR clustering occurs well before innervation of the myotome, whereas in mouse embryo nerve axons invade the myotome extensively before the appearance of AChR clusters. Our approach was to replace somites from a chick host embryo with those derived from mouse donor embryos. We show that muscle cells from mouse myotome can differentiate in the chick embryo environment and form neuromuscular contacts with chick motor axons. Host axons invaded in ovo differentiating mouse myotome at a time when they had not yet reached the host myotome. This particular ingrowth of motor nerves was attributable to the mouse transplant since use of a quail somite did not produce the same effect as the mouse somite, which suggests that developing mouse muscles specifically modify the time course of chick axogenesis. The synaptic areas formed between chick motor axons and mouse myotubes developed according to the mouse pattern. Both the timing of their appearance and their morphology correlated perfectly with events in mouse synaptogenesis. These results indicate the important role played by postsynaptic membrane in controlling the first steps of AChR formation.

Mouse-chick chimera: a developmental model of murine neurogenic cells.

Chimeras were prepared by transplanting fragments of neural primordium from 8- to 8.5- and 9-day postcoital mouse embryos into 1.5- and 2-day-old chick embryos at different axial levels. Mouse neuroepithelial cells differentiated in ovo and organized to form the different cellular compartments normally constituting the central nervous system. The graft also entered into the development of the peripheral nervous system through migration of neural crest cells associated with mouse neuroepithelium. Depending on the graft level, mouse crest cells participated in the formation of various derivatives such as head components, sensory ganglia, orthosympathetic ganglionic chain, nerves and neuroendocrine glands. Tenascin knockout mice, which express lacZ instead of tenascin and show no tenascin production (Saga, Y., Yagi, J., Ikawa, Y., Sakakura, T. and Aizawa, S. (1992) Genes and Development 6, 1821-1838), were specifically used to label Schwann cells lining nerves derived from the implant. Although our experiments do not consider how mouse neural tube can participate in the mechanism required to maintain myogenesis in the host somites, they show that the grafted neural tube behaves in the same manner as the chick host neural tube. Together with our previous results on somite development (Fontaine-Pérus, J., Jarno, V., Fournier Le Ray, C., Li, Z. and Paulin, D. (1995) Development 121, 1705-1718), this study shows that chick embryo constitutes a privileged environment, facilitating access to the developmental potentials of normal or defective mammalian cells. It allows the study of the histogenesis and precise timing of a known structure, as well as the implication of a given gene at all equivalent mammalian embryonic stages.

Desmin-lacZ transgene expression and regeneration within skeletal muscle transplants.

The purpose of this study was to investigate the initiation and time course of the regeneration process in fragments of skeletal muscle transplants as a function of muscle tissue age at implantation. The appearance of desmin occurs at the very beginning of myogenesis. The transgenic desmin nls lacZ mice used in the study bear a transgene in which the 1 kb DNA 5' regulatory sequence of the desmin gene is linked to a reporter gene coding for Escherichia coli beta-galactosidase. The desmin lacZ transgene labels muscle cells in which the desmin synthesis programme has commenced. We implanted pectoralis muscle fragments from fetal transgenic embryos and mature and old transgenic mice into mature non-transgenic mice. Early events of myogenesis occurring during regeneration started sooner in transplants from 4-month-old (day 3 post-implantation) muscle than in those from 24-month-old (day 5-6 post-implantation) muscle, and they lasted longer in those from young (day 17 post-implantation) than in those from old (day 14 post-implantation) muscle fragments. In adult muscle, transgene activation proceeded from the periphery toward the centre of the transplant. In transplants from fetal 18-day-old pectoralis, myotubes with transgene activity were observed from day 1 to day 19. Desmin immunoreactivity, which appeared about one day after transgene activation, was followed by myosin expression. In adult transplants, the continuity of laminin labelling was disrupted around degenerative fibres, illustrating alteration of the extracellular matrix. Our data suggest that satellite cells from old muscle tissue have lower proliferative capacity and/or less access to trophic substances released by the host (damaged fibres, vascularization) than those from fetal or young adult muscle.

Innervation regulates myosin heavy chain isoform expression in developing skeletal muscle fibers.

The influence of innervation on primary and secondary myogenesis and its relation to fiber type diversity were investigated in two specific wing muscles of quail embryo, the posterior (PLD) and anterior latissimus dorsi (ALD). In the adult, these muscles are composed almost exclusively of pure populations of fast and slow fibers, respectively. When slow ALD and fast PLD muscles developed in ovo in an aneurogenic environment induced after neural tube ablation, the cardiac ventricular myosin heavy chain (MHC) isoform was not expressed. The adult slow MHC isoform, SM2, appeared by embryonic day 7 (ED 7) in normal innervated slow ALD but was not expressed in denervated muscle. Analysis of in vitro differentiation of myoblasts from fast PLD and slow ALD muscles isolated from ED 7 control and neuralectomized quail embryos showed no fundamental differences in the pattern of MHC isoform expression. Newly differentiated fibers accumulated cardiac ventricular, embryonic fast, slow SM1 and SM3 MHC isoforms. Nevertheless, the expression of slow SM2 isoform in myotubes formed from slow ALD myoblasts only occurred when myoblasts were cultured in the presence of embryonic spinal cord. Our studies demonstrate that the neural tube influences primary as well as secondary myotube differentiation in avian forelimb and facilitates the expression of different MHC, particularly slow SM2 MHC gene expression in slow myoblasts.

Seasonal variation in the phenotype of adult ferret (Mustela putorius furo) cremaster muscle.

Using immunocytochemistry, electrophoresis and immunoblotting, we studied the expression of fast and slow myosin heavy chain isoforms in adult ferret muscles during quiescent and breeding periods. Adult cremaster muscle expressed slow and fast myosin heavy chain in relatively similar amounts during the quiescent period. During the breeding period, the expression of slow myosin heavy chain, I, significantly decreased, and fast myosin heavy chain II, was predominant. No alteration of the MHC pattern in EDL and soleus muscles was detected between the quiescent and breeding periods. The possible involvement of androgens and mechanical factors in the regulation of myosin heavy chain expression in adult cremaster muscle is discussed.

Mouse chick chimera: a new model to study the in ovo developmental potentialities of mammalian somites.

Chimeras were prepared by transplanting somites from 9-day post-coïtum mouse embryos or somitic dermomyotomes from 10-day post-coïtum mouse embryos into 2-day-old chick embryos at different axial levels. Mouse somitic cells then differentiated in ovo in dermis, cartilage and skeletal muscle as they normally do in the course of development and were able to migrate into chick host limb. To trace the behavior of somitic myogenic stem cells more closely, somites arising from mice bearing a transgene of the desmin gene linked to a reporter gene coding for Escherichia coli beta-galactosidase (lacZ) were grafted in ovo. Interestingly, the transgene was rapidly expressed in myotomal muscles derived from implants. In the limb muscle mass, positive cells were found several days after implantation. Activation of desmin nls lacZ also occurred in in vitro cultures of somite-derived cells. Our experimental method facilitates investigation of the mechanisms of mammalian development, allowing the normal fate of implanted mouse cells to be studied and providing suitable conditions for identification of descendants of genetically modified cells.

Neural tube can induce fast myosin heavy chain isoform expression during embryonic development.

We investigated the role of the neural tube in muscle cell differentiation in developing somitic myotome of chick embryo, particularly through fast myosin heavy chain (MHC) isoform expression. An embryonic fast MHC labeled with EB165 mAb was expressed in somitic cells from stage 15 of Hamburger and Hamilton (H.H.) (24 somites). Moreover, a distinct early embryonic fast MHC was expressed only from stage 15 of H.H. to stage 36 (E10). Like neonatal MHC, this isoform was labeled with 2E9 mAb but differed in its immunopeptide mapping. Expression of EB165-labeled embryonic fast MHC occurred in somitic myotomes deprived of neural tube influence by in ovo ablation as well as in somite explants cultured alone in vitro. Conversely, ablation of the neural tube prevented somitic expression of MHC labeled with 2E9 mAb. The neural tube induced in vitro expression of this MHC in explants of somites which failed to express it when cultured alone. These results indicate that signals emanating from the neural tube are required for the expression of early embryonic fast MHC isoform in developing somitic myotome.

Differentiation potentialities of distinct myogenic cell precursors in avian embryos.

Interspecific grafting experiments between chick and quail embryos were carried out to investigate the differentiation capacities of myoblasts from different development stages. Grafts consisted of 3.5-day-old embryonic quail dermomyotomes isolated from the cranial level, 7- to 10-day-old and 16-day-old embryonic quail pectoralis muscles, 15-day-old postnatal quail pectoralis muscle, and 3- to 10-day-old embryonic quail cardiac and gut muscles. Grafts were implanted into 2-day-old chick embryos in place of the dorsal halves of somites from the prospective wing level. After implantation of dermomyotome fragments, we observed that quail cells participated in trunk and limb musculature. After implantation of 7- to 10-day-old embryonic muscle, quail cells were rarely found in the limb but systematically took part in the formation of trunk muscles. All these capacities were totally lost in 16-day-old embryonic and 15-day-old postnatal muscles. After implantation of nonsomitic derivatives such as embryonic cardiac and gut muscles, implanted cells never participated either in wing or trunk musculature. After dermomyotome, embryonic muscle, and gut implantation, quail cells were capable of invading the dermis and aggregating into feather germs. Our results extend those previously reported and indicate that somitic myogenic derivatives which do not migrate in the normal course of embryogenesis have migratory potentialities and are able to give rise to axial muscles. All these potentialities are lost as myogenesis proceeds in embryos.

Comparison of postnatal development of anterior latissimus dorsi (ALD) muscle in heavy- and light-weight strains of turkey (Meleagris gallopavo).

ALD muscle development was studied from day 2 to week 15 in males of two turkey strains. At 15 weeks, the heavy-weight (HW) strain weighted 2.2 times as much as the light-weight strain (LW). Morphometric and immunocytochemical analysis showed the presence of small fibers in HW ALD muscle which simultaneously accumulated ventricular and embryonic fast myosin heavy chain isoforms. The appearance of these nascent myofibers suggests that hyperplasia contributes to the growth of HW ALD muscle.