A population of myogenic cells derived from the mouse neural tube.

Embryonic mouse neural tubes produce a variety of terminally differentiated cells in vitro, mostly neurons and glia. We report here that some of these cells differentiate into skeletal muscle cells. The possibility of mesoderm contamination was ruled out as follows. First, Dil+ muscle cells were present in cultures from a Dil-labeled neuroepithelium. Second, a small fraction of cultured neural tube cells coexpressed muscle myosin and neuronal beta III tubulin within the same cell. Third, embryos generated from embryonic stem cells in which nlacZ was targeted into the myogenic gene myf-5 expressed nlacZ in a localized region of the neural tube. These myf-5+ cells coexpress neuronal and muscle markers in culture. The developmental significance of this phenomenon is discussed in the context of overlapping regulatory networks between myogenesis and neurogenesis.

A novel system for screening antiretroviral agents.

We propose a new screening system of drugs capable of inactivating retroviruses by interfering with the binding, entry into the cell, uncoating, reverse transcription, migration into the nucleus or integration of the retrovirus. It is based on the utilization of recombinant retroviruses which can be detected in single cells by the expression of a LacZ reporter gene. It allows simple and rapid quantification of the number of infectious viral particles. The screening system can then be used to precisely define the period sensitive to the drug.

Muscle progenitor cells failing to respond to positional cues adopt non-myogenic fates in myf-5 null mice.

Mice that have mutations in both myogenic transcription factors Myf-5 and MyoD totally lack skeletal muscle fibres and their precursor myoblasts, whereas with either mutation alone, muscle is present. Skeletal muscle in the vertebrate body is derived from epithelial somites that respond to environmental signals to form the dorsal epithelial dermomyotome (dermis, muscle) and ventral mesenchymal sclerotome (axial skeleton, ribs). The first muscle, the myotome, forms centrally in the somite, when only myf-5 is programming myogenesis. By targeting the nlacZ reporter gene into the myf-5 locus, we demonstrate that beta-galactosidase+ muscle progenitor cells are present in the dermomyotome of myf-5 null embryos, and that they undergo a normal epithelial-mesenchymal transition; however, they migrate aberrantly. Dorsally, they accumulate under the ectoderm and express a non-muscle dermal marker, Dermo-1. Ventrally, beta-galactosidase+ cells also fail to localize correctly, express a cartilage marker scleraxis, and are subsequently found in ribs. Therefore Myf-5 protein is necessary for cells to respond correctly to positional cues in the embryo and to adopt their myogenic fate. In its absence, muscle progenitors, having activated myf-5, remain multipotent and differentiate into other somitic derivatives according to their local environment.

Redefining the genetic hierarchies controlling skeletal myogenesis: Pax-3 and Myf-5 act upstream of MyoD.

We analyzed Pax-3 (splotch), Myf-5 (targeted with nlacZ), and splotch/Myf-5 homozygous mutant mice to investigate the roles that these genes play in programming skeletal myogenesis. In splotch and Myf-5 homozygous embryos, myogenic progenitor cell perturbations and early muscle defects are distinct. Remarkably, splotch/Myf-5 double homozygotes have a dramatic phenotype not seen in the individual mutants: body muscles are absent. MyoD does not rescue this double mutant phenotype since activation of this gene proves to be dependent on either Pax-3 or Myf-5. Therefore, Pax-3 and Myf-5 define two distinct myogenic pathways, and MyoD acts genetically downstream of these genes for myogenesis in the body. This genetic hierarchy does not appear to operate for head muscle formation.

A beta-galactosidase hybrid protein targeted to nuclei as a marker for developmental studies.

The Escherichia coli lacZ gene has been used as an indicator gene for the study of cell lineage in vivo. To adapt this marker for gene expression studies, a sequence encoding a modified beta-galactosidase and including the simian virus 40 large tumor nuclear location signal (nls-beta-Gal) has been introduced into vectors. In differentiated cells, multipotential cells, and embryos, the constructs led to the expression of an enzymatically active protein. Its location was examined by its beta-galactosidase activity or by using antibodies and electron microscopy. The results show that the nls-beta-Gal protein remains mainly located at the nuclear periphery (probably at the nuclear pores) but does not reach the nucleoplasm. It suggests that an interaction with the nuclear membrane is necessary but not sufficient for protein uptake into the nucleus. In multipotential cells, the expression of nuclear location signal LacZ (nls-LacZ) interferes neither with cell growth nor with differentiation. Using various lacZ constructs, the transcriptional activity of embryos was studied. At the two-cell stage, the promoters of the Rous sarcoma virus, simian virus 40, and the beta-actin gene are functional but the Moloney murine leukemia virus long terminal repeat is not. Thus, transcriptional specificity must already be present at the stage of activation of the embryonic genome.

Activation of a beta-galactosidase recombinant provirus: application to titration of human immunodeficiency virus (HIV) and HIV-infected cells.

A quantitative bioassay for human immunodeficiency viruses has been developed on the basis of the ability of the tat gene to transactivate the expression of an integrated beta-galactosidase gene in a HeLa-CD4+ cell line. Infection by a single virion of HIV-1 or HIV-2 corresponds to a unique blue syncytium or a cell cluster detected after fixation and addition of 5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside (a beta-galactosidase substrate). The number of infected lymphoid cells in a culture (stimulated human peripheral blood lymphocytes and cell lines) can also be quantified by cell-to-cell transmission of HIV into the HeLa-CD4(+)-beta-galactosidase monolayer. Infections by simian immunodeficiency viruses are similarly detected. This assay has been used to determine the dose response of drugs, the half-life of HIV at 37 degrees C, and the appearance of infectious particles after virus infection.

Modular long-range regulation of Myf5 reveals unexpected heterogeneity between skeletal muscles in the mouse embryo.

The myogenic factor Myf5 plays a key role in muscle cell determination, in response to signalling cascades that lead to the specification of muscle progenitor cells. We have adopted a YAC transgenic approach to identify regulatory sequences that direct the complex spatiotemporal expression of this gene during myogenesis in the mouse embryo. Important regulatory regions with distinct properties are distributed over 96 kb upstream of the Myf5 gene. The proximal 23 kb region directs early expression in the branchial arches, epaxial dermomyotome and in a central part of the myotome, the epaxial intercalated domain. Robust expression at most sites in the embryo where skeletal muscle forms depends on an enhancer-like sequence located between -58 and -48 kb from the Myf5 gene. This element is active in the epaxial and hypaxial myotome, in limb muscles, in the hypoglossal chord and also at the sites of Myf5 transcription in prosomeres p1 and p4 of the brain. However later expression of Myf5 depends on a more distal region between -96 and -63 kb, which does not behave as an enhancer. This element is necessary for expression in head muscles but strikingly only plays a role in a subset of trunk muscles, notably the hypaxially derived ventral body muscles and also those of the diaphragm and tongue. Transgene expression in limb muscle masses is not affected by removal of the -96/-63 region. Epaxially derived muscles and some hypaxial muscles, such as the intercostals and those of the limb girdles, are also unaffected. This region therefore reveals unexpected heterogeneity between muscle masses, which may be related to different facets of myogenesis at these sites. Such regulatory heterogeneity may underlie the observed restriction of myopathies to particular muscle subgroups.