Regulation of a muscle-specific transgene by retinoic acid.

Retinoic acid (RA) has been shown to have variable effects on myogenic differentiation in cell culture. The application of RA on primary cultures of embryonic somites, limb buds, and neonatal limbs inhibited myogenic differentiation in a dose-dependent way as indicated by the repression of: (a) myotube formation, (b) myosin heavy chain protein accumulation, (c) myosin light chain (MLC) 1/3, alpha sk-actin and myogenic factor transcript expression. Expression of retinoic acid receptors (RAR) was also affected by RA treatment, specifically RAR gamma transcripts were induced. To further understand the pleiotropic action of RA on myogenesis, we took advantage of two muscle-specific transgene markers which consisted of CAT reporter genes driven by regulatory elements either from the myosin light chain 1/3 locus (MLC-CAT) or the alpha-skeletal actin gene (alpha sk actin-CAT). RA inhibited MLC-CAT transgene but not alpha sk actin-CAT transgene expression in primary cultures from these mice. Analysis of MLC-CAT expression in transgenic mouse primary cultures and in stably transfected C2C12 cells demonstrated that repression of MLC-CAT activity by RA was dependent upon diffusible factors in chick embryo extract. We hypothesize that during development, the pleiotropic effects of RA on myogenesis do not depend solely on the distribution and concentration of RA itself, but are also influenced by extracellular signals in the embryonic environment.

Identification of a novel aspartic-like protease differentially expressed in human breast cancer cell lines.

Four different human breast cancer cell lines were examined to search for genes associated with tumor growth and metastasis. Each of these cell lines, MDA-MB-453, MCF-7, MDA-MB-231 and MDA-MB-435, displays different phenotypic characteristics ranging from poorly to highly tumorigenic and metastatic. The differences in gene expression profiles of these cell lines generated by differential display technique should allow one to identify candidates as putative oncogenes or tumor/metastasis suppressor genes. A novel cDNA expressed in the highly tumorigenic and metastatic cell line, MDA-MB-435, was identified and isolated by this approach. The function for this gene, designated ALP56 (aspartic-like protease 56 kDa), in tumor progression is suggested by the homology of the encoded protein to aspartic proteases, such as cathepsin D. The amino acid residues in two catalytic domains of this family are highly conserved in those domains of ALP56. Northern hybridization indicated that the expression of ALP56 is associated with growth and metastasis of MDA-MB-435 tumors in immunodeficient mice. In situ hybridization of biopsies from breast cancer and colon cancer patients indicated that ALP56 is upregulated in human primary tumors and liver metastasis. These results suggest that this novel gene correlates with human tumor progression.

A transgene target for positional regulators marks early rostrocaudal specification of myogenic lineages.

In transgenic mice, muscle-specific regulatory elements from the myosin light chain (MLC) 1/3 locus drive graded expression of a linked CAT reporter gene in selected fast muscles along the anteroposterior axis of the adult animal. The gradient of MLC-CAT transcripts is established early in development, during the generation of somites from the paraxial mesoderm and the activation of myogenic factor gene expression, and is not reflected in the expression of the endogenous MLC1 gene. At later embryonic stages, the gradient of MLC-CAT transcripts persists in intercostal and intervertebral muscles, but is not maintained in other axial muscles. Profiles of CAT transgene activity reveal that the gradient is generated during the maturation of increasingly caudal somites, opposite to the direction of somite development, and is retained in dissociated somite cultures. We propose that coexpression of myogenic factors is necessary but not sufficient to regulate expression of the MLC-CAT transgene, which is responsive to additional positional cues in the embryo.

Role of methylation in maintenance of positionally restricted transgene expression in developing muscle.

In transgenic mouse embryos, expression of a muscle-specific reporter, consisting of a chloramphenicol acetyltransferase gene linked to regulatory sequences from the rat myosin light chain 1/3 locus (MLC-CAT), is graded in developing axial muscles along the rostrocaudal axis and in cell cultures derived from these muscles. Here we demonstrate that maintenance of positional differences in MLC-CAT transgene expression cannot be attributed to differences in the transcriptional competence of corresponding muscles. Rather, patterns of transgene expression are reflected in the extent of CpG demethylation of both MLC1 promoter and MLC enhancer sequences. Variations in reporter gene expression can be reconstituted by in vitro methylation of specific CpGs in transfected MLC-CAT DNA. As the MLC-CAT transgene is activated during embryogenesis, demethylation of the MLC1 promoter lags behind that of the downstream MLC enhancer, which appears to be the initial target for epigenetic modification. In developing somites, demethylation of the transgenic MLC enhancer is not graded and therefore does not reflect early regional differences in MLC-CAT transgene expression patterns. These studies implicate selective methylation in the maintenance rather than in the establishment of transcriptional differences in developing muscles.

Muscle-specific cell ablation conditional upon Cre-mediated DNA recombination in transgenic mice leads to massive spinal and cranial motoneuron loss.

We describe here a binary transgenic system based on Cre-mediated DNA recombination for genetic cell ablation in mice that enabled us to obtain skeletal muscle-deficient embryos by mating two phenotypically normal transgenic lines. In those embryos, skeletal muscles are eliminated as a consequence of the expression of the gene encoding the diphtheria toxin A fragment. Cell ablation occurs gradually beginning approximately on embryonic day (E) 12.5, and by E18-5 almost all skeletal muscle is absent. Analysis of the consequences of muscle cell ablation revealed that almost all spinal motoneurons are lost by E18.5, providing strong evidence that survival of spinal motoneurons during embryogenesis is dependent on signals from their target tissue, skeletal muscle, and that trophic signals produced by nonmuscle sources are sufficient to support survival of no more than 10% of embryonic spinal motoneurons in the absence of muscle-derived signals. There was also substantial loss of cranial (hypoglossal and facial) motoneurons in the muscle-deficient embryos, thus indicating that cranial motoneuron survival is also dependent on trophic signals produced by their target tissue. Although spinal motoneurons are a major target of spinal interneurons, the loss of motoneurons did not affect interneuron survival. Muscle-deficient embryos had a cleft palate and abnormalities of the lower jaw, raising the possibility that they might serve as a mouse model for the human disorder, Robin sequence. The data reported here demonstrate the utility of a binary transgenic system for obtaining mouse embryos in which a specific cell population has been ablated, so that its role in embryonic development can be studied.

The chick limbless mutation causes abnormalities in limb bud dorsal-ventral patterning: implications for the mechanism of apical ridge formation.

In chick embryos homozygous for the limbless mutation, limb bud outgrowth is initiated, but a morphologically distinct apical ridge does not develop and limbs do not form. Here we report the results of an analysis of gene expression in limbless mutant limb buds. Fgf4, Fgf8, Bmp2 and Msx2, genes that are expressed in the apical ridge of normal limb buds, are not expressed in the mutant limb bud ectoderm, providing molecular support for the hypothesis that limb development fails in the limbless embryo because of the inability of the ectoderm to form a functional ridge. Moreover, Fgf8 expression is not detected in the ectoderm of the prospective limb territory or the early limb bud of limbless embryos. Since the early stages of limb bud outgrowth occur normally in the mutant embryos, this indicates that FGF8 is not required to promote initial limb bud outgrowth. In the absence of FGF8, Shh is also not expressed in the mutant limb buds, although its expression can be induced by application of FGF8-soaked beads. These observations support the hypothesis that Fgf8 is required for the induction of Shh expression during normal limb development. Bmp2 expression was also not detected in mutant limb mesoderm, consistent with the hypothesis that SHH induces its expression. In contrast, SHH is not required for the induction of Hoxd11 or Hoxd13 expression, since expression of both these genes was detected in the mutant limb buds. Thus, some aspects of mesoderm A-P patterning can occur in the absence of SHH and factors normally expressed in the apical ridge. Intriguingly, mutant limbs rescued by local application of FGF displayed a dorsalized feather pattern. Furthermore, the expression of Wnt7a, Lmx1 and En1, genes involved in limb D-V patterning, was found to be abnormal in mutant limb buds. These data suggest that D-V patterning and apical ridge formation are linked, since they show that the limbless mutation affects both processes. We present a model that explains the potential link between D-V positional information and apical ridge formation, and discuss the possible function of the limbless gene in terms of this model.

An E box comprises a positional sensor for regional differences in skeletal muscle gene expression and methylation.

To dissect the molecular mechanisms conferring positional information in skeletal muscles, we characterized the control elements responsible for the positionally restricted expression patterns of a muscle-specific transgene reporter, driven by regulatory sequences from the MLC1/3 locus. These sequences have previously been shown to generate graded transgene expression in the segmented axial muscles and their myotomal precursors, fortuitously marking their positional address. An evolutionarily conserved E box in the MLC enhancer core, not recognized by MyoD, is a target for a nuclear protein complex, present in a variety of tissues, which includes Hox proteins and Zbu1, a DNA-binding member of the SW12/SNF2 gene family. Mutation of this E box in the MLC enhancer has only a modest positive effect on linked CAT gene expression in transfected muscle cells, but when introduced into transgenic mice the same mutation elevates CAT transgene expression in skeletal muscles, specifically releasing the rostral restriction on MLC-CAT transgene expression in the segmented axial musculature. Increased transgene activity resulting from the E box mutation in the MLC enhancer correlates with reduced DNA methylation of the distal transgenic MLC1 promoter as well as in the enhancer itself. These results identify an E box and the proteins that bind to it as a positional sensor responsible for regional differences in axial skeletal muscle gene expression and accessibility.

The cloning and developmental expression of unconventional myosin IXA (MYO9A) a gene in the Bardet-Biedl syndrome (BBS4) region at chromosome 15q22-q23.

Bardet-Biedl Syndrome (BBS) is a heterogeneous, autosomal recessive disorder characterized by mental retardation, obesity, retinitis pigmentosa, syndactyly and/or polydactyly, short stature, and hypogenitalism and is caused by mutations at a number of distinct loci. Using a positional cloning approach for identifying the BBS4 (chromosome 15) gene, we identified and cloned an unconventional myosin gene, myosin IXA (HGMW-approved symbol MYO9A). Since mutations in unconventional myosins are known to cause several human diseases, and since mutations of unconventional myosin VIIa cause retinal degeneration, we evaluated myosin IXA as a candidate for BBS. We exploited PCR-based techniques to clone a 8473-nt cDNA for myosin IXA. A 7644-bp open reading frame predicts a protein with all the hallmarks of class IX unconventional myosins. Human Northern blot analysis and in situ hybridization of mouse embryos reveal that myosin IXA is expressed in many tissues consistent with BBS. Intron/exon boundaries were identified, and myosin IXA DNA and RNA from BBS4 patients were evaluated for mutation.