Project description:Skeletal muscle is the contractile tissue that distributes throughout body, with its functionally heterogeneous properties amongst muscles, which may relate to region specific pathology of muscle diseases. Here we found that homeobox (Hox) genes, key regulators of body-plan in the embryo, are region-specifically and robustly maintained as positional memory in both muscle and its associated stem cells named satellite cells in adult mice and humans. Although satellite cell function in adults was unaffected by genetic loss of Hoxa10 in muscle progenitors at the developmental stage, postnatal deletion of Hoxa10 in satellite cells led to genomic instability and mitosis abnormality, resulting in a remarkable decline in regenerative ability of muscles in a region-specific manner. Our results suggest that Hox-based positional memory is flexibly established during embryonic development and governs topographic function of stem cells in adult muscles once it is fixed, potentially influencing the region-specific weakness in muscle diseases

Project description:Skeletal muscle is contractile tissue distributed throughout the body with functionally heterogeneous properties that may relate to region-specific pathophysiology of muscle diseases. Recent studies revealed that muscle stem cells (satellite cells) are a functional heterogeneous population in different muscles, dependent not only on fiber-types but also on embryonic origin. Homeobox (Hox) genes are key regulators of the embryonic body plan. Here, we showed that Hox-A cluster genes are robustly maintained in adult muscles and their associated satellite cells of both mice and humans in a body region-specific manner, whose distribution almost recapitulates their embryonic origin. The region-specific expression of Hox genes was linked to DNA hypermethylation status of Hox-A locus. Importantly, Hox gene expression is a functional memory; Hoxa10 inactivation in satellite cells led to genomic instability and mitotic catastrophe, resulting in a decline in the regionally specific regenerative ability of muscles in mice, even though Hox paralogs are known to be often functionally redundant. Thus, our results demonstrate that the topographic Hox gene expression profile could be a geotagging molecular signature that reflects the anatomical location and embryonic history of resident muscle stem cells, potentially contributing to regionally specific regulations of adult skeletal muscles.

Project description:Quiescent satellite cells, also known as adult muscle stem cells, possess a remarkable ability to regenerate skeletal muscle upon injury throughout life. Although they mainly originate from multipotent stem/progenitors of the somite, the mechanism underlying the establishment of quiescent satellite cell populations is unknown. Here, we show that sex hormones induce Mind bomb-1 (Mib1) expression in myofibers at puberty, which activates Notch signaling in cycling juvenile satellite cells and causes them to be converted into quiescent adult satellite cells. Myofibers lacking Mib1 failed to send Notch signals to juvenile satellite cells, leading to impaired cell cycle exit and depletion. Genetic and inhibitor studies revealed that the hypothalamic-pituitary-gonadal axis drives Mib1 expression in the myofiber niche. Our data show how sex hormones establish quiescent adult satellite cell populations by regulating the myofiber niche at puberty. Microarray analysis of Veh or DHT-injected 10-day-old mice s.c. injected with Veh or DHT. TA muscles were isolated 24 h after the injection.

Project description:The satellite cell of skeletal muscle provides a paradigm for quiescent and activated tissue stem cell states. We have carried out transcriptome analyses by comparing satellite cells from adult skeletal muscles, where they are mainly quiescent, with cells from growing muscles, regenerating (mdx) muscles, or with cells in culture, where they are activated. Our study gives new insights into the satellite cell biology during activation and in respect with its niche. We used microarrays to study the global programme of gene expression underlying adult satellite cell quiescence compared to activation states and to identify distinct classes of up-regulated genes in these two different states Skeletal muscle satellite cells were isolated by flow cytrometry using the GFP fluorescence marker from Pax3GFP/+ mice skeletal muscle. The transcriptome of quiescent satellite cells from adult Pax3GFP/+ muscle was compared to the transcriptome of activated satellite cells obtained from three different samples: 1) regenerating Pax3GFP/+:mdx/mdx muscle (Ad.mdx) , 2) growing 1 week old Pax3GFP/+ muscle (1wk), and 3) adult Pax3GFP/+ cells after 3 days in culture (Ad.cult).

Project description:TWIST1, a basic helix-loop-helix transcription factor is essential for the development of cranial mesoderm and cranial neural crest-derived craniofacial structures. Our previous work showed that, in the absence of TWIST1, some cells within the cranial mesoderm adopt an abnormal epithelial configuration. Here, we show by transcriptome analysis that loss of TWIST1 in the cranial mesoderm is accompanied by a reduction in the expression of genes that are associated with cell-extracellular matrix interactions and the acquisition of mesenchymal characteristics. By comparing the transcriptional profiles of cranial mesoderm-specific Twist1 loss-of-function mutant and control mouse embryos, we identified a set of genes that are both TWIST1-dependent and predominantly expressed in the mesoderm. By ChIP-seq in a cell line model of a TWIST1-dependent mesenchymal state, we identified, among the downstream genes, three direct transcriptional targets of TWIST1: Ddr2, Pcolce and Tgfbi. Our findings show that the mesenchymal properties of the cranial mesoderm is likely to be regulated by a network of TWIST1 targets genes that influence the extracellular matrix and cell-matrix interactions, and collectively they are required for the morphogenesis of the craniofacial structures. Cranial neural crest and cranial mesoderm cells were isolated by flow sorting of GFP reporter-labelled cells collected from heads of E9.5 mouse embryos. Three replicates were independently isolated and hybridized to Illumina mouse WG v 2.0 chips

Project description:Somites form during embryonic development and give rise to unique cell and tissue types, such as skeletal muscles and bones and cartilages of the vertebrae. Using somitogenesis stage human embryos, we performed the first ever transcriptomic profiling of human presomitic mesoderm as well as nascent and developed somites. Using this approach we uncovered novel regulators unique duing human somitogensis, and efficiently guided human pluripotent stem cells to differentiate to somite cells and downstream progeny. This work improves our understanding of human somite development and may enhance our ability to model and treat diseases affecting somite derivatives.

Project description:The satellite cell of skeletal muscle provides a paradigm for quiescent and activated tissue stem cell states. We have carried out transcriptome analyses by comparing satellite cells from adult skeletal muscles, where they are mainly quiescent, with cells from growing muscles, regenerating (mdx) muscles, or with cells in culture, where they are activated. Our study gives new insights into the satellite cell biology during activation and in respect with its niche. We used microarrays to study the global programme of gene expression underlying adult satellite cell quiescence compared to activation states and to identify distinct classes of up-regulated genes in these two different states

Project description:Quiescent satellite cells, also known as adult muscle stem cells, possess a remarkable ability to regenerate skeletal muscle upon injury throughout life. Although they mainly originate from multipotent stem/progenitors of the somite, the mechanism underlying the establishment of quiescent satellite cell populations is unknown. Here, we show that sex hormones induce Mind bomb-1 (Mib1) expression in myofibers at puberty, which activates Notch signaling in cycling juvenile satellite cells and causes them to be converted into quiescent adult satellite cells. Myofibers lacking Mib1 failed to send Notch signals to juvenile satellite cells, leading to impaired cell cycle exit and depletion. Genetic and inhibitor studies revealed that the hypothalamic-pituitary-gonadal axis drives Mib1 expression in the myofiber niche. Our data show how sex hormones establish quiescent adult satellite cell populations by regulating the myofiber niche at puberty.

Project description:TWIST1, a basic helix-loop-helix transcription factor is essential for the development of cranial mesoderm and cranial neural crest-derived craniofacial structures. Our previous work showed that, in the absence of TWIST1, some cells within the cranial mesoderm adopt an abnormal epithelial configuration. Here, we show by transcriptome analysis that loss of TWIST1 in the cranial mesoderm is accompanied by a reduction in the expression of genes that are associated with cell-extracellular matrix interactions and the acquisition of mesenchymal characteristics. By comparing the transcriptional profiles of cranial mesoderm-specific Twist1 loss-of-function mutant and control mouse embryos, we identified a set of genes that are both TWIST1-dependent and predominantly expressed in the mesoderm. By ChIP-seq in a cell line model of a TWIST1-dependent mesenchymal state, we identified, among the downstream genes, three direct transcriptional targets of TWIST1: Ddr2, Pcolce and Tgfbi. Our findings show that the mesenchymal properties of the cranial mesoderm is likely to be regulated by a network of TWIST1 targets genes that influence the extracellular matrix and cell-matrix interactions, and collectively they are required for the morphogenesis of the craniofacial structures. Chromatin extracts were subject to chromatin immunoprecipitation with anti TWIST1 monoclonal antibody (ChIP-seq). Input chromatin, not subject to ChIP was used as the negative control. Two independent replicate experiments were performed. Purified, immunoprecipitated DNA was sequenced at Australian Genome Research facility.

Project description:Global gene expression patterns were determined from microarray results from sham surgery or following 1 week of plantaris muscle hypertrophy induced by synergist ablation in young adult Pax7-DTA mice (4 months). Vehicle treated mice have their full complement of satellite cells; tamoxifen treated mice have had their satellite cells genetically depleted through Cre-loxP technology After sham surgery or 1 week of overload, Affymetrix chips (mouse430_2.0) were used with 1 µg of total RNA derived from a pooled sample of the right and left plantaris muscles from 11 animals.