Project description:Skeletal muscles are formed in a variety of shapes and sizes, and this diversity impacts muscle function and disease susceptibility. To understand how muscle diversity is generated, we performed gene expression profiling of muscle subsets from Drosophila embryos. By comparing the transcriptional profiles of two muscle subsets, we identified a core group of founder cell-enriched genes. We screened mutant embryos for muscle defects and identified Sin3A and 10 other transcription and chromatin regulators as having novel functions in the Drosophila embryonic somatic musculature. Sin3A is required for the morphogenesis of a subset of muscles, and Sin3A mutants display muscle loss and misattachment. Additionally, misexpression of identity gene transcription factors in Sin3A heterozygous embryos leads to direct transformations of one muscle into another, while overexpression of Sin3A results in the reverse transformation. Our data implicate Sin3A as a key buffer controlling muscle responsiveness to transcription factors in the formation of muscle identity, thereby generating tissue diversity. We used microarray analysis to look for changes in gene expression between different musle founder cell subsets Flies expressing GFP or RFP transgenes were maintained at 25° C on a 12-hour light/12-hour dark cycle in an incubator and fed with yeast paste spread on apple juice agar plates. After a 2-hour pre-lay, flies were allowed to lay for 2 hours; these plates were removed and aged for an additional 8 hours. Embryos were dissociated by dounce homogenization into a single cell suspension as previously described (Dobi et al., 2011). Cells were sorted using standard methods on a Beckton-Dickson FACS Aria Cell Sorter (Estrada and Michelson, 2008). Total cellular RNA from each sample was prepared from sorted cells using TRIzol LS Reagent without amplification (Invitrogen). Total cellular RNA was labeled and hybridized to Drosophila Affymetrix GeneChip 2.0 arrays according to the manufacturers instructions. Three independent sorts were made for each transgene, and each RNA sample was independently labeled and hybridized. For apME-GFP, we sorted 1,000,000 GFP-positive cells from 4 X 108 starting cells, a positive-rate of 0.03%, which yielded 1 μg of RNA. The purity upon resort of the cells was 74%. The purity of S59ME-RFP and twiprom-actin-GFP was 87% and 95%, respectively, with positive-rates and yields also correspondingly higher. Affymetrix microarray data was normalized and compared using Partek Genomics Suite Software. apterousME-GFP and slouchME-RFP-positive cells were compared to twiprom-actin-GFP-expressing cells to generate lists of differentially regulated genes, fold change ≥ 1.7, p-value < 0.05. The Database for Annotation, Visualization and Integrated Discovery (DAVID) v6.7 was used to assign Gene Ontology classifications to the genes identified by the array (Huang et al., 2009a; 2009b). Default parameters were used to perform Functional Annotation of gene lists, p-value < 0.05.

Project description:Muscle development and diversity require a large number of spatially and temporally regulated events controlled by transcription factors (TFs). Drosophila has long stood as a model organism to study myogenesis due to the highly conserved key TFs involved at all stages of muscle development, from specification to differentiation. While many studies focused on the diversification of Drosophila larval musculature, how distinct adult muscle types are generated is much less characterised. Here, we identify a novel essential regulator of Drosophila thoracic flight muscle development, the Hox TF Antennapedia (Antp). Correcting a long standing misconception that flight muscle development occurs without the input of Hox TFs, we show that Antp intervenes at several stages of adult flight muscle development, from the establishment of the progenitor pool in the embryo to myoblast differentiation in the early pupa. Furthermore, the precisely regulated clearance of Hox at the pupal stage in the developing indirect flight muscle fibers is required to allow for stretch-activated fibrillar muscle fate diversification that sets these flight muscles apart from all other adult tubular muscle types.

Project description:Muscle development and diversity require a large number of spatially and temporally regulated events controlled by transcription factors (TFs). Drosophila has long stood as a model organism to study myogenesis due to the highly conserved key TFs involved at all stages of muscle development, from specification to differentiation. While many studies focused on the diversification of Drosophila larval musculature, how distinct adult muscle types are generated is much less characterised. Here, we identify a novel essential regulator of Drosophila thoracic flight muscle development, the Hox TF Antennapedia (Antp). Correcting a long standing misconception that flight muscle development occurs without the input of Hox TFs, we show that Antp intervenes at several stages of adult flight muscle development, from the establishment of the progenitor pool in the embryo to myoblast differentiation in the early pupa. Furthermore, the precisely regulated clearance of Hox at the pupal stage in the developing indirect flight muscle fibers is required to allow for stretch-activated fibrillar muscle fate diversification that sets these flight muscles apart from all other adult tubular muscle types.

Project description:Muscle development and diversity require a large number of spatially and temporally regulated events controlled by transcription factors (TFs). Drosophila has long stood as a model organism to study myogenesis due to the highly conserved key TFs involved at all stages of muscle development, from specification to differentiation. While many studies focused on the diversification of Drosophila larval musculature, how distinct adult muscle types are generated is much less characterised. Here, we identify a novel essential regulator of Drosophila thoracic flight muscle development, the Hox TF Antennapedia (Antp). Correcting a long standing misconception that flight muscle development occurs without the input of Hox TFs, we show that Antp intervenes at several stages of adult flight muscle development, from the establishment of the progenitor pool in the embryo to myoblast differentiation in the early pupa. Furthermore, the precisely regulated clearance of Hox at the pupal stage in the developing indirect flight muscle fibers is required to allow for stretch-activated fibrillar muscle fate diversification that sets these flight muscles apart from all other adult tubular muscle types. This SuperSeries is composed of the SubSeries listed below.

Project description:The Hippo signalling pathway effector protein Yap positively regulates adult skeletal muscle mass and limits muscle atrophy in settings of neuromuscular perturbation. However, the mechanisms that lead to changes in muscle mass following alterations in Yap activity remain unclear. Here, we show in the limb musculature of adult mice, that Yap inhibition alters the expression of genes associated with metabolic capacity, with sustained inhibition of Yap resulting in incomplete metabolism of fatty acids. In the context of metabolic disease, we demonstrate that Yap levels are lower in both the glycolytic skeletal musculature of Lepr db/db mice and in the muscles of insulin-resistant humans. Restoring Yap levels in the striated muscles of Lepr db/db mice was associated with an increase in skeletal muscle oxidative potential and resulted in a reduction in adiposity and hepatic steatosis. Our findings provide the first evidence of a metabolic role for the Hippo pathway effector Yap in post-mitotic skeletal muscle cells and suggest that modulating Yap activity may be an approach to promote skeletal muscle lipid metabolism.

Project description:Our study focuses on understanding the early transcriptional changes taking place during the divergence of the adult muscle precursors that give rise to indirect flight muscles and direct flight muscles in Drosophila. We analyzed the heterogenous cell population of the adult muscle precursors by scRNA-seq and build an integrated single-cell reference atlas. We addressed the differences among muscle-type and different cell state during myoblast differentiation. Also, our dataset includes the transcriptional profile of the epithelial cells localized in the presumptive hinge and notum of third instar larval wing discs. In addition we studied the functional relevance of Amalgam in flight muscle development by depleting Ama expression specifically in the adult muscle precursors. We determined the transcriptional changes and perturbations in AMP cell identity upon Ama knockdown.

Project description:HIBM is a neuromuscular disorder characterized by adult-onset, slowly progressive distal and proximal muscle weakness. Here, gene expression was measured in muscle specimens from 10 HIBM patients carrying the M712T Persian Jewish founder mutation in GNE and presenting with mild histological changes, and from 10 healthy matched control individuals. Experiment Overall Design: Samples were taken from muscle specimens (deltoid, biceps, quadriceps, tibialis), from 10 HIBM patients carrying the M712T Persian Jewish founder mutation in GNE and presenting with mild histological changes. Ages of patients range between 20 to 59. Additional 10 matched samples were taken from healthy control individuals (deltoid, biceps, quadriceps, gluteus, paraspinally and triceps muscles), with age range 18 to 74.

Project description:Our study focuses on understanding the early transcriptional changes taking place during the divergence of the adult muscle precursors that give rise to indirect flight muscles and direct flight muscles in Drosophila. We analyzed the heterogenous cell population of the adult muscle precursors by scRNA-seq and build an integrated single-cell reference atlas. We addressed the differences among muscle-type and different cell state during myoblast differentiation. Also, our dataset includes the transcriptional profile of the epithelial cells localized in the presumptive hinge and notum of third instar larval wing discs. In addition we studied the functional relevance of Amalgam in flight muscle development by depleting Ama expression specifically in the adult muscle precursors. We determined the transcriptional changes and perturbations in AMP cell identity upon Ama knockdown.

Project description:Our study focuses on understanding how Rbf impacts the formation of flight muscles in Drosophila. We analyzed by RNA-seq the transcriptional changes dependent on Rbf in proliferating adult muscle precursors and in mature flight muscles at two different stages of Drosophila development

Project description:RNA-seq was performed on samples of frozen tissue (liver, adipose, skeletal muscle, heart, and pancreatic islets) from the eight founder stains for the Diversity Outbred mice. The mice were fed a high-fat, high-sugar diet to sensitize them to the development of diabetes.