Project description:While the majority of cells contain a single nucleus, cell types such as trophoblasts, osteoclasts, and skeletal myofibers require multinucleation. One advantage of multinucleation can be the assignment of distinct functions to different nuclei, but comprehensive interrogation of transcriptional heterogeneity within multinucleated tissues has been challenging due to the presence of a shared cytoplasm. Here, we utilized single-nucleus RNA-sequencing (snRNA-seq) to determine the extent of transcriptional diversity within multinucleated skeletal myofibers. Nuclei from mouse skeletal muscle were profiled across the lifespan, which revealed the emergence of distinct myonuclear populations in postnatal development and their reactivation in aging muscle. Our datasets also provided a platform for discovery of novel genes associated with rare specialized regions of the muscle cell, including markers of the myotendinous junction and functionally validated factors expressed at the neuromuscular junction. These findings reveal that myonuclei within syncytial muscle fibers possess distinct transcriptional profiles that regulate muscle biology.

Project description:Skeletal muscle myofibers accrue hundreds of nuclei during post-natal development via fusion with activated satellite cells (myoblasts), which is absolutely reliant on expression of the muscle fusogen myomaker (Mymk) in the myoblasts. Using an inducible genetic approach to render myoblasts non-fusogenic (by tamoxifen-inducible Pax7-CreER mediated recombination of the Mymk gene exclusively in satellite cells), we blocked myonuclear accrual at different time-points of post-natal development and thereby titrated the number of nuclei in resultant mutant myofibers. These Microarray assays were carried out on age day 28 (P28) using total RNA isolated from control and mutant muscle to determine changes in transcriptional profiles of these muscles to (a) assess effects of myonuclear titration, and (b) identify adaptive mechanisms elicited in mutant muscles in response to myonuclear deficiency. We used microarrays to generate information about transcriptional profiles in muscles with varying levels of myonuclear deficiencies.

Project description:Multinucleated skeletal muscle cells have an obligatory need to acquire additional nuclei through fusion with activated skeletal muscle stem cells when responding to both developmental and adaptive growth stimuli. A fundamental question in skeletal muscle biology has been the reason underlying this need for new nuclei in syncytial cells that already harbor hundreds of nuclei. To begin to answer this long-standing question, we utilized nuclear RNA-sequencing approaches and developed a lineage tracing strategy capable of defining the transcriptional state of recently fused nuclei and distinguishing this state from that of pre-existing nuclei. Our findings reveal the presence of conserved markers of newly fused nuclei both during development and after a hypertrophic stimulus in the adult. However, newly fused nuclei also exhibit divergent gene expression that is determined by the syncytial environment they fuse into. Moreover, accrual of additional nuclei through fusion is required for nuclei already resident in adult myofibers to mount a normal transcriptional response to a load-induced stimulus. We propose a model of mutual regulation in the control of skeletal muscle development and adaptations, where newly fused and pre-existing myonuclei influence each other to maintain optimal functional growth.

Project description:In order to study the subcellular localization of lncRNAs in myofibers of skeletal muscle, single myofibers were isolated from Soleus, Extensor Digitorum Longus (EDL) and Tibialis Anterior (TA) of 9 mice. RNA was extracted from nuclei and cytoplasmic fractions of 5-10 isolated myofibers and than separately hybridized on microarrays. Preferential expression in nuclear or cytoplasmic compartment of each lncRNA was determined.

Project description:Duchenne muscular dystrophy (DMD) is a fatal muscle disorder characterized by cycles of degeneration and regeneration of multinucleated myofibers and pathological activation of a variety of other associated cell types. Here, we describe the creation of a new mouse model of DMD caused by deletion of exon 51 of the dystrophin gene, which represents a prevalent mutation in humans. To understand the transcriptional abnormalities and heterogeneity associated with the nuclei of myofibers, as well as other mononucleated cell types that contribute to DMD disease pathogenesis, we performed single nucleus transcriptomics of skeletal muscle of mice with exon 51 deletion. Our results reveal distinctive and previously unrecognized myonuclear subtypes within dystrophic myofibers and uncover degenerative and regenerative transcriptional pathways underlying DMD pathogenesis. Our findings provide new insights into the molecular underpinnings of DMD, controlled by the transcriptional activity of different types of muscle and nonmuscle nuclei.

Project description:Duchenne muscular dystrophy (DMD) is a fatal muscle disorder characterized by cycles of degeneration and regeneration of multinucleated myofibers and pathological activation of a variety of other associated cell types. Here, we describe the creation of a new mouse model of DMD caused by deletion of exon 51 of the dystrophin gene, which represents a prevalent mutation in humans. To understand the transcriptional abnormalities and heterogeneity associated with the nuclei of myofibers, as well as other mononucleated cell types that contribute to DMD disease pathogenesis, we performed single nucleus transcriptomics of skeletal muscle of mice with exon 51 deletion. Our results reveal distinctive and previously unrecognized myonuclear subtypes within dystrophic myofibers and uncover degenerative and regenerative transcriptional pathways underlying DMD pathogenesis. Our findings provide new insights into the molecular underpinnings of DMD, controlled by the transcriptional activity of different types of muscle and nonmuscle nuclei.

Project description:Skeletal muscle is composed of multinucleated myofibers, in which nuclei share the cytoplasm, and other cell types. Here, we performed single-nucleus RNA sequencing (snRNA-Seq) to determine the gene expressions in each nucleus in gastrocnemius and plantaris muscles collected from 12-week-old C57BL/6 wild-type mice. Our datasets also provided a basis for comparing gene expressions between myofibers and other cell types and discovering the novel cell populations in muscle tissues.

Project description:Conditions affecting skeletal muscle, such as chronic rotator cuff tears, low back pain, dystrophies, and many others often share changes in muscle phenotype: intramuscular adipose and fibrotic tissue increase while contractile tissue is lost. The underlying changes in cell populations and cell ratios observed with these phenotypic changes complicate the interpretation of tissue-level transcriptional data. Novel single cell transcriptomics has limited capacity to address this problem because muscle fibers are too long to be engulfed in single cell droplets and single nuclei transcriptomics are complicated by muscle fibers’ multinucleation. Therefore, the goal of this project was to evaluate the potential and challenges of a spatial transcriptomics technology to add dimensionality to transcriptional data in an attempt to better understand regional cellular activity in heterogeneous skeletal muscle tissue.

Project description:Skeletal muscle function is vital to movement, thermogenesis and metabolism. Muscle fibers differ in contractile ability, mitochondrial content and metabolic properties and muscle fiber transition influences muscle function. However, the molecular mechanisms regulating muscle fiber transition in muscle function are unclear. Here, in over 150 human muscle samples, we observed that markers of oxidative muscle fiber and mitochondria correlate positively with PPARGC1 and CDK4, and, negatively with CDKN2A, a locus significantly associated with type 2 diabetes. Mice expressing an overactive Cdk4 that cannot bind its inhibitor p16INK4a, a product of the CDKN2A locus, are longer, leaner, exhibit increased oxidative myofibers with superior mitochondrial energetics, display enhanced muscle glucose uptake, and are protected from obesity and diabetes. In contrast, Cdk4-deficiency, or skeletal muscle-specific deletion of Cdk4’s transcriptional target, E2F3, reduces oxidative myofiber numbers, deteriorates mitochondrial function and exercise capacity, while increasing diabetes susceptibility. E2F3 activates the PPARGC1 promoter and CDK4/E2F3/PPARGC1 levels correlate positively with exercise and fitness, and negatively with adiposity, insulin resistance and lipid accumulation in muscle. These findings provide insight into oxidative muscle fiber transition and function that is of relevance to metabolic and muscular diseases.

Project description:Skeletal muscle growth and regeneration rely on myogenic progenitor and satellite cells, the stem cells of postnatal muscle. Elimination of Notch signals during mouse development results in premature differentiation of myogenic progenitors and formation of very small muscle groups. Here we show that this drastic effect is rescued by mutation of the muscle differentiation factor MyoD. However, rescued myogenic progenitors do not assume a satellite cell position and contribute poorly to myofiber growth. The disrupted homing is due to a deficit in basal lamina assembly around emerging satellite cells and to their impaired adhesion to myofibers. On a molecular level, emerging satellite deregulate the expression of basal lamina components and adhesion molecules like integrin a7, collagen XVIIIa1, Megf10 and Mcam. We conclude that Notch signals control homing of satellite cells, stimulating them to contribute to their own microenvironment and to adhere to myofibers. Gene expression analysis using total RNA from FACS-isolated Vcam-1+/CD31-/CD45-/Sca1- embryonic muscle progenitor cells from E17.5 back muscle tissue of MyoD-/-, Pax3cre/+;Rbpjflox/flox;MyoD-/- and Pax3cre/+;DnMamlflox/flox;MyoD-/- mice.