Project description:Facioscapulohumeral muscular dystrophy (FSHD) is characterised by a progressive degeneration and weakness of skeletal muscle fibers attributed to inappropriate expression of the transcription factor double homeobox 4 (DUX4). However, the cellular events that precede pathology in DUX4 expressing muscle fibers remain incompletely understood. Using recombinant AAV vectors to activate species-specific DUX transcription factors in murine and human skeletal muscle fibers, we developed models for examining DUX4-induced pathology. RNA-sequencing prior to the onset of muscle pathology reveals that perturbation of metabolic and mitochondrial function is an early event following activation of DUX transcription factors across species. A reduction in mitochondrial membrane potential was confirmed following DUX4 activation in human muscle fibers prior to reductions in force generating capacity. These studies present new models that can be used to delineate the changes in biological processes following acute DUX4 activation in mouse and human skeletal muscle fibers, for greater insight into the pathogenesis of FSHD, and support further investigation of mitochondrial function as a therapeutic target in FSHD.

Project description:The FSHD effector protein Dux promotes myopathy via Myostatin-Smad signaling

Project description:Age-related frailty may in part be due to a decreased competency in skeletal muscle regeneration. The role of the closely related TGFbeta amily molecules myostatin and GDF11 in regeneration is unclear. The commercially available antibody which in a prior report was used to demonstrate an age-related decrease in GDF11 was found to detect both GDF11 and myostatin, and with this reagent it appears that the combination of GDF11 and myostatin increases with age in serum. Mechanistically, GDF11 and myostatin induce SMAD2/3 phosphorylation, and both inhibit myoblast differentiation and regulate identical downstream signaling. GDF11 injected into adult mice in a model of regeneration induces an increase in smaller fibers and a decrease in satellite cell expansion. There are no signs of benefit from GDF11 to regeneration. Thus, GDF11 appears to be an age-associated myokine that inhibits muscle differentiation, and is thus a target for blockade to treat frailty

Project description:DUX4 activates the first wave of zygotic gene expression in the early embryo. Mis-expression of DUX4 in skeletal muscle causes facioscapulohumeral dystrophy (FSHD), whereas expression in cancers suppresses IFNg-induction of MHC Class I and contributes to immune evasion. We show that the DUX4 protein broadly suppresses immune signaling pathways—including IFNg, IFNb, DDX58, IFIH1 and cGAS mediated pathways. A conserved region containing (L)LxxL(L) motifs in the DUX4 carboxyterminal domain (CTD) was necessary to suppress interferon stimulated genes (ISGs). Co-immunoprecipitation identified DUX4-CTD interaction with multiple immune signaling factors, including STAT1. The DUX4-CTD (L)LxxL(L) region interacts with phosphorylated STAT1, sequesters it in the nucleus, modestly reduces its DNA binding, and prevents STAT1 from inducing ISG transcription. Mouse Dux similarly interacted with STAT1 and suppressed IFNg induction of ISGs. These findings identify an evolved role of the DUXC family in modulating immune signaling pathways with implications for development, cancers, and FSHD.

Project description:Because myostatin normally limits skeletal muscle growth, there is an extensive effort to develop myostatin inhibitors for clinical use. One potential concern is that in patients with muscle degenerative diseases, inducing hypertrophy may increase stress on dystrophic fibers. Here, we show that blocking the myostatin pathway in dysferlin mutant mice results in early improvement in histopathology but ultimately accelerates muscle degeneration. Hence, benefits of this approach should be weighed against these potential detrimental effects.

Project description:Human DUX4 and mouse Dux transcription factors are normally expressed in the germ line and early embryonic cells where they activate the cleavage stage genes. The misexpression of DUX4 in skeletal muscles causes Facioscapulohumeral dystrophy (FSHD). In primates and rodents, DUX4 and Dux arose from retrotransposition of the mRNA from the ancestral intron-containing DUXC, which is not found in these species, and whether it has similar roles in the cleavage stage and FSHD as DUX4 and Dux are unknown. Here, we identified two isoforms of DUXC in canine testis tissues: One encodes the canonical double homeodomain (DUXC) similar to DUX4/Dux, and one contains an extra exon that disrupts the conserved amino-acid sequence of the first homeodomain (DUXC-ALT). We expressed DUXC and DUXC-ALT in canine skeletal muscle and found that the expression of DUXC induced retrotransposons and pluripotent programs similar to DUX4 and Dux, whereas DUXC-ALT did not robustly activate genes in these assays.

Project description:Human DUX4 and mouse Dux transcription factors are normally expressed in the germ line and early embryonic cells where they activate the cleavage stage genes. The misexpression of DUX4 in skeletal muscles causes Facioscapulohumeral dystrophy (FSHD). In primates and rodents, DUX4 and Dux arose from retrotransposition of the mRNA from the ancestral intron-containing DUXC, which is not found in these species, and whether it has similar roles in the cleavage stage and FSHD as DUX4 and Dux are unknown. Here, we identified two isoforms of DUXC in canine testis tissues: One encodes the canonical double homeodomain (DUXC) similar to DUX4/Dux, and one contains an extra exon that disrupts the conserved amino-acid sequence of the first homeodomain (DUXC-ALT). We expressed DUXC and DUXC-ALT in canine skeletal muscle and found that the expression of DUXC induced retrotransposons and pluripotent programs similar to DUX4 and Dux, whereas DUXC-ALT did not robustly activate genes in these assays.

Project description:DUX4 and its mouse ortholog Dux are normally expressed in the early embryo—the 4 cell or 2 cell cleavage stage embryo, respectively—and activate a portion of the first wave of zygotic gene expression. DUX4 is epigenetically suppressed in nearly all somatic tissue, whereas FSHD-causing mutations result in its aberrant expression in skeletal muscle, transcriptional activation of the early embryonic program, and subsequent muscle pathology. Although DUX4 and Dux both activate an early totipotent transcriptional program, divergence of their DNA binding domains limits the use of DUX4 expressed in mice as a pre-clinical model for FSHD. In this study, we identify the porcine DUXC mRNA expressed in early development and show that both pig DUXC and human DUX4 robustly activate a highly similar early embryonic program in pig muscle cells. These results support further investigation of pig preclinical models for FSHD.

Project description:Facioscapulohumeral dystrophy (FSHD) is caused by decreased epigenetic repression of the D4Z4 macrosatellite array and recent studies have shown that this results in the expression of low levels of the DUX4 mRNA in skeletal muscle. Several other mechanisms have been suggested for FSHD pathophysiology and it remains unknown whether DUX4 expression can account for most of the molecular changes seen in FSHD. Since DUX4 is a transcription factor, we used RNA-seq to measure gene expression in muscle cells transduced with DUX4, and in muscle cells and biopsies from control and FSHD individuals. We show that DUX4 target gene expression is the major molecular signature in FSHD muscle together with a gene expression signature consistent with an immune cell infiltration. In addition, one unaffected individual without a known FSHD-causing mutation showed expression of DUX4 target genes. This individual has a sibling with FSHD and also without a known FSHD-causing mutation, suggesting the presence of yet unidentified modifier locus for DUX4 expression and FSHD. These findings demonstrate that expression of DUX4 accounts for the majority of the gene expression changes in FSHD skeletal muscle together with an immune cell infiltration. RNA-seq for muscle cells and biopsies from control and FSHD individuals.

Project description:Facioscapulohumeral dystrophy (FSHD; OMIM #158900, #158901) is caused by mis-expression of the DUX4 transcription factor in skeletal muscle1. Animal models of FSHD are hampered by incomplete knowledge of the conservation of the DUX4 transcriptional program in other species. Despite divergence of their binding motifs, both mouse Dux and human DUX4 activate genes associated with cleavage-stage embryos, including MERV-L and ERVL-MaLR retrotransposons, in mouse and human muscle cells respectively. When expressed in mouse cells, human DUX4 maintained modest activation of cleavage-stage genes driven by conventional promoters, but did not activate MERV-L-promoted genes. These findings indicate that the ancestral DUX4-factor regulated genes characteristic of cleavage-stage embryos driven by conventional promoters, whereas divergence of the DUX4/Dux homeodomains correlates with retrotransposon specificity. These results provide insight into how species balance conservation of a core transcriptional program with innovation at retrotransposon promoters and provide a basis for animal models that recreate the FSHD transcriptome.