Project description:FSHD is characterized by the misexpression of DUX4 in skeletal muscle. Although DUX4 upregulation is thought to be the pathogenic cause of FSHD, DUX4 is lowly expressed in patient samples, and analysis of the consequences of DUX4 expression has largely relied on artificial overexpression. To better understand the native expression profile of DUX4 and its targets, we first performed pooled RNA-seq on a 6-day differentiation time-course in FSHD2 patient-derived primary myoblasts. We identify a set of 54 FSHD-induced genes upregulated in FSHD2 cells starting at day 2 of differentiation through the end of the time-course. Using single-cell and single-nucleus RNA-seq on FSHD2 myoblasts and day 3 and day 5 differentiated myotubes respectively, we captured, for the first time, DUX4 expressed at the single-nucleus level in a native state. We identified two populations of FSHD myotube nuclei based on low or high enrichment of DUX4 and FSHD-induced genes (FSHD-Lo and “FSHD Hi”, respectively). FSHD-Hi nuclei upregulate many cell cycle related genes with significant enrichment of E2F target genes and p53 signaling activation. In FSHD-Hi myotube nuclei, multiple DUX4 target genes are co-expressed including a set of transcription factors, such as DUXA, ZSCAN4 and LEUTX. DUXA (the DUX4 paralog) is more widely expressed than DUX4, and depletion of DUXA suppressed the expression of LEUTX and ZSCAN4 in late, but not early, differentiation. The results indicate that the DUXA can take over the role of DUX4 and maintain target gene expression. These results may provide explanation as to why it is easier to detect and monitor DUX4 target genes than DUX4 itself in patient cells and suggest a self-sustaining network of gene dysregulation that perpetuates this disease after DUX4 is no longer expressed.

Project description:FSHD is characterized by the misexpression of DUX4 in skeletal muscle. Although DUX4 upregulation is thought to be the pathogenic cause of FSHD, DUX4 is lowly expressed in patient samples, and analysis of the consequences of DUX4 expression has largely relied on artificial overexpression. To better understand the native expression profile of DUX4 and its targets, we first performed pooled RNA-seq on a 6-day differentiation time-course in FSHD2 patient-derived primary myoblasts. We identify a set of 54 FSHD-induced genes upregulated in FSHD2 cells starting at day 2 of differentiation through the end of the time-course. Using single-cell and single-nucleus RNA-seq on FSHD2 myoblasts and day 3 and day 5 differentiated myotubes respectively, we captured, for the first time, DUX4 expressed at the single-nucleus level in a native state. We identified two populations of FSHD myotube nuclei based on low or high enrichment of DUX4 and FSHD-induced genes (FSHD-Lo and “FSHD Hi”, respectively). FSHD-Hi nuclei upregulate many cell cycle related genes with significant enrichment of E2F target genes and p53 signaling activation. In FSHD-Hi myotube nuclei, multiple DUX4 target genes are co-expressed including a set of transcription factors, such as DUXA, ZSCAN4 and LEUTX. DUXA (the DUX4 paralog) is more widely expressed than DUX4, and depletion of DUXA suppressed the expression of LEUTX and ZSCAN4 in late, but not early, differentiation. The results indicate that the DUXA can take over the role of DUX4 and maintain target gene expression. These results may provide explanation as to why it is easier to detect and monitor DUX4 target genes than DUX4 itself in patient cells and suggest a self-sustaining network of gene dysregulation that perpetuates this disease after DUX4 is no longer expressed.

Project description:Facioscapulohumeral muscular dystrophy (FSHD) is caused by insufficient epigenetic repression of D4Z4 macrosatellite repeat where DUX4, an FSHD causing gene is embedded. There are two forms of FSHD, FSHD1 with contraction of D4Z4 repeat and FSHD2 with chromatin compaction defects mostly due to SMCHD1 mutation. Previous reports showed DUX4-induced gene expression changes as well as changes in microRNA expression in FSHD muscle cells. However, a genome wide analysis of small noncoding RNAs that might be regulated by DUX4 or by mutations in SMCHD1 has not been reported yet. Here, we identified several types of small noncoding RNAs including known microRNAs that are differentially expressed in FSHD2 muscle cells compared to control. Although fewer small RNAs were differentially expressed during muscle differentiation in FSHD2 cells compared to controls, most of the known myogenic microRNAs, such as miR1, miR133a, and miR206 were induced in both FSHD2 and control muscle cells during differentiation. Our small RNA sequencing data analysis also revealed both DUX4- and SMCHD1-specific changes in FSHD2 muscle cells. Six FSHD2 microRNAs were affected by DUX4 overexpression in control myoblasts, whereas increased expression of tRNAs and 5S rRNAs in FSHD2 muscle cells was largely recapitulated in SMCHD1-depleted control myoblasts. Altogether, our studies suggest that the small noncoding RNA transcriptome changes in FSHD2 might be different from those in FSHD1 and that these differences may provide new diagnostic and therapeutic tools specific to FSHD2.

Project description:Double homeobox genes are unique to eutherian mammals, transiently expressed in early blastomere-stage embryos, and comprise 3 clades (DUXA, B, C) evolved by homeobox duplication and divergence from an ancestral single homeobox gene, sDUX, present in other vertebrates. We test platypus sDUX and find that it drives cytotoxicity and inhibition of myogenesis identical to DUX4, the human DUXC gene. sDUX binds DNA as a head-to-head dimer, with protein core and DNA nearly overlapping the DUX4-DNA crystal structure. Although DUXA lacks transcriptional activity, DUXA-VP64 transcriptome and chromatin accessibility profiles significantly overlap those of DUX4 and sDUX, including expression of ZGA genes and LTR elements. Furthermore, DUXA binds DUX4 sites at most DUX4 target genes and counteracts transcriptional activity of DUX4, including in FSHD patient cells, potentiating a feedback inhibitory loop. The DUX gene family therefore comprises cross-regulating members of opposing function, with implications for their roles in ZGA, FSHD, and cancer.

Project description:Double homeobox genes are unique to eutherian mammals, transiently expressed in early blastomere-stage embryos, and comprise 3 clades (DUXA, B, C) evolved by homeobox duplication and divergence from an ancestral single homeobox gene, sDUX, present in other vertebrates. We test platypus sDUX and find that it drives cytotoxicity and inhibition of myogenesis identical to DUX4, the human DUXC gene. sDUX binds DNA as a head-to-head dimer, with protein core and DNA nearly overlapping the DUX4-DNA crystal structure. Although DUXA lacks transcriptional activity, DUXA-VP64 transcriptome and chromatin accessibility profiles significantly overlap those of DUX4 and sDUX, including expression of ZGA genes and LTR elements. Furthermore, DUXA binds DUX4 sites at most DUX4 target genes and counteracts transcriptional activity of DUX4, including in FSHD patient cells, potentiating a feedback inhibitory loop. The DUX gene family therefore comprises cross-regulating members of opposing function, with implications for their roles in ZGA, FSHD, and cancer.

Project description:Double homeobox genes are unique to eutherian mammals, transiently expressed in early blastomere-stage embryos, and comprise 3 clades (DUXA, B, and C) evolved by homeodomain duplication and divergence from an ancestral single homeobox gene, sDUX, present in non-eutherian mammals and other vertebrates.  We test platypus sDUX and find that it drives cellular phenotypes identical to DUX4, the human DUXC gene, including cytotoxicity and inhibition of myogenic differentiation.  sDUX binds DNA as a head-to-head dimer, showing near overlap of protein core and DNA to the DUX4-DNA crystal structure.  DUXA and sDUX bind both palindromic and nonpalindromic TAAT/TGAT double homeodomain motifs against DUX4 preference for non-palindromic.  Although DUXA lacks transcriptional activation potential, we find significant similarities in transcriptional and chromatin profiles of sDUX with DUX4 and DUXA-VP64, including expression of ZGA genes and LTR elements.  Furthermore, DUXA binds to a significant fraction of DUX4 target sites and is able to counteract transcriptional activation of DUX4 on its targets, potentiating a feedback inhibitory loop, including in cells from patients with facioscapulohumeral muscular dystrophy (FSHD).  The DUX gene family therefore comprises cross-regulating members of opposing function, with implications for their roles in ZGA, FSHD, and cancer.

Project description:Facioscapulohumeral dystrophy (FSHD) is caused by a deletion in a D4Z4 macrosatellite repeat array in the 4q subtelomere that leads to somatic de-repression of the transcription factor DUX4. It is not fully understood how array contractions cause de-repression, but they alter the local chromatin structure of D4Z4, resulting in loss of heterochromatic markers. In order to determine whether pathogenic contractions also alter the nuclear organization of the FSHD locus, we designed an allele-aware, high-throughput circular chromosome conformation capture assay (4C-seq) that distinguishes the two 4q copies of the locus from each other and from a paralogous locus in the 10q subtelomere. Using a short sequence length polymorphism (SSLP) four kilobasepairs from the array as âharacterized the genomic contacts made by the four copies of the FSHD locus in muscle cell nuclei. The SSLP contacts predominate on the same chromosome arm as the bait, decaying rapidly beyond 30-40 Mb. Contacts on other chromosomes were enriched near centromeres and CTCF sites. We also found that the FSHD locus normally contacts regions adjacent to the nuclear lamina and with low overall gene expression. However, we found that the deleted locus in FSHD cells makes more contacts with regions with comparatively lower lamina adjacency and higher overall gene expression than in control cells. Furthermore, association of D4Z4 with components of the nuclear lamina was reduced in FSHD cells relative to control cells. Our results suggest that altered nuclear organization at 4q35 may be one factor in the de-repression of DUX4 in FSHD. 5 primary cells (2 control, 1 FSHD1, 1 FSHD2, and 1 FSHD3) were used to generate 4C libraries in biological duplicate, for a total of 10 4C libraries

Project description:Here, we describe the identification and characterization of p38α as a novel regulator of DUX4 expression in FSHD myotubes. By using multiple highly characterized, potent and specific inhibitors of p38α/β, we show a robust reduction of DUX4 expression, activity and cell death across FSHD1 and FSHD2 patient-derived lines. RNA-seq profiling reveals that a small number of genes are differentially expressed upon p38α/β inhibition, the vast majority of which are DUX4 target genes. Our results reveal a novel and apparently critical role for p38α in the aberrant activation of DUX4 in FSHD and support the potential of p38α/β inhibitors as effective therapeutics to treat FSHD at its root cause.

Project description:The human double-homeodomain retrogene DUX4 is expressed in the testis and epigenetically repressed in somatic tissues. Facioscapulohumeral muscular dystrophy (FSHD) is caused by mutations that decrease the epigenetic repression of DUX4 in somatic tissues and result in mis-expression of this transcription factor in skeletal muscle. DUX4 binds sites in the human genome that contain a double-homeobox sequence motif, including sites in unique regions of the genome as well as many sites in repetitive elements. Using ChIP-seq and RNA-seq on myoblasts transduced with DUX4 we show that DUX4 binds and activates transcription of mammalian apparent LTR-retrotransposons (MaLRs), endogenous retrovirus (ERVL and ERVK) elements, and pericentromeric satellite HSATII sequences. Some DUX4-activated MaLR and ERV elements create novel promoters for genes, long non-coding RNAs, and antisense transcripts. Many of these novel transcripts are expressed in FSHD muscle cells but not control cells, and thus might contribute to FSHD pathology. For example, HEY1, a repressor of myogenesis, is activated by DUX4 through a MaLR promoter. DUX4-bound motifs, including those in repetitive elements, show evolutionary conservation and some repeat-initiated transcripts are expressed in healthy testis, the normal expression site of DUX4, but more rarely in other somatic tissues. Testis expression patterns are known to have evolved rapidly in mammals, but the mechanisms behind this rapid change have not yet been identified: our results suggest that mobilization of MaLR and ERV elements during mammalian evolution altered germline gene expression patterns through transcriptional activation by DUX4. Our findings demonstrate a role for DUX4 and repetitive elements in mammalian germline evolution and in FSHD muscular dystrophy. RNA-seq of differentiated human primary myotube cell lines for FSHD patients and control samples Raw data not provided due to patient privacy concerns.

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.