Facioscapulohumeral dystrophy (FSHD) is characterized by chromatin relaxation of the D4Z4 macrosatellite array on chromosome 4 and expression of the D4Z4-encoded DUX4 gene in skeletal muscle. The more common form, autosomal dominant FSHD1, is caused by a contraction of the D4Z4 array, whereas the genetic determinants and inheritance of D4Z4 array contraction-independent FSHD2 are unclear. Here we show that mutations in SMCHD1 (structural maintenance of chromosomes flexible hinge domain containing 1) on chromosome 18 reduce SMCHD1 protein levels and segregate with genome-wide D4Z4 CpG hypomethylation in human kindreds. FSHD2 occurs in individuals who inherited both the SMCHD1 mutation and a normal-sized D4Z4 array on a chromosome 4 haplotype permissive for DUX4 expression. Reducing SMCHD1 levels in skeletal muscle results in contraction-independent DUX4 expression. Our study identifies SMCHD1 as an epigenetic modifier of the D4Z4 metastable epiallele and as a causal genetic determinant of FSHD2 and possibly other human diseases subject to epigenetic regulation.
Facioscapulohumeral muscular dystrophy (FSHD) is caused by chromatin relaxation that results in aberrant expression of the transcription factor Double Homeobox 4 (DUX4). DUX4 protein is present in a small subset of FSHD muscle cells, making its detection and analysis of its effects historically difficult. Using a DUX4-activated reporter, we demonstrate the burst expression pattern of endogenous DUX4, its method of signal amplification in the unique shared cytoplasm of the myotube, and FSHD cell death that depends on its activation. Transcriptome analysis of DUX4-expressing cells revealed that DUX4 activation disrupts RNA metabolism including RNA splicing, surveillance and transport pathways. Cell signaling, polarity and migration pathways were also disrupted. Thus, DUX4 expression is sufficient for myocyte death, and these findings suggest mechanistic links between DUX4 expression and cell migration, supporting recent descriptions of phenotypic similarities between FSHD and an FSHD-like condition caused by FAT1 mutations.
Deletion of a subset of the D4Z4 macrosatellite repeats in the subtelomeric region of chromosome 4q causes facioscapulohumeral muscular dystrophy (FSHD) when occurring on a specific haplotype of 4qter (4qA161). Several genes have been examined as candidates for causing FSHD, including the DUX4 homeobox gene in the D4Z4 repeat, but none have been definitively shown to cause the disease, nor has the full extent of transcripts from the D4Z4 region been carefully characterized. Using strand-specific RT-PCR, we have identified several sense and antisense transcripts originating from the 4q D4Z4 units in wild-type and FSHD muscle cells. Consistent with prior reports, we find that the DUX4 transcript from the last (most telomeric) D4Z4 unit is polyadenylated and has two introns in its 3-prime untranslated region. In addition, we show that this transcript generates (i) small si/miRNA-sized fragments, (ii) uncapped, polyadenylated 3-prime fragments that encode the conserved C-terminal portion of DUX4 and (iii) capped and polyadenylated mRNAs that contain the double-homeobox domain of DUX4 but splice-out the C-terminal portion. Transfection studies demonstrate that translation initiation at an internal methionine can produce the C-terminal polypeptide and developmental studies show that this peptide inhibits myogenesis at a step between MyoD transcription and the activation of MyoD target genes. Together, we have identified new sense and anti-sense RNA transcripts, novel mRNAs and mi/siRNA-sized RNA fragments generated from the D4Z4 units that are new candidates for the pathophysiology of FSHD.
Adeno-associated virus (AAV) vectors transduce cells by multiple pathways, including integration at nonhomologouschromosomal locations by an unknown mechanism 1-5 . We reasoned that spontaneous chromosome breaks may facilitate vector integration and investigated this in cells containing a specific chromosomal double-strand break created by the endonuclease I-SceI or multiple breaks created by treatment with etoposide or γ-irradiation. Vector proviruses were found at I-SceI cleavage sites, and sequencing of vector-chromosome junctions detected microhomologies, deletions and insertions that were similar when integration occurred spontaneously at random locations or at induced double-strand breaks. Infection with AAV vectors did not increase mutation rates in normal human cells. Our results establish a mechanism for integration and suggest that AAV vectors can integrate at existing chromosome breaks rather than causing breaks themselves, which has implications for their clinical use.We introduced the 18-bp recognition sequence of the I-SceI homing endonuclease into human HT-1080 fibrosarcoma cells by using an integrating foamy retrovirus vector (CSnZPNO; Fig. 1) to create a chromosomal target site for formation of double-strand breaks (DSBs). CSnZPNO is a shuttle vector that allows G418 selection of transduced mammalian cells and propagation of rescued proviruses as bacterial plasmids. We expanded a G418-resistant clone containing a single provirus (HT-1080/CSnZPNO) and infected it with the murine leukemia virus (MLV) vector LSceISHD expressing I-SceI or with the control vector LXSHD lacking I-SceI (Fig. 1). Southern-blot analysis showed that DSBs formed at a fraction of I-SceI target sites in genomic DNA from cells transduced with LSceISHD (Fig. 2c).We infected HT-1080/CSnZPNO cells containing I-SceI-induced breaks at the CSnZPNO chromosomal target site with the AAV2-RH vector encoding hygromycin B kinase (Fig. 1). We analyzed 12 hygromycinresistant cell clones by probing a Southern blot of genomic DNA for target site and AAV vector sequences (Fig. 2). We observed new fragments in several clones (Fig. 2a), indicative of earlier target site cleavage and repair. One of 12 clones contained an AAV vector provirus integrated at the I-SceI site, as shown by hybridization of both target site and AAV vector probes to the same SpeI fragment (Fig. 2a,b) and sequencing of integration junctions (Fig. 3a). We also analyzed integration by rescuing I-SceI target sites as bacterial plasmids from a polyclonal population of hygromycin-resistant HT-1080/CSnZPNO cells transduced by AAV2-RH. Eight of 190 rescued target sites contained the AAV vector (4.2%), as shown by hybridization to vector sequences. In each of these cases, integration occurred at or near the I-SceI site (Figs. 2d and 3a).
Facioscapulohumeral muscular dystrophy (FSHD) represents a major unmet clinical need arising from the progressive weakness and atrophy of skeletal muscles. The dearth of adequate experimental models has severely hampered our understanding of the disease. To date, no treatment is available for FSHD. Human embryonic stem cells (hESCs) potentially represent a renewable source of skeletal muscle cells (SkMCs) and provide an alternative to invasive patient biopsies. We developed a scalable monolayer system to differentiate hESCs into mature SkMCs within 26 days, without cell sorting or genetic manipulation. Here we show that SkMCs derived from FSHD1-affected hESC lines exclusively express the FSHD pathogenic marker double homeobox 4 and exhibit some of the defects reported in FSHD. FSHD1 myotubes are thinner when compared with unaffected and Becker muscular dystrophy myotubes, and differentially regulate genes involved in cell cycle control, oxidative stress response, and cell adhesion. This cellular model will be a powerful tool for studying FSHD and will ultimately assist in the development of effective treatments for muscular dystrophies. STEM CELLS TRANSLATIONAL MEDICINE 2016;5:1145-1161 SIGNIFICANCEThis work describes an efficient and highly scalable monolayer system to differentiate human pluripotent stem cells (hPSCs) into skeletal muscle cells (SkMCs) and demonstrates disease-specific phenotypes in SkMCs derived from both embryonic and induced hPSCs affected with facioscapulohumeral muscular dystrophy. This study represents the first human stem cell-based cellular model for a muscular dystrophy that is suitable for high-throughput screening and drug development.
The integration sites of viral vectors used in human gene therapy can have important consequences for safety and efficacy. However, an extensive evaluation of adeno-associated virus (AAV) vector integration sites has not been completed, despite the ongoing use of AAV vectors in clinical trials. Here we have used a shuttle vector system to isolate and analyze 977 unique AAV vector-chromosome integration junctions from normal human fibroblasts and describe their genomic distribution. We found a significant preference for integrating within CpG islands and the first 1 kb of genes, but only a slight overall preference for transcribed sequences. Integration sites were clustered throughout the genome, including a major preference for integration in ribosomal DNA repeats, and 13 other hotspots that contained three or more proviruses within a 500-kb window. Both junctions were localized from 323 proviruses, allowing us to characterize the chromosomal deletions, insertions, and translocations associated with vector integration. These studies establish a profile of insertional mutagenesis for AAV vectors and provide unique insight into the chromosomal distribution of DNA strand breaks that may facilitate integration.
Facioscapulohumeral muscular dystrophy is a dominantly inherited myopathy associated with chromatin relaxation of the D4Z4 macrosatellite array on chromosome 4. DUX4 is encoded within each unit of the D4Z4 array where it is normally transcriptionally silenced and packaged as constitutive heterochromatin. Truncation of the array to less than 11 D4Z4 units (FSHD1) or mutations in SMCHD1 (FSHD2) results in chromatin relaxation and a small percentage of cultured myoblasts from these individuals exhibit infrequent bursts of DUX4 expression. There are no cellular or animal models to determine the trigger of the DUX4 producing transcriptional bursts and there has been a failure to date to detect the protein in significant numbers of cells from FSHD-affected individuals. Here, we demonstrate for the first time that myotubes generated from FSHD patients express sufficient amounts of DUX4 to undergo DUX4-dependent apoptosis. We show that activation of the Wnt/β-catenin signaling pathway suppresses DUX4 transcription in FSHD1 and FSHD2 myotubes and can rescue DUX4-mediated myotube apoptosis. In addition, reduction of mRNA transcripts from Wnt pathway genes β-catenin, Wnt3A and Wnt9B results in DUX4 activation. We propose that Wnt/β-catenin signaling is important for transcriptional repression of DUX4 and identify a novel group of therapeutic targets for the treatment of FSHD.
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