Studies of the epigenetic disease mechanism in FSHD

Facioscapulohumeral muscular dystrophy is an autosomal dominant myopathy that is caused by a contraction of the D4Z4 repeat on the 4qA161 genetic variant of chromosome 4qter (FSHD1). FSHD1 patients show loss of DNA methylation on the first D4Z4 repeat unit. Interestingly, a small group of patients with a myopathy clinically indistinguishable from FSHD1 but without a D4Z4 contraction (FSHD2) and patients suffering from the ICF (Immunodeficiency, Centromeric instability and Facial anomalies) syndrome also present with very low D4Z4 methylation. In this thesis studies are described that focused on the unraveling of the epigenetic disease mechanism responsible for FSHD development. These studies show that (1) the overlap between FSHD patients and ICF patients is restricted to low D4Z4 methylation levels, (2) FSHD1 and FSHD2 patients show loss of methyl groups on lysine 9 of histone protein H3 and a secondary loss of the proteins HP1? and cohesin at the D4Z4 repeat, (3) the combination of the 4qA161 genetic variant and low D4Z4 methylation is a necessary prerequisite for FSHD development and (4) supplementation with folic and methionine can raise the total amount of methyl groups present on the DNA but cannot restore D4Z4 methylation levels in FSHD1 and FSHD2 patients.UBL - phd migration 201

The prospects of targeting DUX4 in facioscapulohumeral muscular dystrophy

Purpose of review Facioscapulohumeral muscular dystrophy (FSHD) is a neuromuscular disorder, which is caused by incomplete repression of the transcription factor double homeobox 4 (DUX4) in skeletal muscle. To date, there is no DUX4-targeting treatment to prevent or delay disease progression. In the present review, we summarize developments in therapeutic strategies with the focus on inhibiting DUX4 and DUX4 target gene expression. Recent findings Different studies show that DUX4 and its target genes can be repressed with genetic therapies using diverse strategies. Additionally, different small compounds can reduce DUX4 and its target genes in vitro and in vivo. Most studies that show DUX4 repression by genetic therapies have only been tested in vitro. More efforts should be made to test them in vivo for clinical translation. Several compounds have been shown to prevent DUX4 and target gene expression in vitro and in vivo. However, their efficiency and specificity has not yet been shown. With emerging clinical trials, the clinical benefit from DUX4 repression in FSHD will likely soon become apparent.Functional Genomics of Muscle, Nerve and Brain Disorder

Dnmt3bregulates DUX4 expression in a tissue-dependent manner in transgenic D4Z4 mice

Background Facioscapulohumeral muscular dystrophy (FSHD) is a skeletal muscle disorder that is caused by derepression of the transcription factor DUX4 in skeletal muscle cells. Apart from SMCHD1, DNMT3B was recently identified as a disease gene and disease modifier in FSHD. However, the exact role of DNMT3B at the D4Z4 repeat array remains unknown. Methods To determine the role of Dnmt3b on DUX4 repression, hemizygous mice with a FSHD-sized D4Z4 repeat array (D4Z4-2.5 mice) were cross-bred with mice carrying an in-frame exon skipping mutation inDnmt3b(Dnmt3b(MommeD14)mice). Additionally, siRNA knockdowns ofDnmt3bwere performed in mouse embryonic stem cells (mESCs) derived from the D4Z4-2.5 mouse model. Results In mESCs derived from D4Z4-2.5 mice, Dnmt3b was enriched at the D4Z4 repeat array and DUX4 transcript levels were upregulated after a knockdown ofDnmt3b. In D4Z4-2.5/Dnmt3b(MommeD14)mice, Dnmt3b protein levels were reduced; however, DUX4 RNA levels in skeletal muscles were not enhanced and no pathology was observed. Interestingly, D4Z4-2.5/Dnmt3b(MommeD14)mice showed a loss of DNA methylation at the D4Z4 repeat array and significantly higher DUX4 transcript levels in secondary lymphoid organs. As these lymphoid organs seem to be more sensitive to epigenetic modifiers of the D4Z4 repeat array, different immune cell populations were quantified in the spleen and inguinal lymph nodes of D4Z4-2.5 mice crossed with Dnmt3b(MommeD14)mice or Smchd1(MommeD1)mice. Only in D4Z4-2.5/Smchd1(MommeD1)mice the immune cell populations were disturbed. Conclusions Our data demonstrates that loss of Dnmt3b results in derepression of DUX4 in lymphoid tissues and mESCs but not in myogenic cells of D4Z4-2.5/Dnmt3b(MommeD14)mice. In addition, the Smchd1(MommeD1)variant seems to have a more potent role in DUX4 derepression. Our studies suggest that the immune system is particularly but differentially sensitive to D4Z4 chromatin modifiers which may provide a molecular basis for the yet underexplored immune involvement in FSHD.Functional Genomics of Muscle, Nerve and Brain Disorder

Systemic delivery of a DUX4-targeting antisense oligonucleotide to treat facioscapulohumeral muscular dystrophy

Facioscapulohumeral muscular dystrophy (FSHD) is one of the most prevalent skeletal muscle dystrophies. Skeletal muscle pathology in individuals with FSHD is caused by inappropriate expression of the transcription factor DUX4, which activates different myotoxic pathways. At the moment there is no molecular therapy that can delay or prevent skeletal muscle wasting in FSHD. In this study, a systemically delivered antisense oligonucleotide (ASO) targeting the DUX4 transcript was tested in vivo in ACTA1-MCM;FLExDUX4 mice that express DUX4 in skeletal muscles. We show that the DUX4 ASO was well tolerated and repressed the DUX4 transcript, DUX4 protein, and mouse DUX4 target gene expression in skeletal muscles. In addition, the DUX4 ASO alleviated the severity of skeletal muscle pathology and partially prevented the dysregulation of inflammatory and extracellular matrix genes. DUX4 ASOtreated ACTA1-MCM;FLExDUX4 mice performed better on a treadmill; however, the hanging grid and four-limb grip strength tests were not improved compared to control ASOtreated ACTA1-MCM;FLExDUX4 mice. This study shows that systemic delivery of ASOs targeting DUX4 is a promising therapeutic strategy for FSHD and strategies that further improve the ASO efficacy in skeletal muscle are warranted.Functional Genomics of Muscle, Nerve and Brain Disorder

Smchd1 haploinsufficiency exacerbates the phenotype of a transgenic FSHD1 mouse model

Functional Genomics of Muscle, Nerve and Brain Disorder

Generation of genetically matched hiPSC lines from two mosaic facioscapulohumeral dystrophy type 1 patients

Facioscapulohumeral dystrophy type 1 (FSHD1) is caused by contraction of the D4Z4 repeat array on chromosome 4q resulting in sporadic misexpression of the transcription factor DUX4 in skeletal muscle tissue. In ~4% of families, de novo D4Z4 contractions occur after fertilization resulting in somatic mosaicism with control and FSHD1 cell populations present within the same patient. Reprogramming of mosaic fibroblasts from two FSHD1 patients into human induced pluripotent stem cells (hiPSCs) generated genetically matched control and FSHD1 hiPSC lines. All hiPSC lines contained a normal karyotype, expressed pluripotency genes and differentiated into cells from the three germ layers

Mouse models for muscular dystrophies: an overview

Muscular dystrophies (MDs) encompass a wide variety of inherited disorders that are characterized by loss of muscle tissue associated with a progressive reduction in muscle function. With a cure lacking for MDs, preclinical developments of therapeutic approaches depend on well-characterized animal models that recapitulate the specific pathology in patients. The mouse is the most widely and extensively used model for MDs, and it has played a key role in our understanding of the molecular mechanisms underlying MD pathogenesis. This has enabled the development of therapeutic strategies. Owing to advancements in genetic engineering, a wide variety of mouse models are available for the majority of MDs. Here, we summarize the characteristics of the most commonly used mouse models for a subset of highly studied MDs, collated into a table. Together with references to key publications describing these models, this brief but detailed overview would be useful for those interested in, or working with, mouse models of MD