Abstract
Facioscapulohumeral muscular dystrophy (FSHD) is a debilitating muscle disease that currently does not have an effective cure or therapy. The abnormal reactivation of DUX4, an embryonic gene that is epigenetically silenced in somatic tissues, is causal to FSHD. Disease-specific reactivation of DUX4 has two common characteristics, the presence of a non-canonical polyadenylation sequence within exon 3 of DUX4 that stabilizes pathogenic transcripts, and the loss of repressive chromatin modifications at D4Z4, the macrosatellite repeat which encodes DUX4. We used CRISPR/Cas9 to silence DUX4 using two independent approaches. We deleted the DUX4 pathogenic polyadenylation signal, which resulted in downregulation of pathogenic DUX4-fl transcripts. In another approach, we transcriptionally repressed DUX4 by seeding heterochromatin using the dCas9-KRAB platform within exon 3. These feasibility of targeting DUX4 experiments were initially tested in a non-myogenic carcinoma cell line that we have previously characterized. Subsequently, in an immortalized patient myoblast cell line, we demonstrated that targeting DUX4 by either approach led to substantial downregulation of not only pathogenic DUX4 transcripts, but also a subset of its target genes that are known biomarkers of FSHD. These findings offer proof-of-concept of the effect of silencing the polyadenylation sequence on pathogenic DUX4 expression.