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Uncovering the Role of Hypermethylation by CTG Expansion in Myotonic Dystrophy Type 1 Using Mutant Human Embryonic Stem Cells

CTG repeat expansion in DMPK, the cause of myotonic dystrophy type 1 (DM1), frequently results in hypermethylation and reduced SIX5 expression. The contribution of hypermethylation to disease pathogenesis and the precise mechanism by which SIX5 expression is reduced are unknown. Using 14 different D...

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Published in:Stem cell reports 2015-08, Vol.5 (2), p.221-231
Main Authors: Yanovsky-Dagan, Shira, Avitzour, Michal, Altarescu, Gheona, Renbaum, Paul, Eldar-Geva, Talia, Schonberger, Oshrat, Mitrani-Rosenbaum, Stella, Levy-Lahad, Ephrat, Birnbaum, Ramon Y., Gepstein, Lior, Epsztejn-Litman, Silvina, Eiges, Rachel
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Language:English
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Summary:CTG repeat expansion in DMPK, the cause of myotonic dystrophy type 1 (DM1), frequently results in hypermethylation and reduced SIX5 expression. The contribution of hypermethylation to disease pathogenesis and the precise mechanism by which SIX5 expression is reduced are unknown. Using 14 different DM1-affected human embryonic stem cell (hESC) lines, we characterized a differentially methylated region (DMR) near the CTGs. This DMR undergoes hypermethylation as a function of expansion size in a way that is specific to undifferentiated cells and is associated with reduced SIX5 expression. Using functional assays, we provide evidence for regulatory activity of the DMR, which is lost by hypermethylation and may contribute to DM1 pathogenesis by causing SIX5 haplo-insufficiency. This study highlights the power of hESCs in disease modeling and describes a DMR that functions both as an exon coding sequence and as a regulatory element whose activity is epigenetically hampered by a heritable mutation. [Display omitted] •We identify a disease-associated, differentially methylated region in DM1 hESCs•CTG expansion size correlates with the degree of methylation specifically in DM1 hESCs•DMPK hypermethylation hampers the activity of a regulatory element for SIX5•DM1 hESCs provide an opportunity to study diseased cardiomyocytes in vitro Eiges and colleagues used a large cohort of myotonic dystrophy type 1-affected hESCs to characterize a disease-associated, differentially methylated region that hypermethylates as a function of expansion size and, when unmethylated, promotes the expression of a neighboring gene, SIX5, in undifferentiated cells and in in vitro-differentiated cardiomyocytes.
ISSN:2213-6711
2213-6711
DOI:10.1016/j.stemcr.2015.06.003