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ABSTRACT: The MBNL and CELF proteins act antagonistically to control the alternative splicing of specific exons during mammalian postnatal development. This process is dysregulated in myotonic dystrophy because MBNL proteins are sequestered by (CUG)n and (CCUG)n RNAs expressed from mutant DMPK and ZNF9 genes, respectively. While these observations predict that MBNL proteins have a higher affinity for these pathogenic RNAs versus their normal splicing targets, we demonstrate that MBNL1 possesses comparably high affinities for (CUG)n and (CAG)n RNAs as well as a splicing target, Tnnt3. Mapping of a MBNL1-binding site upstream of the Tnnt3 fetal exon indicates that a preferred binding site for this protein is a GC-rich RNA hairpin containing a pyrimidine mismatch. To investigate how pathogenic RNAs sequester MBNL1 in DM1 cells, we used a combination of chemical/enzymatic structure probing and electron microscopy to determine that MBNL1 forms a ring-like structure which binds to the dsCUG helix. While the MBNL1 N-terminal region is required for RNA binding, the C-terminal region mediates homotypic interactions which may stabilize intra- and/or inter-ring interactions. Our results provide a mechanistic basis for dsCUG-induced MBNL1 sequestration and highlight a striking similarity in the binding sites for MBNL proteins on splicing precursor and pathogenic RNAs.
Nucleic Acids Research 02/2007; 35(16):5474-86. · 8.03 Impact Factor
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ABSTRACT: RNA-mediated pathogenesis is a recently developed disease model that proposes that certain types of mutant genes produce toxic transcripts that inhibit the activities of specific proteins. This pathogenesis model was proposed first for the neuromuscular disease myotonic dystrophy (DM), which is associated with the expansion of structurally related (CTG)(n) and (CCTG)(n) microsatellites in two unrelated genes. At the RNA level, these expansions form stable hairpins that alter the pre-mRNA splicing activities of two antagonistic factor families, the MBNL and CELF proteins. It is unclear which altered activity is primarily responsible for disease pathogenesis and whether other factors and biochemical pathways are involved. Here, we show that overexpression of Mbnl1 in vivo mediated by transduction of skeletal muscle with a recombinant adeno-associated viral vector rescues disease-associated muscle hyperexcitability, or myotonia, in the HSA(LR) poly(CUG) mouse model for DM. Myotonia reversal occurs concurrently with restoration of the normal adult-splicing patterns of four pre-mRNAs that are misspliced during postnatal development in DM muscle. Our results support the hypothesis that the loss of MBNL1 activity is a primary pathogenic event in the development of RNA missplicing and myotonia in DM and provide a rationale for therapeutic strategies designed either to overexpress MBNL1 or inhibit MBNL1 interactions with CUG and CCUG repeat expansions.
Proceedings of the National Academy of Sciences 09/2006; 103(31):11748-53. · 9.68 Impact Factor
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ABSTRACT: In myotonic dystrophy (DM), expression of RNA containing expanded CUG or CCUG repeats leads to misregulated alternative splicing of pre-mRNA. The repeat-bearing transcripts accumulate in nuclear foci, together with proteins in the muscleblind family, MBNL1 and MBNL2. In transgenic mice that express expanded CUG repeats, we show that the splicing defect selectively targets a group of exons that share a common temporal pattern of developmental regulation. These exons undergo a synchronized splicing switch between post-natal day 2 and 20 in wild-type mice. During this post-natal interval, MBNL1 protein translocates from a predominantly cytoplasmic to nuclear distribution. In the absence of MBNL1, these physiological splicing transitions do not occur. The splicing defect induced by expanded CUG repeats in mature muscle fibers is closely reproduced by deficiency of MBNL1 but not by deficiency of MBNL2. A parallel situation exists in human DM type 1 and type 2. MBNL1 is depleted from the muscle nucleoplasm because of sequestration in nuclear foci, and the associated splicing defects are remarkably similar to those observed in MBNL1 knockout mice. These results indicate that MBNL1 participates in the post-natal remodeling of skeletal muscle by controlling a key set of developmentally regulated splicing switches. Sequestration of MBNL1, and failure to maintain these splicing transitions, has a pivotal role in the pathogenesis of muscle disease in DM.
Human Molecular Genetics 08/2006; 15(13):2087-97. · 7.64 Impact Factor
