Myotonic dystrophy (dystrophia myotonica, DM) is an autosomal dominant genetic disease, with a diagnosed prevalence of 1:8000 people worldwide, that affects multiple tissues of the body, including skeletal muscle, heart, and related to this proposal, the central nervous system (CNS). DM1 is caused by expanded CTG repeats in the 3' UTR of dystrophia myotonica protein kinase (DMPK). There is substantial evidence in mouse DM1 models and human DM1 postmortem tissue to support an RNA-mediated disease mechanism where toxic intranuclear CUG RNA foci sequester Muscleblind (MBNL) RNA binding proteins that normally play crucial roles to regulate various aspects of post-transcriptional gene regulation. A major gap in our understanding is that we do not know which RNA processing defects underlie specific impairments in DM1 brain function. Recent work together with our new findings suggests that missplicing of RNAs encoding synaptic proteins is responsible for CNS dysfunction in DM1. Our central hypothesis is that CNS phenotypes are directly attributed to loss of MBNL mediated RNA processing and that restoration of MBNL activity and/or splicing can restore brain function. Our goal is to gain a thorough understanding of RNA processing-mediated mechanisms of CNS dysfunction in DM1 and use this to develop and rigorously evaluate novel therapeutic strategies. The overall objectives of this proposal are to use both candidate and genome wide approaches, applied to MBNL KO mice and a new AAV9 based neuronal mouse model, compared to RNAseq analysis of human postmortem brain, to evaluate the role of specific splicing events to drive symptoms, and to comprehensively identify changes in missplicing and RNA processing.
Aim 1 will characterize how dysregulation of GABRG2, GRIN1, and SNAP25 splicing events is linked to molecular, cellular, and behavioral phenotypes observed in DM1.
Aim 2 will develop a new AAV9 based mouse model to elucidate the set of RNA processing events in neurons that cause DM1 phenotypes, through transcriptional profiling and overlap of human DM brains with DM mouse model brains.
Aim 3 will assess the extent to which antisense oligonucleotides or MBNL expression can rescue molecular, cellular, physiologic and behavioral phenotypes in DM1 mouse models. These studies will provide new mechanistic insights into how perturbations to specific RNA processing events can lead to CNS symptoms in myotonic dystrophy, and provide a broader comprehensive view of all transcriptome changes occurring in the DM CNS. The proposed work is significant, as no molecular changes have been linked to any phenotypes in the DM CNS. This provides the framework for future therapeutic efforts aimed at correcting CNS defects.
The proposed research is relevant to public health, since it is focused on acquiring an understanding of the molecular events that lead to impaired brain function in myotonic dystrophy, DM1. RNA processing changes including mis-splicing have been observed, but no molecular changes have been directly linked to clinical phenotypes in the DM1 CNS. The aim of this project is to utilize vertebrate animal models and human patient brain tissue to determine which MBNL-dependent RNA processing defects contribute to specific aspects of brain dysfunction in DM1. This research further evaluates the efficacy and mechanism of potential therapeutic strategies to improve brain function in myotonic dystrophy.
