Abstract Details

Title Mechanisms of Neurodegeneration and Mini-gene Therapeutic Approach for Charcot-Marie-Tooth Disease Type 4B3

Topic Child Neurology and Developmental Neurology

Presentation(s) S37 - Emerging Therapies in Child Neurology (4:42 PM-4:54 PM)

Poster/Presentation
Number 007

Background

Charcot-Marie-Tooth Disease type 4B3 (CMT4B3) is a recessive, clinically heterogenous and often severe form of hereditary peripheral neuropathy with onset during infancy or early childhood. Symptoms of CMT4B3 range from an isolated demyelinating sensorimotor polyneuropathy to a complex neurodevelopmental phenotype with axonal neuropathy, cranial nerve involvement, intellectual disability and facial dysmorphism. Mutations in the Sbf1 gene cause CMT4B3 via loss of the pseudo-phosphatase Myotubularin-Related Protein 5 (MTMR5). MTMR5 is an important yet poorly understood regulator of autophagy and endosomal sorting and is involved nervous system development. Gene replacement therapy would be appropriate for CMT4B3, however, the cDNA of Sbf1 is larger (5,679bp) than the size limit of adeno-associated viral vectors (~4,700 bp).

Objective NA

Design/Methods

To circumvent this challenge, we’ve devised several candidate minigenes based on comparative protein family studies, cross-species, and cross-domain investigations. Additionally, we have established a resource of four CMT4B3 patient iPSC lines and derived human motor neurons to both elucidate the mechanism of Sbf1 mutations on axonal degeneration and to validate the mini-gene replacement strategy.

Results

Functional studies in human motor neurons and iPSCs reveal that MTMR2 expression is decreased, while minimal MTMR5 expression remains, indicating that residual, truncated MTMR5 could produce toxic gain-of-function. Both an increase in supernatant NF-L, an axonal injury biomarker, and aberrances in autophagic flux were also identified in the patient motor neurons. We have identified one minigene that recapitulates proper subcellular distribution of MTMR5 in patient-derived fibroblasts, while both co-precipitate with the active binding partner of MTMR5, MTMR2.

Conclusions

Our studies provide evidence that CMT4B3 could occur via axonal mechanisms. Future directions include refinement of fluorescence-based autophagic trafficking assays, identification of novel MTMR5 binding partners and gene expression profiling. Insight from such studies will inform refinement of candidate minigenes and will be used to develop an image-based cellular phenotypic screening platform for CMT4B3.

Authors/Disclosures
Elizabeth H. Jacobs (University of Miami Miller School of Medicine) PRESENTER	An immediate family member of Ms. Jacobs has received personal compensation for serving as an employee of Frida. The institution of Ms. Jacobs has received research support from National Institutes of Health.
Matt Danzi (University of Miami)	Matt Danzi has nothing to disclose.
Adriana Rebelo	No disclosure on file
Stephan Zuchner, MD, FAAN (University of Miami School of Medicine)	Dr. Zuchner has received personal compensation in the range of $500-$4,999 for serving as a Consultant for Applied Therapeutics. The institution of Dr. Zuchner has received research support from Muscular Dystrophy Association. The institution of Dr. Zuchner has received research support from CMT Association. Dr. Zuchner has received intellectual property interests from a discovery or technology relating to health care.
Mario A. Saporta, MD, PhD, FAAN (University of Miami)	Dr. Saporta has received personal compensation in the range of $5,000-$9,999 for serving as a Consultant for SwanBio. Dr. Saporta has received personal compensation in the range of $5,000-$9,999 for serving as a Consultant for Pharnext. Dr. Saporta has received personal compensation in the range of $5,000-$9,999 for serving as a Consultant for Applied Therapeutics.