TorsinA restoration in a mouse model identifies a critical therapeutic window for DYT1 dystonia
Jay Li, … , Samuel S. Pappas, William T. Dauer
Jay Li, … , Samuel S. Pappas, William T. Dauer
Published February 2, 2021
Citation Information: J Clin Invest. 2021;131(6):e139606. https://doi.org/10.1172/JCI139606.
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Research Article Neuroscience

TorsinA restoration in a mouse model identifies a critical therapeutic window for DYT1 dystonia

Abstract

In inherited neurodevelopmental diseases, pathogenic processes unique to critical periods during early brain development may preclude the effectiveness of gene modification therapies applied later in life. We explored this question in a mouse model of DYT1 dystonia, a neurodevelopmental disease caused by a loss-of-function mutation in the TOR1A gene encoding torsinA. To define the temporal requirements for torsinA in normal motor function and gene replacement therapy, we developed a mouse line enabling spatiotemporal control of the endogenous torsinA allele. Suppressing torsinA during embryogenesis caused dystonia-mimicking behavioral and neuropathological phenotypes. Suppressing torsinA during adulthood, however, elicited no discernible abnormalities, establishing an essential requirement for torsinA during a developmental critical period. The developing CNS exhibited a parallel “therapeutic critical period” for torsinA repletion. Although restoring torsinA in juvenile DYT1 mice rescued motor phenotypes, there was no benefit from adult torsinA repletion. These data establish a unique requirement for torsinA in the developing nervous system and demonstrate that the critical period genetic insult provokes permanent pathophysiology mechanistically delinked from torsinA function. These findings imply that to be effective, torsinA-based therapeutic strategies must be employed early in the course of DYT1 dystonia.

Authors

Jay Li, Daniel S. Levin, Audrey J. Kim, Samuel S. Pappas, William T. Dauer

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Figure 5

Whole CNS torsinA depletion causes neuropathology only when initiated during CNS development.

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Whole CNS torsinA depletion causes neuropathology only when initiated du...
(A) Representative Nissl-stained sagittal sections from P8 Nes-Tet(TorA) mice after prenatal suppression of torsinA. Scale bar: 500 μm. (B) Representative sagittal sections from P8 Nes-Tet(TorA) mice after prenatal suppression of torsinA immunostained with an antibody targeted to GFAP. Arrows indicate cortical gliosis and the circle outlines gliosis in thalamus. Scale bar: 500 μm. (C) GFAP fluorescence intensity analysis of P8 Nes-Tet(TorA) mice after prenatal suppression of torsinA. GFAP intensity increased in DCN, 7N, RN, thalamus, and cortex. n = 3 per group. (D) Schematic of experimental design for adult suppression of torsinA in the Nestin-Cre field. Light gray (ON) bars represent ages when torsinA is expressed and dark gray (OFF) areas represent ages when torsinA is suppressed. Each color corresponds to an experimental group in subsequent graphs. (E) Representative Nissl and GFAP costained sagittal sections from Nes-Tet(TorA) mice after adult suppression of torsinA. Scale bar: 1 mm. (F) GFAP fluorescence intensity analysis of P250 Nes-Tet(TorA) mice after adult suppression of torsinA. GFAP intensity is unchanged by adult torsinA suppression in all brain regions examined. n = 5 per group. (G) Cell counts of medial DCN neurons in P250 Nes-Tet(TorA) mice after adult suppression of torsinA. n = 5 per group. (H) Cell counts of 7N neurons in P250 Nes-Tet(TorA) mice after adult suppression of torsinA. n = 5 per group. Data analyzed by unpaired t test (C) and 2-way ANOVA (FH). *P < 0.05, **P < 0.01, ***P < 0.001.