In Vivo Genome Editing Using Novel AAV-PHP Variants Rescues Motor Function Deficits and Extends Survival in a SOD1-ALS Mouse Model

Overview

Journal Gene Ther

Date 2022 Nov 30

PMID 36450833

Authors

Yi A Chen

Mark W Kankel

Sam Hana

Shukkwan Kelly Lau

Maria I Zavodszky

Olivia McKissick

Nicole Mastrangelo

Jessica Dion

Bin Wang

Daniel Ferretti

David Koske

Sydney Lehman

Kathryn Koszka

Helen McLaughlin

Mei Liu

Eric Marshall

Attila J Fabian

Patrick Cullen

Galina Marsh

Stefan Hamann

Michael Craft

Jennifer Sebalusky

H Moore Arnold

Rachelle Driscoll

Adam Sheehy

Yi Luo

Sonia Manca

Thomas Carlile

Chao Sun

Kirsten Sigrist

Alexander McCampbell

Christopher E Henderson

Shih-Ching Lo

Affiliations

Soon will be listed here.

Abstract

CRISPR-based gene editing technology represents a promising approach to deliver therapies for inherited disorders, including amyotrophic lateral sclerosis (ALS). Toxic gain-of-function superoxide dismutase 1 (SOD1) mutations are responsible for ~20% of familial ALS cases. Thus, current clinical strategies to treat SOD1-ALS are designed to lower SOD1 levels. Here, we utilized AAV-PHP.B variants to deliver CRISPR-Cas9 guide RNAs designed to disrupt the human SOD1 (huSOD1) transgene in SOD1 mice. A one-time intracerebroventricular injection of AAV.PHP.B-huSOD1-sgRNA into neonatal H11 SOD1 mice caused robust and sustained mutant huSOD1 protein reduction in the cortex and spinal cord, and restored motor function. Neonatal treatment also reduced spinal motor neuron loss, denervation at neuromuscular junction (NMJ) and muscle atrophy, diminished axonal damage and preserved compound muscle action potential throughout the lifespan of treated mice. SOD1 treated mice achieved significant disease-free survival, extending lifespan by more than 110 days. Importantly, a one-time intrathecal or intravenous injection of AAV.PHP.eB-huSOD1-sgRNA in adult H11 SOD1 mice, immediately before symptom onset, also extended lifespan by at least 170 days. We observed substantial protection against disease progression, demonstrating the utility of our CRISPR editing preclinical approach for target evaluation. Our approach uncovered key parameters (e.g., AAV capsid, Cas9 expression) that resulted in improved efficacy compared to similar approaches and can also serve to accelerate drug target validation.

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