Antisense oligonucleotides extend survival and reverse decrement in muscle response in ALS models
Alex McCampbell, … , Eric E. Swayze, Timothy M. Miller
Alex McCampbell, … , Eric E. Swayze, Timothy M. Miller
Published July 16, 2018
Citation Information: J Clin Invest. 2018;128(8):3558-3567. https://doi.org/10.1172/JCI99081.
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Research Article Neuroscience

Antisense oligonucleotides extend survival and reverse decrement in muscle response in ALS models

Abstract

Mutations in superoxide dismutase 1 (SOD1) are responsible for 20% of familial ALS. Given the gain of toxic function in this dominantly inherited disease, lowering SOD1 mRNA and protein is predicted to provide therapeutic benefit. An early generation antisense oligonucleotide (ASO) targeting SOD1 was identified and tested in a phase I human clinical trial, based on modest protection in animal models of SOD1 ALS. Although the clinical trial provided encouraging safety data, the drug was not advanced because there was progress in designing other, more potent ASOs for CNS application. We have developed next-generation SOD1 ASOs that more potently reduce SOD1 mRNA and protein and extend survival by more than 50 days in SOD1G93A rats and by almost 40 days in SOD1G93A mice. We demonstrated that the initial loss of compound muscle action potential in SOD1G93A mice is reversed after a single dose of SOD1 ASO. Furthermore, increases in serum phospho-neurofilament heavy chain levels, a promising biomarker for ALS, are stopped by SOD1 ASO therapy. These results define a highly potent, new SOD1 ASO ready for human clinical trial and suggest that at least some components of muscle response can be reversed by therapy.

Authors

Alex McCampbell, Tracy Cole, Amy J. Wegener, Giulio S. Tomassy, Amy Setnicka, Brandon J. Farley, Kathleen M. Schoch, Mariah L. Hoye, Mark Shabsovich, Linhong Sun, Yi Luo, Mingdi Zhang, Nicole Comfort, Bin Wang, Jessica Amacker, Sai Thankamony, David W. Salzman, Merit Cudkowicz, Danielle L. Graham, C. Frank Bennett, Holly B. Kordasiewicz, Eric E. Swayze, Timothy M. Miller

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Figure 5

SOD1 ASO lowers SOD1 in nonhuman primate CNS and CSF.

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SOD1 ASO lowers SOD1 in nonhuman primate CNS and CSF. (A–C) The safety o...
(AC) The safety of the ASO was assessed in cynomolgus monkeys, which also provided an opportunity to understand the on-target activity of the ASO and the utility of SOD1 in the cerebrospinal fluid as a marker of target suppression in the tissue. Monkeys were dosed with artificial CSF or 4, 12, or 35 mg ASO 1, with each monkey receiving 5 doses. One week after the final dose, SOD1 mRNA and protein were quantified and associated with ASO concentration across brain regions. (A) A dose-dependent lowering of mRNA across CNS regions, including the lumbar spinal cord, was observed (n = 6, average ± SEM). L, lumbar; Th, thoracic; Cerv, cervical; Fr, frontal cortex; Motor, motor cortex; Hip, hippocampus; Pons, pons; Cb, cerebellum. (B) A pharmacokinetic/pharmacodynamic relationship could be observed, with an estimated IC50 of 20 μg/g tissue (n = 126, each point representing one tissue). (C) A dose-dependent lowering of SOD1 protein across CNS regions, including the lumbar spinal cord, was observed (n = 6, average ± SEM). aCSF, artificial CSF. (D) A dose-dependent lowering of SOD1 protein in CSF as compared with the vehicle-treated group was observed (n = 6; line, average; 4 mg, P = 0.0019; 12 mg, P = 0.0006; 35 mg, P = 0.0003; 1-way ANOVA). **P < 0.005; ***P < 0.001. (E) CSF SOD1 protein remains significantly reduced as compared with day 0, roughly 100 days following the last intrathecal ASO administration (n = 6, average ± SEM; ****P = 0.0001; 1-way ANOVA).