Macrophage Depletion Blocks Congenital SARM1-dependent Neuropathy

Overview

Journal J Clin Invest

Specialty General Medicine

Date 2022 Oct 26

PMID 36287209

Authors

Caitlin B Dingwall

Amy Strickland

Sabrina W Yum

Aldrin Ky Yim

Jian Zhu

Peter L Wang

Yurie Yamada

Robert E Schmidt

Yo Sasaki

A Joseph Bloom

Aaron DiAntonio

Jeffrey Milbrandt

Affiliations

Soon will be listed here.

Abstract

Axon loss contributes to many common neurodegenerative disorders. In healthy axons, the axon survival factor NMNAT2 inhibits SARM1, the central executioner of programmed axon degeneration. We identified 2 rare NMNAT2 missense variants in 2 brothers afflicted with a progressive neuropathy syndrome. The polymorphisms resulted in amino acid substitutions V98M and R232Q, which reduced NMNAT2 NAD+-synthetase activity. We generated a mouse model to mirror the human syndrome and found that Nmnat2V98M/R232Q compound-heterozygous CRISPR mice survived to adulthood but developed progressive motor dysfunction, peripheral axon loss, and macrophage infiltration. These disease phenotypes were all SARM1-dependent. Remarkably, macrophage depletion therapy blocked and reversed neuropathic phenotypes in Nmnat2V98M/R232Q mice, identifying a SARM1-dependent neuroimmune mechanism as a key driver of disease pathogenesis. These findings demonstrate that SARM1 induced inflammatory neuropathy and highlight the potential of immune therapy as a treatment for this rare syndrome and other neurodegenerative conditions associated with NMNAT2 loss and SARM1 activation.

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