Integrated Elemental Analysis Supports Targeting Copper Perturbations As a Therapeutic Strategy in Multiple Sclerosis

Overview

Journal Neurotherapeutics

Specialty Neurology

Date 2024 Aug 20

PMID 39164165

Authors

James B W Hilton

Kai Kysenius

Jeffrey R Liddell

Stephen W Mercer

Carsten Rautengarten

Dominic J Hare

Gojko Buncic

Bence Paul

Simon S Murray

Catriona A McLean

Trevor J Kilpatrick

Joseph S Beckman

Scott Ayton

Ashley I Bush

Anthony R White

Blaine R Roberts

Paul S Donnelly

Peter J Crouch

Affiliations

Soon will be listed here.

Abstract

Multiple sclerosis (MS) is a debilitating affliction of the central nervous system (CNS) that involves demyelination of neuronal axons and neurodegeneration resulting in disability that becomes more pronounced in progressive forms of the disease. The involvement of neurodegeneration in MS underscores the need for effective neuroprotective approaches necessitating identification of new therapeutic targets. Herein, we applied an integrated elemental analysis workflow to human MS-affected spinal cord tissue utilising multiple inductively coupled plasma-mass spectrometry methodologies. These analyses revealed shifts in atomic copper as a notable aspect of disease. Complementary gene expression and biochemical analyses demonstrated that changes in copper levels coincided with altered expression of copper handling genes and downstream functionality of cuproenzymes. Copper-related problems observed in the human MS spinal cord were largely reproduced in the experimental autoimmune encephalomyelitis (EAE) mouse model during the acute phase of disease characterised by axonal demyelination, lesion formation, and motor neuron loss. Treatment of EAE mice with the CNS-permeant copper modulating compound Cu(atsm) resulted in recovery of cuproenzyme function, improved myelination and lesion volume, and neuroprotection. These findings support targeting copper perturbations as a therapeutic strategy for MS with Cu(atsm) showing initial promise.

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