Neurobiology of Disease (Oct 2020)

Accelerated transsulfuration metabolically defines a discrete subclass of amyotrophic lateral sclerosis patients

  • Qiuying Chen,
  • Csaba Konrad,
  • Davinder Sandhu,
  • Dipa Roychoudhury,
  • Benjamin I. Schwartz,
  • Roger R. Cheng,
  • Kirsten Bredvik,
  • Hibiki Kawamata,
  • Elizabeth L. Calder,
  • Lorenz Studer,
  • Steven.M. Fischer,
  • Giovanni Manfredi,
  • Steven.S. Gross

Journal volume & issue
Vol. 144
p. 105025

Abstract

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Amyotrophic lateral sclerosis is a disease characterized by progressive paralysis and death. Most ALS-cases are sporadic (sALS) and patient heterogeneity poses challenges for effective therapies. Applying metabolite profiling on 77-sALS patient-derived-fibroblasts and 43-controls, we found ~25% of sALS cases (termed sALS-1) are characterized by transsulfuration pathway upregulation, where methionine-derived-homocysteine is channeled into cysteine for glutathione synthesis. sALS-1 fibroblasts selectively exhibited a growth defect under oxidative conditions, fully-rescued by N-acetylcysteine (NAC). [U13C]-glucose tracing showed transsulfuration pathway activation with accelerated glucose flux into the Krebs cycle. We established a four-metabolite support vector machine model predicting sALS-1 metabotype with 97.5% accuracy. Both sALS-1 metabotype and growth phenotype were validated in an independent cohort of sALS cases. Importantly, plasma metabolite profiling identified a system-wide cysteine metabolism perturbation as a hallmark of sALS-1. Findings reveal that sALS patients can be stratified into distinct metabotypes with differential sensitivity to metabolic stress, providing novel insights for personalized therapy.

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