神经退行性变
神经科学
多发性硬化
生物
鉴定(生物学)
疾病
中枢神经系统
神经科学家
肌萎缩侧索硬化
心理学
医学
少突胶质细胞
病理
免疫学
髓鞘
植物
作者
Max Kaufmann,Anna-Lena Schaupp,Rosa Sun,Fabian Coscia,Calliope A. Dendrou,Adrián Cortés,Gurman Kaur,Hayley G. Evans,Annelie Mollbrink,José Fernández Navarro,Jana K. Sonner,Christina Mayer,Gabriele C. DeLuca,Joakim Lundeberg,Paul M. Matthews,Kathrine E. Attfield,Manuel A. Friese,Matthias Mann,Lars Fugger
标识
DOI:10.1038/s41593-022-01097-3
摘要
Progressive multiple sclerosis (MS) is characterized by unrelenting neurodegeneration, which causes cumulative disability and is refractory to current treatments. Drug development to prevent disease progression is an urgent clinical need yet is constrained by an incomplete understanding of its complex pathogenesis. Using spatial transcriptomics and proteomics on fresh-frozen human MS brain tissue, we identified multicellular mechanisms of progressive MS pathogenesis and traced their origin in relation to spatially distributed stages of neurodegeneration. By resolving ligand–receptor interactions in local microenvironments, we discovered defunct trophic and anti-inflammatory intercellular communications within areas of early neuronal decline. Proteins associated with neuronal damage in patient samples showed mechanistic concordance with published in vivo knockdown and central nervous system (CNS) disease models, supporting their causal role and value as potential therapeutic targets in progressive MS. Our findings provide a new framework for drug development strategies, rooted in an understanding of the complex cellular and signaling dynamics in human diseased tissue that facilitate this debilitating disease. By complementing spatial transcriptomics with high-resolution proteomics, Kaufmann et al. tracked a gradient of disease severity across the brains of patients with progressive multiple sclerosis, uncovering new therapeutic opportunities to slow disease.
科研通智能强力驱动
Strongly Powered by AbleSci AI