Spatiotemporal dynamics of molecular pathology in amyotrophic lateral sclerosis

Silas Maniatis(New York Genome Center), Tarmo Äijö(Flatiron Health (United States)), Sanja Vicković(Broad Institute), Catherine Braine(New York Genome Center), Kristy Kang(New York Genome Center), Annelie Mollbrink(Science for Life Laboratory), Delphine Fagegaltier(New York Genome Center), Žaneta Andrusivová(Science for Life Laboratory), Sami Saarenpää(Science for Life Laboratory), Gonzalo Saiz-Castro(Science for Life Laboratory), Miguel Cuevas(Columbia University), Aaron Watters(Flatiron Health (United States)), Joakim Lundeberg(Science for Life Laboratory), Richard Bonneau(Flatiron Health (United States)), Hemali Phatnani(New York Genome Center)
Science
April 4, 2019
10.1126/science.aav9776
Cited by 454

Abstract

Paralysis occurring in amyotrophic lateral sclerosis (ALS) results from denervation of skeletal muscle as a consequence of motor neuron degeneration. Interactions between motor neurons and glia contribute to motor neuron loss, but the spatiotemporal ordering of molecular events that drive these processes in intact spinal tissue remains poorly understood. Here, we use spatial transcriptomics to obtain gene expression measurements of mouse spinal cords over the course of disease, as well as of postmortem tissue from ALS patients, to characterize the underlying molecular mechanisms in ALS. We identify pathway dynamics, distinguish regional differences between microglia and astrocyte populations at early time points, and discern perturbations in several transcriptional pathways shared between murine models of ALS and human postmortem spinal cords.

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