An emergent disease-associated motor neuron state precedes cell death in ALS

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Olivia Gautier, Jacob A Blum, Thao P Nguyen, Shaolong Cao, Sandy Klemm, Mai Yamakawa, Dann Huh, Jessica A Hurt, Nasa Sinnott-Armstrong, Yi Zeng, Chung-Ha O Davis, Juliane Bombosch, Chang Liu, Lisa N Encarnacion, Kevin A Guttenplan, Derek Chen, Arwa Kathiria, Luke Zhao, Stephen Moore, Alex Meng, Kailee Ong, Don W Cleveland, John Ravits, Jessica E Rexach, William J Greenleaf, Aaron D Gitler,
To define molecular determinants of motor neuron degeneration in amyotrophic lateral sclerosis (ALS), we generated longitudinal single-nucleus transcriptomes and chromatin accessibility profiles of spinal motor neurons together with spatial transcriptomics from the SOD1-G93A mouse model. Vulnerable alpha motor neurons showed thousands of molecular changes, marking a transition into a distinct cell state we named "disease-associated motor neurons" (DMs). We identified transcription factor networks that govern how healthy cells transition into DMs and those associated with motor neuron subtype-selective vulnerability. Upregulation of DM-associated transcription factors in human motor neurons induced key features of DMs, demonstrating an active regulatory component. Human ALS spinal cord single-nucleus RNA sequencing data demonstrated conservation of the DM signature in alpha motor neurons, and human orthologs of regions differentially accessible in SOD1-G93A mouse motor neurons were enriched for ALS genetic risk variants. Together, these findings establish a conserved, genetically linked motor neuron signature in ALS.