Single-nucleus multiomic atlas of ALS primary motor cortex nominates neuroprotective WDR49-expressing astrocytes
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Amyotrophic lateral sclerosis (ALS) causes selective neurodegeneration in primary motor cortex, yet cell-type-specific molecular changes driving this vulnerability remain poorly understood. We present an integrated single-nucleus RNA- and ATAC-sequencing atlas of 778,330 nuclei from the primary motor cortex of 140 genetically characterised donors. ALS is associated with widespread transcriptional reprogramming driven by a common set of transcription factors (TFs) across multiple cell-types. Astrocytes harbour the most differentially expressed genes. Within astrocytes, a WDR49-expressing subpopulation is spatially associated with TDP-43 pathology, and genetic variants within WDR49 confer risk for both sporadic and monogenic autosomal dominant ALS. In patient-derived induced astrocytes, WDR49 protein abundance predicts the survival of co-cultured neurons. WDR49 localises to PML nuclear bodies, where it regulates astrocyte reactivity and secretion of EVs containing protein chaperones. Together, these in vivo and in vitro findings suggest that WDR49+ astrocytes mount a compensatory secretory response to extracellular protein aggregates, and that loss of this capacity lowers the threshold for ALS pathogenesis.