Lysosomes cell autonomously regulate myeloid cell states and immune responses

Myeloid cells maintain tissue homeostasis via the recognition, engulfment, and lysosomal clearance of dying cells and cellular debris, which is often accompanied by changes from homeostatic to reactive states. While a role for phagocytic receptors in gating these transitions has been described, less is known about if and how lysosomes can contribute to transcriptional and functional plasticity. To determine how lysosomal health impacts myeloid cell states, we evaluated microglia and macrophages deficient for progranulin (encoded by Grn), a lysosomal protein with pleiotropic functions whose loss is associated with several neurodegenerative diseases. Single-cell RNA-sequencing of the aged mouse brain identified a Grn knockout (KO)-specific microglial subpopulation marked by high GPNMB expression that displays hallmarks of lysosomal dysfunction, including lipofuscin accumulation. Epigenetic analysis of aged microglia revealed MITF/TFE transcription factors as key mediators of the transcriptional states associated with Grn deficiency. In addition to identifying a core myeloid cell transcriptional response to diverse lysosomal stressors, targeted perturbations of various lysosomal properties in vitro uncovered a cell autonomous, TREM2-independent, response to lysosomal deacidification (via v-ATPase or VPS34 loss of function) that overlaps with Grn KO microglia phenotypes, including the induction of a lysosomal gene program, increased proliferation, and secretion of pro-inflammatory cytokines. Compound loss-of-function approaches established GPNMB upregulation upon lysosomal stress is required for the compensatory response to enhance lysosomal function via promoting acidification. Finally, pharmacological endolysosomal reacidification through sodium/proton exchanger inhibition partially rescued Grn KO microglia phenotypes. Overall, these data establish a fundamental link between lysosomal health and myeloid cell epigenetic, transcriptional, and functional states observed in neurodegeneration models. Two year old mice were anesthetized, transcardially perfused with PBS, and brains were removed for scRNA-seq or microglial H3K27ac analyses (see below). Hemibrains were separated and one half was frozen for nuclei isolation for H3K27ac ChIP-seq. Microglial nuclei sorted from two mice were pooled for each individual replicate, and analyses were performed with duplicates for each genotype.