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Repopulated spinal cord microglia exhibit a unique transcriptome and contribute to pain resolution

Lauren J. Donovan, Caldwell M. Bridges, Amy R. Nippert, Meng Wang, Shaogen Wu, Thomas E. Forman, Elena S. Haight, Nolan A. Huck, Sabrina F. Bond, Claire E. Jordan, Aysha M. Gardner, Ramesh V. Nair, Vivianne L. Tawfik

2024Cell Reports19 citationsDOIOpen Access PDF

Abstract

Microglia are implicated as primarily detrimental in pain models; however, they exist across a continuum of states that contribute to homeostasis or pathology depending on timing and context. To clarify the specific contribution of microglia to pain progression, we take advantage of a temporally controlled transgenic approach to transiently deplete microglia. Unexpectedly, we observe complete resolution of pain coinciding with microglial repopulation rather than depletion. We find that repopulated mouse spinal cord microglia are morphologically distinct from control microglia and exhibit a unique transcriptome. Repopulated microglia from males and females express overlapping networks of genes related to phagocytosis and response to stress. We intersect the identified mouse genes with a single-nuclei microglial dataset from human spinal cord to identify human-relevant genes that may ultimately promote pain resolution after injury. This work presents a comprehensive approach to gene discovery in pain and provides datasets for the development of future microglial-targeted therapeutics.

Topics & Concepts

MicrogliaTranscriptomeSpinal cordNeuroscienceComputational biologyMedicineBiologyBioinformaticsInflammationImmunologyGeneticsGene expressionGeneNeuroinflammation and Neurodegeneration MechanismsPain Mechanisms and TreatmentsNeuropeptides and Animal Physiology