Repopulation of the brain with microglia-like cells following intraperitoneal bone marrow cell transfer in microglia-deficient mice

Germ-line deletion of a conserved enhancer (the Fms intrinsic regulatory element, FIRE) in the mouse Csf1r locus causes congenital absence of microglia. Homozygous FIRE deletion on a C57BL/6J background leads to perinatal lethality and hydrocephalus (HC) in surviving pups. We developed a congenic C57BL/6J line with defined regions of non-C57BL/6J genomic DNA, increased postnatal viability and reduced incidence of HC. Both perinatal lethality and HC were eliminated in F2 mice following outcross of the congenic line to CBA/J or BALBc/J backgrounds. To assess the impacts of microglial deficiency in postnatal neurodevelopment we analyzed deep total RNA-seq data from multiple brain regions of wild-type and Csf1rΔFIRE/ΔFIRE mice. Aside from the loss of microglial-specific transcripts, we found no significant alterations in relative abundance of any cell-type or region-specific transcriptomic signature. Transcripts associated with endosome/lysosome function, which are enriched in microglia, were not affected, suggesting compensatory expression by other cell types. On the C57BL/6J x CBA/J F2 background, congenital absence of microglia did not affect motor activity, behavior or myelination up to 7 months of age but was associated with astrocytosis and calcification in the thalamus. In the congenic C57BL/6J Csf1rΔFIRE/ΔFIRE mouse line, intraperitoneal transfer of wild-type bone marrow cells (BMT) at weaning led to complete repopulation of the brain with microglia-like cells without giving rise to monocytic intermediates. Our results suggest novel strategies for treatment of microglial deficiency.