Prenatal Immune Stress Blunts Microglia Reactivity, Impairing Neurocircuitry

Overview

Journal Nature

Specialty Science

Date 2022 Sep 28

PMID 36171283

Authors

Lindsay N Hayes

Kyongman An

Elisa Carloni

Fangze Li

Elizabeth Vincent

Chloe Trippaers

Manish Paranjpe

Gul Dolen

Loyal A Goff

Adriana Ramos

Shin-Ichi Kano

Akira Sawa

Affiliations

Soon will be listed here.

Abstract

Recent studies suggested that microglia, the primary brain immune cells, can affect circuit connectivity and neuronal function. Microglia infiltrate the neuroepithelium early in embryonic development and are maintained in the brain throughout adulthood. Several maternal environmental factors-such as an aberrant microbiome, immune activation and poor nutrition-can influence prenatal brain development. Nevertheless, it is unknown how changes in the prenatal environment instruct the developmental trajectory of infiltrating microglia, which in turn affect brain development and function. Here we show that, after maternal immune activation (MIA) in mice, microglia from the offspring have a long-lived decrease in immune reactivity (blunting) across the developmental trajectory. The blunted immune response was accompanied by changes in chromatin accessibility and reduced transcription factor occupancy of the open chromatin. Single-cell RNA-sequencing analysis revealed that MIA does not induce a distinct subpopulation but, rather, decreases the contribution to inflammatory microglia states. Prenatal replacement of microglia from MIA offspring with physiological infiltration of naive microglia ameliorated the immune blunting and restored a decrease in presynaptic vesicle release probability onto dopamine receptor type-two medium spiny neurons, indicating that aberrantly formed microglia due to an adverse prenatal environment affect the long-term microglia reactivity and proper striatal circuit development.

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