Peripheral NOD-like Receptor Deficient Inflammatory Macrophages Trigger Neutrophil Infiltration into the Brain Disrupting Daytime Locomotion

Overview

Journal Commun Biol

Specialty Biology

Date 2022 May 16

PMID 35577844

Authors

Victoria Kwon

Peiwen Cai

Cameron T Dixon

Victoria Hamlin

Caroline G Spencer

Alison M Rojas

Matthew Hamilton

Celia E Shiau

Affiliations

Soon will be listed here.

Abstract

Inflammation is known to disrupt normal behavior, yet the underlying neuroimmune interactions remain elusive. Here, we investigated whether inappropriate macrophage-evoked inflammation alters CNS control of daily-life animal locomotion using a set of zebrafish mutants selected for specific macrophage dysfunction and microglia deficiency. Large-scale genetic and computational analyses revealed that NOD-like receptor nlrc3l mutants are capable of normal motility and visuomotor response, but preferentially swim less in the daytime, suggesting possible low motivation rather than physical impairment. Examining their brain activities and structures implicates impaired dopaminergic descending circuits, where neutrophils abnormally infiltrate. Furthermore, neutrophil depletion recovered daytime locomotion. Restoring wild-type macrophages reversed behavioral and neutrophil aberrations, while three other microglia-lacking mutants failed to phenocopy nlrc3l mutants. Overall, we reveal how peripheral inflammatory macrophages with elevated pro-inflammatory cues (including il1β, tnfα, cxcl8a) in the absence of microglia co-opt neutrophils to infiltrate the brain, thereby potentially enabling local circuitry modulation affecting daytime locomotion.

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