Neutrophil-microglia interaction drives motor dysfunction in a neuromyelitis optica model induced by subarachnoid AQP4-IgG
Fangfang Qi, Vanda A. Lennon, Shunyi Zhao, Yong Guo, Husheng Ding, Caiyun Liu, Whitney M. Bartley, Tingjun Chen, Claudia F. Lucchinetti, Long-Jun Wu
Fangfang Qi, Vanda A. Lennon, Shunyi Zhao, Yong Guo, Husheng Ding, Caiyun Liu, Whitney M. Bartley, Tingjun Chen, Claudia F. Lucchinetti, Long-Jun Wu
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Research Article Autoimmunity Neuroscience

Neutrophil-microglia interaction drives motor dysfunction in a neuromyelitis optica model induced by subarachnoid AQP4-IgG

Abstract

Neutrophils and neutrophil extracellular traps (NETs) contribute to early neuromyelitis optica (NMO) histopathology initiated by IgG targeting astrocytic aquaporin-4 (AQP4) water channels. Yet, the mechanisms underlying neutrophil recruitment and their pathogenic roles in disease progression remain unclear. To investigate molecular-cellular events preceding classical complement cascade activation in a mouse NMO model, we continuously infused, via spinal subarachnoid route, a non-complement-activating mouse monoclonal AQP4-IgG. Parenchymal infiltration of netting neutrophils containing C5a ensued with microglial activation and motor impairment but no blood-brain barrier leakage. Motor impairment and neuronal dysfunction both reversed when AQP4-IgG infusion stopped. Two-photon microscopy and electron microscopy–based reconstructions revealed physical interaction of infiltrating neutrophils with microglia. Ablation of either peripheral neutrophils or microglia attenuated the motor deficit, highlighting their synergistic pathogenic roles. Of note, mice lacking complement receptor C5aR1 exhibited reduction in neutrophil infiltration, microglial lysosomal activation, neuronal lipid droplet burden, and motor impairment. Pharmacological inhibition of C5aR1 recapitulated this protection. Immunohistochemical analysis of an NMO patient’s spinal cord revealed disease-associated microglia surrounding motor neurons in nondestructive lesions. Our study identifies neutrophil-derived C5a signaling through microglial C5aR1 as a key early driver of reversible motor neuron dysfunction in the precytolytic phase of NMO.

Authors

Fangfang Qi, Vanda A. Lennon, Shunyi Zhao, Yong Guo, Husheng Ding, Caiyun Liu, Whitney M. Bartley, Tingjun Chen, Claudia F. Lucchinetti, Long-Jun Wu

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Figure 2

Neutrophil-microglial contacts in lumbar parenchyma, AQP4-IgG infusion day 3.

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Neutrophil-microglial contacts in lumbar parenchyma, AQP4-IgG infusion d...
(A) Confocal image identifies putatively interacting microglia (Cx3cr1GFP+, green) and neutrophil (Ly6G+, red) adjacent to a neuronal soma (NeuN+, blue); subsequent images are Imaris 3D rendering. (B) Cord region of interest containing contacting neutrophil-microglia; laser-branded frame by 2-photon imaging; magnified. (C) Serial block-face scanning electron microscopy (SBF-SEM) shows ultrastructurally the same neutrophil, microglia, and 2 neurons boxed in A. Yellow arrows (magnified, C1) indicate contacting microglial-neutrophil somata edges (green and red lines in C2). (D) 3D serial reconstruction of contacting microglial-neutrophil somata in C (Supplemental Video 1, Z-stack). (E) Representative confocal image (left, 2,048 × 2,048 pixel; ×63 objective lens) and 3D rendering image (right) show microglial process and soma interacting with Ly6G+ neutrophils in lumbar parenchyma of AQP4-IgG recipient (Supplemental Video 2, Imaris). (F) Representative 3D rendering image shows netting (MPO+) neutrophil interacting with microglial processes in lumbar parenchyma of AQP4-IgG-recipient. High power shows microglial process-neutrophil soma physical interaction (Supplemental Video 3, Imaris). Multilobed nucleus, DAPI+ (blue). IBA1, ionized calcium-binding adapter molecule 1. (GI) Serial histopathologic sections of NMO patient’s early spinal cord lesion. (G) White matter parenchyma shows intact myelin (Luxol fast blue) with infiltrating neutrophils and eosinophils close to a penetrating vessel. Neutrophil infiltration area, right upper inset; 2 infiltrated neutrophils in right lower inset have multilobed nuclei (arrow). (H) AQP4 immunoreactivity is reduced in this region; the adjacent area (right inset) retained AQP4. (I) CD68 (KiM1p) immunostain identifies macrophages/microglia in this non-demyelinated lesion. (J) Neutrophils among P2Y12+ microglia; magnification (inset box right) shows 3 neutrophils (segmented nuclei, hematoxylin-stained) abutting microglial processes. Arrows indicate neutrophils contacting microglia.