A Characterization of the Molecular Phenotype and Inflammatory Response of Schizophrenia Patient-derived Microglia-like Cells

Overview

Journal Brain Behav Immun

Publisher Elsevier

Specialties Allergy & Immunology
Neurology
Psychiatry

Date 2020 Aug 18

PMID 32798663

Citations 27

Authors

Paul R Ormel

Chotima Bottcher

Frederieke A J Gigase

Roy D Missall

Welmoed van Zuiden

M Camila Fernandez Zapata

Dilara Ilhan

Michelle de Goeij

Evan Udine

Iris E C Sommer

Josef Priller

Towfique Raj

Rene S Kahn

Elly M Hol

Lot D de Witte

Affiliations

Soon will be listed here.

Abstract

Different lines of evidence support a causal role for microglia in the pathogenesis of schizophrenia. However, how schizophrenia patient-derived microglia are affected at the phenotypic and functional level is still largely unknown. We used a recently described model to induce patient-derived microglia-like cells and used this to analyze changes in the molecular phenotype and function of myeloid cells in schizophrenia. We isolated monocytes from twenty recent-onset schizophrenia patients and twenty non-psychiatric controls. We cultured the cells towards an induced microglia-like phenotype (iMG), analyzed the phenotype of the cells by RNA sequencing and mass cytometry, and their response to LPS. Mass cytometry showed a high heterogeneity of iMG in cells derived from patients as well as controls. The prevalence of two iMG clusters was significantly higher in schizophrenia patients (adjusted p-value < 0.001). These subsets are characterized by expression of ApoE, Ccr2, CD18, CD44, and CD95, as well as IRF8, P2Y Cx3cr1 and HLA-DR. In addition, we found that patient-derived iMG show an enhanced response to LPS, with increased secretion of TNF-α. Further studies are needed to replicate these findings, to determine whether similar subclusters are present in schizophrenia patients in vivo, and to address how these subclusters are related to the increased response to LPS, as well as other microglial functions.

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