Tissue Proteomic Analysis Identifies Mechanisms and Stages of Immunopathology in Fatal COVID-19.

Clark D Russell,Stuart D Armstrong,J Kenneth Baillie,David J Harrison,Ahsan R Akram,Rebekah Penrice-Randal,Naomi N Gachanja,David A Dorward,Asta Valanciute,Julian A Hiscox,Sara Clohisey,Wael Al Qsous,Jillian Stephen,Jo Stevens,William A Wallace,Christopher D Lucas,Gabriel C Oniscu,Bo Wang,Kevin Dhaliwal

doi:10.1165/rcmb.2021-0358oc

Abstract

Immunopathology occurs in the lung and spleen in fatal coronavirus disease (COVID-19), involving monocytes/macrophages and plasma cells. Antiinflammatory therapy reduces mortality, but additional therapeutic targets are required. We aimed to gain mechanistic insight into COVID-19 immunopathology by targeted proteomic analysis of pulmonary and splenic tissues. Lung parenchymal and splenic tissue was obtained from 13 postmortem examinations of patients with fatal COVID-19. Control tissue was obtained from cancer resection samples (lung) and deceased organ donors (spleen). Protein was extracted from tissue by phenol extraction. Olink multiplex immunoassay panels were used for protein detection and quantification. Proteins with increased abundance in the lung included MCP-3, antiviral TRIM21, and prothrombotic TYMP. OSM and EN-RAGE/S100A12 abundance was correlated and associated with inflammation severity. Unsupervised clustering identified “early viral” and “late inflammatory” clusters with distinct protein abundance profiles, and differences in illness duration before death and presence of viral RNA. In the spleen, lymphocyte chemotactic factors and CD8A were decreased in abundance, and proapoptotic factors were increased. B-cell receptor signaling pathway components and macrophage colony stimulating factor (CSF-1) were also increased. Additional evidence for a subset of host factors (including DDX58, OSM, TYMP, IL-18, MCP-3, and CSF-1) was provided by overlap between 1) differential abundance in spleen and lung tissue; 2) meta-analysis of existing datasets; and 3) plasma proteomic data. This proteomic analysis of lung parenchymal and splenic tissue from fatal COVID-19 provides mechanistic insight into tissue antiviral responses, inflammation and disease stages, macrophage involvement, pulmonary thrombosis, splenic B-cell activation, and lymphocyte depletion.

Highlights

Fatal coronavirus disease 2019 (COVID-19) is associated with pronounced inflammatory changes in the lung and reticuloendothelial system[1]
All patients had histologic evidence of pulmonary inflammation in the same lung lobe used for proteomic analysis, with diffuse alveolar damage in 9/13
In fatal COVID-19 there is histologic evidence of substantial monocyte/macrophage expansion within the lung parenchyma and frequent occurrence of a monocyte/myeloid cell vasculitis [1, 6], suggesting that these cells are direct contributors to the immunopathology seen in severe disease

Summary

Introduction

Fatal coronavirus disease 2019 (COVID-19) is associated with pronounced inflammatory changes in the lung and reticuloendothelial system[1]. The presence of virus is not consistently associated with the occurrence or nature of the inflammatory response. This disconnect between the presence of virus and inflammation identifies virus-independent immunopathology as a pathophysiologic feature of severe COVID-19. Pulmonary inflammation is characterised by an expansion of macrophages/monocytes in the lung parenchyma, a mononuclear cell pulmonary artery vasculitis, micro-thrombosis and increased numbers of megakaryocytes[1, 5, 6]. The biological mechanisms leading to and from these immunopathogenic changes are unknown

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