A Repertoire of 124 Potential Autoantigens for Autoimmune Kidney Diseases Identified by Dermatan Sulfate Affinity Enrichment of Kidney Tissue Proteins

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2019 Jun 26

PMID 31237920

Citations 13

Authors

Wei Zhang

Jung-hyun Rho

Michael W Roehrl

Michael H Roehrl

Julia Y Wang

Affiliations

Soon will be listed here.

Abstract

Autoantigens are the molecular targets in autoimmune diseases. They are a cohort of seemingly unrelated self-molecules present in different parts of the body, yet they can trigger a similar chain of autoimmune responses such as autoantibody production. We previously reported that dermatan sulfate (DS) can bind self-molecules of dying cells to stimulate autoreactive CD5+ B cells to produce autoantibodies. The formation of autoantigen-DS complexes converts the normally non-antigenic self-molecules to none-self antigens, and thus DS-affinity represents a common underlying biochemical property for autoantigens. This study sought to apply this property to identify potential autoantigens in the kidney. Total proteins were extracted from mouse kidney tissues and loaded onto DS-Sepharose resins. Proteins without affinity were washed off the resins, whereas those with increasing DS-affinity were eluted with step gradients of increasing salt strength. Fractions with strong and moderate DS-affinity were sequenced by mass spectrometry and yielded 25 and 99 proteins, respectively. An extensive literature search was conducted to validate whether these had been previously reported as autoantigens. Of the 124 proteins, 79 were reported autoantigens, and 19 out of 25 of the strong-DS-binding ones were well-known autoantigens. Moreover, these proteins largely fell into the two most common autoantibody categories in autoimmune kidney diseases, including 40 ANA (anti-nuclear autoantibodies) and 25 GBM (glomerular basement membrane) autoantigens. In summary, this study compiles a large repertoire of potential autoantigens for autoimmune kidney diseases. This autoantigen-ome sheds light on the molecular etiology of autoimmunity and further supports our hypothesis DS-autoantigen complexes as a unifying principle of autoantigenicity.

Citing Articles

An Autoantigen Atlas From Human Lung HFL1 Cells Offers Clues to Neurological and Diverse Autoimmune Manifestations of COVID-19.

Wang J, Zhang W, Roehrl V, Roehrl M, Roehrl M Front Immunol. 2022; 13:831849.

PMID: 35401574 PMC: 8987778. DOI: 10.3389/fimmu.2022.831849.

A master autoantigen-ome links alternative splicing, female predilection, and COVID-19 to autoimmune diseases.

Wang J, Roehrl M, Roehrl V, Roehrl M J Transl Autoimmun. 2022; 5:100147.

PMID: 35237749 PMC: 8872718. DOI: 10.1016/j.jtauto.2022.100147.

An Autoantigen Profile from Jurkat T-Lymphoblasts Provides a Molecular Guide for Investigating Autoimmune Sequelae of COVID-19.

Wang J, Zhang W, Roehrl M, Roehrl V, Roehrl M bioRxiv. 2021; .

PMID: 34729561 PMC: 8562547. DOI: 10.1101/2021.07.05.451199.

A Master Autoantigen-ome Links Alternative Splicing, Female Predilection, and COVID-19 to Autoimmune Diseases.

Wang J, Roehrl M, Roehrl V, Roehrl M bioRxiv. 2021; .

PMID: 34373855 PMC: 8351778. DOI: 10.1101/2021.07.30.454526.

Dermatan Sulfate Is a Potential Regulator of IgH Interactions With Pre-BCR, GTF2I, and BiP ER Complex in Pre-B Lymphoblasts.

Lee J, Rho J, Roehrl M, Wang J Front Immunol. 2021; 12:680212.

PMID: 34113352 PMC: 8185350. DOI: 10.3389/fimmu.2021.680212.

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