Organization of the Autoantibody Repertoire in Healthy Newborns and Adults Revealed by System Level Informatics of Antigen Microarray Data

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2009 Aug 12

PMID 19667184

Citations 35

Authors

Asaf Madi

Inbal Hecht

Sharron Bransburg-Zabary

Yifat Merbl

Adi Pick

Merav Zucker-Toledano

Francisco J Quintana

Alfred I Tauber

Irun R Cohen

Eshel Ben-Jacob

Affiliations

Soon will be listed here.

Abstract

The immune system is essential to body defense and maintenance. Specific antibodies to foreign invaders function in body defense, and it has been suggested that autoantibodies binding to self molecules are important in body maintenance. Recently, the autoantibody repertoires in the bloods of healthy mothers and their newborns were studied using an antigen microarray containing hundreds of self molecules. It was found that the mothers expressed diverse repertoires for both IgG and IgM autoantibodies. Each newborn shares with its mother a similar repertoire of IgG antibodies, which cross the placental but its IgM repertoire is more similar to those of other newborns. Here, we took a system-level approach and analyzed the correlations between autoantibody reactivities of the previous data and extended the study to new data from newborns at birth and a week later, and from healthy young women. For the young women, we found modular organization of both IgG and IgM isotypes into antigen cliques-subgroups of highly correlated antigen reactivities. In contrast, the newborns were found to share a universal congenital IgM profile with no modular organization. Moreover, the IgG autoantibodies of the newborns manifested buds of the mothers' antigen cliques, but they were noticeably less structured. These findings suggest that the natural autoantibody repertoire of humans shows relatively little organization at birth, but, by young adulthood, it becomes sorted out into a modular organization of subgroups (cliques) of correlated antigens. These features revealed by antigen microarrays can be used to define personal states of autoantibody organizational motifs.

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