IgH isotype-specific B cell receptor dosage regulates B cell fate

Abstract

Abstract Immunoglobulin heavy chain (IgH) isotypes (e.g. IgM, IgG and IgE) are generated as secreted/soluble antibodies (sIg) or as membrane-bound (mIg) B cell receptors (BCR) through alternative RNA splicing. IgH isotype dictates soluble antibody function, but how mIg isotype influences B cell behavior is unclear. We examined IgH isotype-specific BCR function by engineering polyclonal Ighγ1/γ1 and Ighɛ/ɛ mice, which initially produce IgG1 or IgE from their respective native genomic configurations. Transcripts producing IgM, IgG1, and IgE are produced in an alternative splice form bias hierarchy, where mIgμ>mIgγ1>mIgɛ—influencing respective BCR densities and fitness for populating the periphery—a pattern replicated in activated and memory B cells from wild-type mice. Restrained B cell development from Ighγ1/γ1 and Ighɛ/ɛ mice was proportional to sIg/mIg ratios, and was rescued by enforced expression of the respective mIgs. In addition, enhanced BCR signaling by way of PTEN deletion in IgE B cells generated functional IgE memory responses from IgE memory B cells themselves, which are normally absent under normal conditions, indicating that weak signal strength normally restrains IgE responses. Thus, IgH isotype-specific mIg dosage regulates B cell fate by influencing quantitative baseline BCR signal strength.