Optimisation of Memory B Cell Expansion/differentiation for Interrogation of Rare Peripheral Memory B Cell Subset Responses

Overview

Journal Wellcome Open Res

Specialty Biomedical Engineering

Date 2018 Mar 29

PMID 29588920

Citations 6

Authors

Luke Muir

Paul F McKay

Velislava N Petrova

Oleksiy V Klymenko

Sven Kratochvil

Christopher L Pinder

Paul Kellam

Robin J Shattock

Affiliations

Soon will be listed here.

Abstract

Human memory B cells play a vital role in the long-term protection of the host from pathogenic re-challenge. In recent years the importance of a number of different memory B cell subsets that can be formed in response to vaccination or infection has started to become clear. To study memory B cell responses, cells can be cultured allowing for an increase in cell number and activation of these quiescent cells, providing sufficient quantities of each memory subset to enable full investigation of functionality. However, despite numerous papers being published demonstrating bulk memory B cell culture, we could find no literature on optimised conditions for the study of memory B cell subsets, such as IgM memory B cells. Following a literature review, we carried out a large screen of memory B cell expansion conditions to identify the combination that induced the highest levels of memory B cell expansion. We subsequently used a novel Design of Experiments approach to finely tune the optimal memory B cell expansion and differentiation conditions for human memory B cell subsets. Finally, we characterised the resultant memory B cell subpopulations by IgH sequencing and flow cytometry. The application of specific optimised conditions induce multiple rounds of memory B cell proliferation equally across Ig isotypes, differentiation of memory B cells to antibody secreting cells, and importantly do not alter the Ig genotype of the stimulated cells. Overall, our data identify a memory B cell culture system that offers a robust platform for investigating the functionality of rare memory B cell subsets to infection and/or vaccination.

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