Vaccine Elicitation of HIV Broadly Neutralizing Antibodies from Engineered B Cells

Overview

Journal Nat Commun

Specialty Biology

Date 2020 Nov 18

PMID 33203876

Citations 42

Authors

Deli Huang

Jenny Tuyet Tran

Alex Olson

Thomas Vollbrecht

Mary Tenuta

Mariia V Guryleva

Roberta P Fuller

Torben Schiffner

Justin R Abadejos

Lauren Couvrette

Tanya R Blane

Karen Saye

Wenjuan Li

Elise Landais

Alicia Gonzalez-Martin

William Schief

Ben Murrell

Dennis R Burton

David Nemazee

James E Voss

Affiliations

Soon will be listed here.

Abstract

HIV broadly neutralizing antibodies (bnAbs) can suppress viremia and protect against HIV infection. However, their elicitation is made difficult by low frequencies of appropriate precursor B cell receptors and the complex maturation pathways required to generate bnAbs from these precursors. Antibody genes can be engineered into B cells for expression as both a functional antigen receptor on cell surfaces and as secreted antibody. Here, we show that HIV bnAb-engineered primary mouse B cells can be adoptively transferred and vaccinated in immunocompetent mice resulting in the expansion of durable bnAb memory and long-lived plasma cells. Somatic hypermutation after immunization indicates that engineered cells have the capacity to respond to an evolving pathogen. These results encourage further exploration of engineered B cell vaccines as a strategy for durable elicitation of HIV bnAbs to protect against infection and as a contributor to a functional HIV cure.

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