Antibody-independent Protection Against Heterologous SARS-CoV-2 Challenge Conferred by Prior Infection or Vaccination

Overview

Journal Nat Immunol

Date 2024 Mar 15

PMID 38486021

Authors

Valeria Fumagalli

Micol Rava

Davide Marotta

Pietro Di Lucia

Elisa B Bono

Leonardo Giustini

Federica De Leo

Maura Casalgrandi

Emanuele Monteleone

Violette Mouro

Chiara Malpighi

Chiara Perucchini

Marta Grillo

Sara De Palma

Lorena Donnici

Silvia Marchese

Matteo Conti

Hiromi Muramatsu

Stanley Perlman

Norbert Pardi

Mirela Kuka

Raffaele De Francesco

Marco E Bianchi

Luca G Guidotti

Matteo Iannacone

Affiliations

Soon will be listed here.

Abstract

Vaccines have reduced severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) morbidity and mortality, yet emerging variants challenge their effectiveness. The prevailing approach to updating vaccines targets the antibody response, operating under the presumption that it is the primary defense mechanism following vaccination or infection. This perspective, however, can overlook the role of T cells, particularly when antibody levels are low or absent. Here we show, through studies in mouse models lacking antibodies but maintaining functional B cells and lymphoid organs, that immunity conferred by prior infection or mRNA vaccination can protect against SARS-CoV-2 challenge independently of antibodies. Our findings, using three distinct models inclusive of a novel human/mouse ACE2 hybrid, highlight that CD8 T cells are essential for combating severe infections, whereas CD4 T cells contribute to managing milder cases, with interferon-γ having an important function in this antibody-independent defense. These findings highlight the importance of T cell responses in vaccine development, urging a broader perspective on protective immunity beyond just antibodies.

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