Longitudinal single-cell analysis of SARS-CoV-2–reactive B cells uncovers persistence of early-formed, antigen-specific clones
Lydia Scharf, Hannes Axelsson, Aikaterini Emmanouilidi, Nimitha R. Mathew, Daniel J. Sheward, Susannah Leach, Pauline Isakson, Ilya V. Smirnov, Emelie Marklund, Nicolae Miron, Lars-Magnus Andersson, Magnus Gisslén, Ben Murrell, Anna Lundgren, Mats Bemark, Davide Angeletti
Lydia Scharf, Hannes Axelsson, Aikaterini Emmanouilidi, Nimitha R. Mathew, Daniel J. Sheward, Susannah Leach, Pauline Isakson, Ilya V. Smirnov, Emelie Marklund, Nicolae Miron, Lars-Magnus Andersson, Magnus Gisslén, Ben Murrell, Anna Lundgren, Mats Bemark, Davide Angeletti
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Research Article COVID-19 Immunology

Longitudinal single-cell analysis of SARS-CoV-2–reactive B cells uncovers persistence of early-formed, antigen-specific clones

Abstract

Understanding persistence and evolution of B cell clones after COVID-19 infection and vaccination is crucial for predicting responses against emerging viral variants and optimizing vaccines. Here, we collected longitudinal samples from patients with severe COVID-19 every third to seventh day during hospitalization and every third month after recovery. We profiled their antigen-specific immune cell dynamics by combining single-cell RNA-Seq, Cellular Indexing of Transcriptomes and Epitopes by Sequencing (CITE-Seq), and B cell receptor–Seq (BCR-Seq) with oligo-tagged antigen baits. While the proportion of Spike receptor binding domain–specific memory B cells (MBC) increased from 3 months after infection, the other Spike- and Nucleocapsid-specific B cells remained constant. All patients showed ongoing class switching and sustained affinity maturation of antigen-specific cells, and affinity maturation was not significantly increased early after vaccine. B cell analysis revealed a polyclonal response with limited clonal expansion; nevertheless, some clones detected during hospitalization, as plasmablasts, persisted for up to 1 year, as MBC. Monoclonal antibodies derived from persistent B cell families increased their binding and neutralization breadth and started recognizing viral variants by 3 months after infection. Overall, our findings provide important insights into the clonal evolution and dynamics of antigen-specific B cell responses in longitudinally sampled patients infected with COVID-19.

Authors

Lydia Scharf, Hannes Axelsson, Aikaterini Emmanouilidi, Nimitha R. Mathew, Daniel J. Sheward, Susannah Leach, Pauline Isakson, Ilya V. Smirnov, Emelie Marklund, Nicolae Miron, Lars-Magnus Andersson, Magnus Gisslén, Ben Murrell, Anna Lundgren, Mats Bemark, Davide Angeletti

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Figure 2

Longitudinal characterization of T cells in patients with COVID-19.

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Longitudinal characterization of T cells in patients with COVID-19. (A) ...
(A) UMAP plot, based on both RNA and surface protein expression, of T cells. Cluster names are based on Figure 1. Each dot indicates an individual cell. (B) UMAP plot showing average expression of selected genes (rna), proteins (ADT), or combined gene signatures, according to ref. 30. “ADT” indicates surface protein expression, while “rna” shows transcript expression. “CMrest” score is genes associated with resting central memory; “Treg” score represents genes associated with Tregs; “IFN” score is genes associated with IFN response; and “CTL” score represents genes associated with cytotoxic T cell responses. Each dot is a cell and color intensity represent expression. (C) UMAP plot of T cells as in A, but grouping is based on gene signature expression as in B. (D) UMAP plot as in C but split based on hospitalization status. (E) Quantification of the proportion of cells for each T cell cluster at each sampling time. All patients were included. (F) Frequency for each of the identified clusters, indicated for each patient and time of sampling. Multiple comparisons were performed using 1-way ANOVA, with Tukey’s multiple-comparison test. *P < 0.05; **P < 0.01.