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Preservation of naive-phenotype CD4+ T cells after vaccination contributes to durable immunity
Yi-Gen Pan, Laurent Bartolo, Ruozhang Xu, Bijal V. Patel, Veronika I. Zarnitsyna, Laura F. Su
Yi-Gen Pan, Laurent Bartolo, Ruozhang Xu, Bijal V. Patel, Veronika I. Zarnitsyna, Laura F. Su
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Research Article Immunology Vaccines

Preservation of naive-phenotype CD4+ T cells after vaccination contributes to durable immunity

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Abstract

Memory T cells are conventionally associated with durable recall responses. In our longitudinal analyses of CD4+ T cell responses to the yellow fever virus (YFV) vaccine by peptide-MHC tetramers, we unexpectedly found CD45RO–CCR7+ virus-specific CD4+ T cells that expanded shortly after vaccination and persisted months to years after immunization. Further phenotypic analyses revealed the presence of stem cell–like memory T cells within this subset. In addition, after vaccination T cells lacking known memory markers and functionally resembling genuine naive T cells were identified, referred to herein as marker-negative T (TMN) cells. Single-cell TCR sequencing detected expanded clonotypes within the TMN subset and identified TMN TCRs shared with memory and effector T cells. Longitudinal tracking of YFV-specific responses over subsequent years revealed superior stability of TMN cells, which correlated with the longevity of the overall tetramer+ population. These findings uncover additional complexity within the post-immune T cell compartment and implicate TMN cells in durable immune responses.

Authors

Yi-Gen Pan, Laurent Bartolo, Ruozhang Xu, Bijal V. Patel, Veronika I. Zarnitsyna, Laura F. Su

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Figure 6

TMN cells are stable and associated with durable T cell memory.

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TMN cells are stable and associated with durable T cell memory.
(A) Repr...
(A) Representative plots show YFV-specific CD4+ T cells over the indicated time points from HD2. (B) Each tet+ population of a given specificity was subdivided according to phenotypes. The change over time for each phenotypic subset was quantified by the estimated slope using a mixed effects exponential decay model (n = 19 tetramer+ populations from 5 donors). (C) A mixed effects exponential decay model fitted to the dynamics of YFV-specific CD4+ T cells after a single YFV vaccination (n = 8 populations, combined from donors 4 and 5). The estimated decay (blue line) was used for calculating the t1/2. (D) Ranking of tet+ populations by the averaged frequency of TMN cells within each population across all time points. (E) Plot summarizes the estimated slopes of individual tet+ populations, divided into top and bottom halves by TMN frequency in D. (F) The correlation between slopes characterizing the change over time for the overall tetramer+ populations and their corresponding averaged TMN frequencies. (G) Pie charts show the distribution of memory subsets. Populations were divided into top and bottom groups by the first measured TMN frequency obtained within 1–2 years after YFV vaccination. (H) Phenotypic diversity of each tet+ population was quantified using Shannon diversity index, categorized into top or bottom groups based on TMN frequency as in G. Each symbol represents 1 tetramer+ population. Experiments were repeated an average of 2.3 times. Data are represented as mean ± SEM. (B) RM 1-way ANOVA was performed and corrected with Tukey’s multiple comparisons test. (E and H) Welch’s t test was performed. (F) Spearman’s correlation was performed. *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001.

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