Lymphocyte subset analyses in healthy adults vaccinated with yellow fever 17DD virus

Santos, Ana Paula dos; Bertho, Álvaro Luiz; Dias, Daniela Capuzzo; Santos, Jaciara Ramos; Marcovistz, Rugimar

doi:10.1590/s0074-02762005000300021

Cited by 28 publications

(16 citation statements)

References 25 publications

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“…ϩ -, and CD8 ϩ -based antiviral immune response (6,9,10,12,16,(30)(31)(32)(33)(34). Although some of these studies used either peptide pools or tetramer-based approaches to address the response to a limited number of viral epitopes (6,9,33), or calculated the percentage of different immune cellular compartments that represented clones induced by vaccination with YFV (reviewed in reference 16), the clonal breadth and complexity of the response to a viral infection has been beyond the reach of available methods.…”

Section: Discussionmentioning

confidence: 99%

“…Although helper T cells are clearly required for the production of YFV-specific Abs (including nAbs), different studies have reported variable levels of induction of CD4 ϩ T cells upon vaccination with YFV (30,31). Some analyses have revealed that cytokineproducing YFV-specific CD4 ϩ T cells can be detected as early as day 2 postvaccination and that they return to baseline by day 28, suggesting that the kinetics of CD4 ϩ T cells precede those of CD8 ϩ T cells (12,32).…”

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confidence: 99%

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Dynamics of the Cytotoxic T Cell Response to a Model of Acute Viral Infection

DeWitt

Emerson

Lindau

et al. 2015

J Virol

146

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A detailed characterization of the dynamics and breadth of the immune response to an acute viral infection, as well as the determinants of recruitment to immunological memory, can greatly contribute to our basic understanding of the mechanics of the human immune system and can ultimately guide the design of effective vaccines. In addition to neutralizing antibodies, T cells have been shown to be critical for the effective resolution of acute viral infections. We report the first in-depth analysis of the dynamics of the CD8 ؉ T cell repertoire at the level of individual T cell clonal lineages upon vaccination of human volunteers with a single dose of YF-17D. This live attenuated yellow fever virus vaccine yields sterile, long-term immunity and has been previously used as a model to understand the immune response to a controlled acute viral infection. We identified and enumerated unique CD8؉ T cell clones specifically induced by this vaccine through a combined experimental and statistical approach that included high-throughput sequencing of the CDR3 variable region of the T cell receptor ␤-chain and an algorithm that detected significantly expanded T cell clones. This allowed us to establish that (i) on average, ϳ2,000 CD8 ؉ T cell clones were induced by YF-17D, (ii) 5 to 6% of the responding clones were recruited to long-term memory 3 months postvaccination, (iii) the most highly expanded effector clones were preferentially recruited to the memory compartment, and (iv) a fraction of the YF-17D-induced clones could be identified from peripheral blood lymphocytes solely by measuring clonal expansion. IMPORTANCEThe exhaustive investigation of pathogen-induced effector T cells is essential to accurately quantify the dynamics of the human immune response. The yellow fever vaccine (YFV) has been broadly used as a model to understand how a controlled, self-resolving acute viral infection induces an effective and long-term protective immune response. Here, we extend this previous work by reporting the identity of activated effector T cell clones that expand in response to the YFV 2 weeks postvaccination (as defined by their unique T cell receptor gene sequence) and by tracking clones that enter the memory compartment 3 months postvaccination. This is the first study to use high-throughput sequencing of immune cells to characterize the breadth of the antiviral effector cell response and to determine the contribution of unique virus-induced clones to the long-lived memory T cell repertoire. Thus, this study establishes a benchmark against which future vaccines can be compared to predict their efficacy. D uring the acute response to a viral infection, viral antigen (Ag)-specific effector CD8ϩ T cell clones (also known as cytotoxic T lymphocytes, or CTLs) become activated and expand as they recognize and eliminate infected host cells (1, 2). The Ag specificity of a T cell clone is determined by the T cell receptor (TCR), which is encoded by random, RAG-mediated V(D)J recombination. Thus, each T cell clone may be iden...

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Dynamics of the Cytotoxic T Cell Response to a Model of Acute Viral Infection

DeWitt

Emerson

Lindau

et al. 2015

J Virol

146

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“…Studies have suggested that the ability of YF-17D to infect dendritic cells and activate multiple Toll-like receptors may be essential for generating this potent immune response (8,(12)(13)(14). The YF-17D vaccine provides a model to study the immune response to vaccination in human populations, including both cellular and humoral responses, and to dissect the mechanisms of effective vaccine responses (10,(15)(16)(17)(18). Defining vaccine efficacy in African populations is of paramount importance, as these populations are targeted by most of the currently tested vaccines for HIV, tuberculosis, malaria, and dengue virus (DENV) (19).…”

Section: Introductionmentioning

confidence: 99%

Immune activation alters cellular and humoral responses to yellow fever 17D vaccine

Muyanja¹,

Ssemaganda²,

Ngauv³

et al. 2014

J. Clin. Invest.

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Background. Defining the parameters that modulate vaccine responses in African populations will be imperative to design effective vaccines for protection against HIV, malaria, tuberculosis, and dengue virus infections. This study aimed to evaluate the contribution of the patient-specific immune microenvironment to the response to the licensed yellow fever vaccine 17D (YF-17D) in an African cohort. Conclusion.Together, these results demonstrate that an activated immune microenvironment prior to vaccination impedes efficacy of the YF-17D vaccine in an African cohort and suggest that vaccine regimens may need to be boosted in African populations to achieve efficient immunity.Trial registration. Registration is not required for observational studies.

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“…Therefore, the YFV 17D vaccine is an excellent and important model for studying human antiviral immunity. Multiple studies have investigated the attributes and dynamics of CD4 ϩ and CD8 ϩ T cell responses following YF vaccination (8)(9)(10)(11)(12). By using a variety of readouts, these studies demonstrated that YFVspecific CD8 ϩ T cell responses are polyfunctional, exhibit distinct surface phenotypic markers, and peak approximately 2 to 4 weeks after vaccination.…”

mentioning

confidence: 99%

Yellow Fever Vaccination Elicits Broad Functional CD4 ⁺ T Cell Responses That Recognize Structural and Nonstructural Proteins

James

LaFond

Gates

et al. 2013

J Virol

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bYellow fever virus (YFV) can induce acute, life-threatening disease that is a significant health burden in areas where yellow fever is endemic, but it is preventable through vaccination. The live attenuated 17D YFV strain induces responses characterized by neutralizing antibodies and strong T cell responses. This vaccine provides an excellent model for studying human immunity. While several studies have characterized YFV-specific antibody and CD8 ؉ T cell responses, less is known about YFV-specific CD4 ؉ T cells. Here we characterize the epitope specificity, functional attributes, and dynamics of YFV-specific T cell responses in vaccinated subjects by investigating peripheral blood mononuclear cells by using HLA-DR tetramers. A total of 112 epitopes restricted by seven common HLA-DRB1 alleles were identified. Epitopes were present within all YFV proteins, but the capsid, envelope, NS2a, and NS3 proteins had the highest epitope density. Antibody blocking demonstrated that the majority of YFV-specific T cells were HLA-DR restricted. Therefore, CD4؉ T cell responses could be effectively characterized with HLA-DR tetramers. Ex vivo tetramer analysis revealed that YFV-specific T cells persisted at frequencies ranging from 0 to 100 cells per million that are detectable years after vaccination. Longitudinal analysis indicated that YFV-specific CD4 ؉ T cells reached peak frequencies, often exceeding 250 cells per million, approximately 2 weeks after vaccination. As frequencies subsequently declined, YFV-specific cells regained CCR7 expression, indicating a shift from effector to central memory. Cells were typically CXCR3 positive, suggesting Th1 polarization, and produced gamma interferon and other cytokines after reactivation in vitro. Therefore, YFV elicits robust early effector CD4؉ T cell responses that contract, forming a detectable memory population. Members of the family Flaviviridae such as Yellow fever virus (YFV) are important causes of illness both historically and at present, causing a significant health burden in areas where yellow fever is endemic (1). Yellow fever (YF) produces symptoms ranging from a mild flu-like illness to hemorrhagic fever and organ failure, but infection is preventable through vaccination (2, 3). The YF vaccine uses a live attenuated virus (17D) and is safe and extremely effective, generating robust antibody responses that persist for decades (4, 5). The vaccine is known to elicit neutralizing antibodies and strong T cell responses in nearly all recipients (6, 7). Therefore, the YFV 17D vaccine is an excellent and important model for studying human antiviral immunity. Multiple studies have investigated the attributes and dynamics of CD4 ϩ and CD8 ϩ T cell responses following YF vaccination (8-12). By using a variety of readouts, these studies demonstrated that YFVspecific CD8 ϩ T cell responses are polyfunctional, exhibit distinct surface phenotypic markers, and peak approximately 2 to 4 weeks after vaccination. Blom et al. evaluated both CD4 ϩ and CD8 ϩ T cell responses by examinin...

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Lymphocyte subset analyses in healthy adults vaccinated with yellow fever 17DD virus

Cited by 28 publications

References 25 publications

Dynamics of the Cytotoxic T Cell Response to a Model of Acute Viral Infection

Dynamics of the Cytotoxic T Cell Response to a Model of Acute Viral Infection

Immune activation alters cellular and humoral responses to yellow fever 17D vaccine

Yellow Fever Vaccination Elicits Broad Functional CD4 ⁺ T Cell Responses That Recognize Structural and Nonstructural Proteins

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Lymphocyte subset analyses in healthy adults vaccinated with yellow fever 17DD virus

Cited by 28 publications

References 25 publications

Dynamics of the Cytotoxic T Cell Response to a Model of Acute Viral Infection

Dynamics of the Cytotoxic T Cell Response to a Model of Acute Viral Infection

Immune activation alters cellular and humoral responses to yellow fever 17D vaccine

Yellow Fever Vaccination Elicits Broad Functional CD4 + T Cell Responses That Recognize Structural and Nonstructural Proteins

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Yellow Fever Vaccination Elicits Broad Functional CD4 ⁺ T Cell Responses That Recognize Structural and Nonstructural Proteins