The impact of poly-microbial sepsis on pre-existing memory CD8 T cell responses

Duong, Sean Duy

01 December 2013

No description available.

memory CD8 T cells

sepsis

Pathology

The Contribution of Cytomegalovirus Infection to Immune Senescence Is Set by the Infectious Dose

Redeker, Anke, Remmerswaal, Ester B. M., van der Gracht, Esmé T. I., Welten, Suzanne P. M., Höllt, Thomas, Koning, Frits, Cicin-Sain, Luka, Nikolich-Žugich, Janko, ten Berge, Ineke J. M., van Lier, René A. W., van Unen, Vincent, Arens, Ramon

10 January 2018

The relationship between human cytomegalovirus (HCMV) infections and accelerated immune senescence is controversial. Whereas some studies reported a CMV-associated impaired capacity to control heterologous infections at old age, other studies could not confirm this. We hypothesized that these discrepancies might relate to the variability in the infectious dose of CMV occurring in real life. Here, we investigated the influence of persistent CMV infection on immune perturbations and specifically addressed the role of the infectious dose on the contribution of CMV to accelerated immune senescence. We show in experimental mouse models that the degree of mouse CMV (MCMV)-specific memory CD8(+) T cell accumulation and the phenotypic T cell profile are directly influenced by the infectious dose, and data on HCMV-specific T cells indicate a similar connection. Detailed cluster analysis of the memory CD8(+) T cell development showed that high-dose infection causes a differentiation pathway that progresses faster throughout the life span of the host, suggesting a virus-host balance that is influenced by aging and infectious dose. Importantly, short-term MCMV infection in adult mice is not disadvantageous for heterologous superinfection with lymphocytic choriomeningitis virus (LCMV). However, following long-term CMV infection the strength of the CD8(+) T cell immunity to LCMV superinfection was affected by the initial CMV infectious dose, wherein a high infectious dose was found to be a prerequisite for impaired heterologous immunity. Altogether our results underscore the importance of stratification based on the size and differentiation of the CMV-specific memory T cell pools for the impact on immune senescence, and indicate that reduction of the latent/lytic viral load can be beneficial to diminish CMV-associated immune senescence.

CMV

memory CD8 T cells

immunesenesence

mouse models

memory inflation

The role of DOCK8 in the maintenance of CD8+ T cell memory and invariant NKT cells

Crawford, Greg Hugh

January 2012

The use of genome wide ENU mutagenesis screening has uncovered vast numbers of novel genes involved in the control of the immune system. This thesis describes the characterization of a novel mutant, Captain Morgan (CPM), originally identified in an immunization screen designed to evaluate both the initial antibody response to antigen and the ability to sustain antibody production. Mapping of this mutant lead to the identification of a single base pair mutation in a novel guanine nucleotide exchange factor, dedicator of cytokinesis 8 (DOCK8). The mutation was found to result in altered gene splicing of the DOCK8 protein leading to the truncation of the protein and loss of catalytic function. The importance of understanding the role of DOCK8 in host immunity has been recently underlined by the discovery that cohorts of patients suffering from autosomal recessive forms of hyper-IgE syndrome have loss-of-function or deletions in this novel guanine nucleotide exchange factor. Disease in these patients is characterised by recurrent viral and bacterial infections mainly of the skin and lungs, with reduced levels of peripheral CD4⁺ and CD8⁺ T cells in the blood of patients. Patients also have high levels of IgE and eosinophilia in the blood and are highly atopic with increased prevalence of allergic diseases including asthma. Loss of DOCK8 function results in a number of phenotypes in CPM mice, which may help understand the immunodeficiency syndrome experienced by DOCK8 deficient patients. CPM mice, like DOCK8 deficient patients, are lymphopenic with losses of both CD4⁺ and CD8⁺ T cells in the blood and secondary lymphoid organs. Challenge of CPM mice with modified vaccina virus (MVA) and influenza strain X31 demonstrated normal primary anti-viral responses. However, similar to the loss of germinal centre B cells previously described in these mice, memory T cell responses were diminished, which may explain the susceptibility of DOCK8 deficient patients to recurrent infections. In addition to the loss of peripheral T cells, rare populations of lymphocytes such as invariant natural killer T cells (iNKT) were also reduced in the liver and thymus. Due to their roles in bacterial and viral responses and cancer immunosurveillance it is expected that loss of these cells will contribute to disease severity. Together these findings illustrate the importance of the ENU mutagenesis model for generating new mutants, which can enhance our understanding of mammalian genes and create disease models of human disease. Further characterization of DOCK8 deficiency and the molecular mechanisms of DOCK8 function will have important implications for disease diagnosis and ongoing treatment for patients.

616.079

Naive and memory CD8 T cell responses after antigen stimulation in vivo

Martin, Matthew David

01 January 2011

The extent to which the progeny of one primary memory CD8 T cell differs from the progeny of one naïve CD8 T cell of the same specificity remains an important question. In order to explore cell autonomous functional differences between naïve and memory CD8 T cells that are not influenced by differences in the priming environment, an experimental model has been developed in which physiological numbers of both populations of cells were co-transferred into naïve host before antigen-stimulation. Interestingly, naïve CD8 T cells expand in numbers more than primary memory CD8 T cells after various infections or immunizations. The intrinsic ability of one naïve CD8 T cell to give rise to more effector CD8 T cells than one memory CD8 T cell is independent of the number of primary memory CD8 T cells present in vivo. The sustained proliferation of primary, but not the increased death of secondary effectors was shown to contribute to the differences in the observed magnitudes of expansion. In addition, longitudinal analysis of primary and secondary CD8 T cell responses revealed that the ability of naïve CD8 T cells to generate long-lived progeny (`memory generation potential') is better than for primary memory CD8 T cells despite the differences in overall kinetics of both responses after infection. Taken together, the data presented here revealed previously unappreciated differences between naïve and memory CD8 T cells and will help further define the functional potential for both cell types. The goal of immunization is to generate memory CD8 T cells of sufficient quality and quantity, and it has been shown that the naïve to primary memory CD8 T cell differentiation in vivo is controlled, at least in part, by the amount and duration of inflammation present early after the initiation of the response. In experiments where naïve CD8 T cells were co-transferred with increasing numbers of primary memory CD8 T cells, we observed a negative correlation between the number of primary memory present and the magnitude of primary CD8 T cell responses. Interestingly, the conversion of newly recruited (either TCR-Tg or endogenous) primary CD8 T cells into CD8 T cells with the phenotype (CD62Lhi, CD27hi) and function (tissue distribution, Ag-driven proliferation, cytokine production) of long-term memory was facilitated when they were primed in the presence of memory CD8 T cells of the same or unrelated specificity. Therefore, these data suggest that the presence of anti-vectorial immunity will not necessarily decrease the efficacy of CD8 T cell vaccination since newly recruited CD8 T cells, despite their decreased magnitude of expansion, might differentiate into functional memory cells faster.

anti-vectorial immunity

immunity

Memory CD8 T cells

Naive CD8 T cells

Pathology

Time-dependent alterations in memory CD8 T cell function after infection

Martin, Matthew David

01 May 2016

CD8 T cells play a critical role in the clearance of pathogenic bacteria, viruses, and protozoan parasites. Upon encountering their cognate antigen through either infection or vaccination, naïve CD8 T cells undergo robust proliferative expansion, which is followed by contraction and the formation of a memory population. Memory CD8 T cells are long-lived, and because they persist in increased numbers and possess enhanced functional abilities compared to naïve CD8 T cells, they are able to provide the host with increased protection following re-infection. Because of these properties, vaccines designed to elicit memory CD8 T cells have the potential to reduce health care burdens related to infection with pathogens including human immuno deficiency virus (HIV), malaria, influenza, and hepatitis virus. However, stimulating protective CD8 T cell responses against these pathogens through vaccination has proven challenging. Therefore, a better understanding of the properties of memory CD8 T cells generated following vaccination, and the characteristics of memory CD8 T cells best suited for providing protection against diverse pathogens is needed. While memory CD8 T cells can be maintained for as long as the life of the host, evidence suggests that their properties change with time after infection. Because CD8 T cell-mediated protection is based upon both the numbers and quality or functional abilities of memory cells present at the time of re-infection, changes in memory CD8 T cell function over time could impact their ability to provide protection upon re-infection. Therefore, a better understanding of how memory CD8 T cells change with time after infection is needed. As part of the studies presented in this thesis, I found that the phenotype and function of memory CD8 T cells including localization, interleukin (IL)-2 cytokine production, responsiveness to homeostatic cytokines, metabolic capabilities, and proliferation and secondary memory generation potential change with time after infection. Interestingly functional changes could not be completely explained by changes in subset composition that occur with time, as changes over time were also seen in defined CD62Lhi subsets. Importantly, functional changes of memory CD8 T cells that occurred with time led to an increased ability to provide protection against a chronic viral infection. These data improve our knowledge of the capabilities of memory CD8 T cells generated following infection, and suggests that the outcome of vaccination strategies designed to elicit protective memory CD8 T cells using single or prime-boost immunizations will depend upon the timing between antigen encounters. Following re-infection, memory CD8 T cells become activated and produce effector cytokines and cytolytic molecules that aid the host in clearing invading microbes. Activation can be triggered not only through cognate antigen recognition, but also by antigen-independent cytokine driven signals. However, our knowledge of how antigen-dependent and –independent signals contribute to CD8 T cell activation and protection following infection is incomplete. In the second part of my thesis, I show that the ability of memory CD8 T cells to become activated in response to inflammation decreases with time after infection, that antigen and inflammation act synergistically to induce activation of memory CD8 T cells, that the presence of cognate antigen enhances activation of memory CD8 T cells that contribute to clearance of infection, and that bystander memory CD8 T cell responses following unrelated bacterial infection do not provide the host with a protective benefit. Together, the data in this thesis further our understanding of memory CD8 T cells generated following infection and/or vaccination, and the properties of memory CD8 T cells important for providing protection upon re-infection with invading pathogens.

publicabstract

Bacterial Infection

Memory CD8 T Cells

Protection from infection

Vaccination

Viral Infection

Immunology of Infectious Disease

Transcriptional control of innate memory CD8+ T cells

Istaces, Nicolas

25 November 2019

CD8+ T cells are essential for host protection against intracellular pathogens and tumors. During antigen-driven responses, CD8+ T cell fate is governed by transcriptional and epigenetic processes that allow naïve CD8+ T cells to develop into a wide range of effector and conventional memory cell subsets. Over the last decades, novel techniques and major efforts led to a better understanding of the origin, nature, and short- and long-term effects of these processes on individual CD8+ T cells. Under certain conditions, naïve CD8+ T cells can acquire memory phenotype and functions in an antigen-independent manner. Although homeostatic cytokines and initial activation pathways that drive the development of these unconventional memory cells had been identified, the ensuing transcriptional profile of these cells and their degree of similarity with conventional memory cells remained ill-defined. The epigenetic events that accompany unconventional memory formation were also not known.Here, we show that innate memory cells, a type of thymic unconventional memory cells, are transcriptionally close to conventional memory cells but only partially epigenetically programmed toward the full memory fate. We also show that the sole overexpression of the transcription factor Eomesodermin (EOMES), a master regulator of effector and conventional memory cells, is able to drive many of the phenotypical, functional, transcriptional, and epigenetic features of innate memory cells, and to induce the recruitment of BRG1, a member of chromatin remodeling complexes, to innate memory gene regulatory regions. We further show that the in vivo interleukine-4-dependent development of innate memory cells is largely dependent on BRG1. We bring to light that, in innate memory cells, EOMES is recruited in many instances to genomic regions previously bound by the transcription factor RUNX3. Overall, we provide insights into the mechanisms that allow memory cell formation and T cell receptor stimulation to be uncoupled. / Doctorat en Sciences médicales (Médecine) / info:eu-repo/semantics/nonPublished

Sciences bio-médicales et agricoles

Immunity

Innate memory CD8+ T cells

Transcription factors

Epigenetics

Eomesodermin

RUNX3

BRG1

The generation and differentiation of memory CD8 T cell responses in health and disease

Khan, Shaniya H

01 July 2015

Memory CD8 T cells offer increased protection to immune hosts by rapidly eliminating pathogen-infected cells during re-infection. Generating and sustaining a protective memory CD8 T cell response is considered a hallmark of adaptive immunity. Extensive research has been devoted to understanding the parameters affecting memory CD8 T cell generation after infection or immunization in order to design the most effective vaccines. An accepted notion in the field is that increased protection from re-infection is afforded by the generation of a large number of memory CD8 T cells. Consecutive prime-boost immunization strategies that elicit secondary responses are often used to increase the absolute numbers of memory CD8 T cells. While parameters affecting the generation of primary memory CD8 T cells are well known, the factors influencing the development of re-stimulated secondary CD8 T cell responses remain understudied. Here, I addressed the mechanisms involved in the generation and development of secondary memory CD8 T cells. I found that the time at which primary memory CD8 T cells enter into an immune response during re-infection impacts their fate and differentiation into secondary memory CD8 T cells. Late-entry of primary memory CD8 T cells into an immune response (relative to the initiation of infection) not only facilitates expression of transcription factors associated with memory formation in secondary effector CD8 T cells, but also influences the ability of secondary memory CD8 T cells to localize within the lymph nodes, produce interleukin-2 cytokine (IL-2), and undergo robust antigen-driven proliferation. The timing of stimulation of primary memory CD8 T cells also impacts the duration of expression of the high-affinity IL-2 receptor (CD25) on secondary effector CD8 T cells and their sensitivity to IL-2 signaling. Importantly, by blocking or enhancing IL-2 signaling in developing secondary CD8 T cells, I verify the role of IL-2 in controlling the differentiation of secondary CD8 T cell responses. The data I present herein suggest that the process of primary memory-to-secondary memory CD8 T cell differentiation is not fixed and can be manipulated, a notion with implications in the design of future prime-boost vaccination approaches. Although vaccines are designed and intended to benefit a range of individuals, at times the efficacy of a vaccination regime depends on the overall health status of a host. Thus, in another portion of my thesis work I explored the extent to which obesity compromises the differentiation and maintenance of protective memory CD8 T cell responses. I found that diet-induced obesity did not impact the maintenance of pre-existing memory CD8 T cells, including their acquisition of a long-term memory phenotype (i.e., CD27hi, CD62Lhi, KLRG1low) and function (i.e., cytokine production, antigen-driven secondary expansion, and memory CD8 T cell-mediated protection). Additionally, diet-induced obesity did not influence the differentiation and maintenance of newly evoked memory CD8 T cell responses, in inbred and outbred hosts, that were generated in response to different types of systemic (LCMV, L. monocytogenes) and/or localized (influenza virus) infections. Interestingly, I found that the rate of naïve-to-memory CD8 T cell differentiation after a peptide-coated dendritic cell immunization was similar in lean and obese hosts. This suggests that obesity-associated inflammation is unlike pathogen- or adjuvant-induced inflammation, and does not influence the development of an endogenous memory CD8 T cell response. My studies reveal that the obese environment does not influence the development or maintenance of memory CD8 T cell responses that are either primed before or after obesity is established. This is a surprising notion with implications for future studies aiming to elucidate the role of obesity in susceptibility to infection and vaccine efficacy. Collectively, the data presented here further the understanding of memory CD8 T cell responses in contexts of health and disease.

publicabstract

Diet-Induced Obesity

Inflammation

Memory CD8 T Cells

Pathogen

Prime-Boost

Secondary Memory

Immunology of Infectious Disease

MECHANISTIC UNDERSTANDING OF THE REGULATION OF LUNG RESIDENT MEMORY T CELLS INDUCED BY TB VACCINATION STRATEGIES

Haddadi, Siamak

January 2018

In the recent years, it has been well established that primary respiratory viral infection-induced lung resident memory CD8 T cells (TRM) characterized by the expression of integrins CD49a and CD103, as well as the early-activation marker CD69, constitute the first line of defense against reinfection. On the other hand, viral vector-based respiratory mucosal (RM) vaccination, as well as parenteral vaccination followed by airway luminal manipulation induce lasting and protective lung T cell immunity towards pulmonary tuberculosis (TB). However, it remains poorly understood whether and how these TB vaccination strategies induce TRM in the lung. As such, within this thesis we will investigate generation of lung CD8 TRM upon different TB vaccination strategies and the underlying mechanisms regulating establishment of such cells. Here using distinct models of replication-deficient adenoviral vector-based TB vaccination, we find that RM vaccination leads to generation of lung CD8 TRM identified by the expression of CD69, CD103, and very late activation Ag 1 (VLA-1). These TRM-associated molecules are acquired by CD8 T cells in distinct tissues. In this regard, VLA-1 is acquired during T cell priming in draining mediastinal lymph nodes (dMLNs) and the others acquired after T cells entered the lung. Once in the lung, Ag-specific CD8 TRM continue to express VLA-1 at high levels through the effector/expansion, contraction, and memory phases of T cell responses. We also reveal that VLA-1 is not required for homing of these cells to the lung, but it negatively regulates them in the contraction phase. Furthermore, VLA-1 has a negligible role in the maintenance of such cells in the lung. Separately, we have observed that while parenteral intramuscular vaccination alone does not induce lung CD8 TRM, subsequent RM inoculation of an Ag-dependent, but not a non-specific inflammatory agonist induces lung CD8 TRM. Such generation of lung CD8 TRM needs CD4 T cell help. These findings not only fill the current knowledge gap, but also hold important implications in developing effective vaccination strategies towards mucosal intracellular infectious diseases such as acquired immunodeficiency syndrome (AIDS), TB and herpes virus infection. / Thesis / Doctor of Philosophy (PhD)

Mémoire lymphocytaire T et persistance virale / T Memory lymphocyte and viral persistence

Jaafoura, Salma

11 December 2014

Au cours d’une réponse immunitaire primaire, les lymphocytes T CD8 mémoires émergent à partir d'un environnement de forte activation immunitaire. Les cellules régulatrices T CD4 FoxP3+ (LTregs) jouent un rôle clé de suppression de la réponse immunitaire. Nous montrons que les LTregs sont nécessaires pour la génération d’une réponse mémoire T CD8 fonctionnelle. En absence de LTregs lors du priming, les LT CD8 mémoires générées prolifèrent faiblement et ne parviennent pas à se différencier après une réactivation antigénique en effecteurs cytotoxiques secondaires fonctionnelles. Nous suggérons que les LTregs agissent tôt, lors de la phase d'expansion des LT CD8, en réduisant l’exposition des précurseurs mémoires T CD8 à l'interleukine-2. Ce nouveau rôle crucial des LTregs a des implications pour le développement optimal de vaccin.Chez les patients sous traitement antirétroviral efficace et prolongée (ART), le VIH peut persister dans un petit pool de cellules T CD4 mémoires quiescentes de longue durée de vie infectées par du virus latent intégré. Ce réservoir latent comprend différentes sous-populations mémoires. Nos résultats suggèrent une contraction progressive de la taille du réservoir latent autour d'un noyau formé de sous-populations T CD4 mémoires moins différenciées (centrales mémoires TCM et souches mémoires TSCM). Ce processus très lent semble dépendre de la taille initiale et du taux de décroissance qui diffère entre les sous-populations mémoires infectées de manière latente. Nos résultats suggèrent également une extrême stabilité du sous-réservoir TSCM, dont la taille est directement liée à l'exposition cumulée au virus plasmatique avant le début du traitement ART, soulignant l'importance d'une initiation précoce du traitement antirétroviral efficace. La présence de cette dynamique intrinsèque dans le réservoir latent peut avoir des implications pour la conception de stratégies optimales de purge thérapeutique contre le VIH. / During the primary immune response, CD8 memory emerges from an environment of strong immune activation. The FoxP3 regulatory CD4 T-cell subset (Treg) is known as a key suppressive component of the immune system. We report that Tregs are required for the generation of functional CD8 memory. In the absence of Tregs during priming, the resulting memory cells proliferate poorly and fail to differentiate into functional cytotoxic secondary effectors following antigen reactivation. We find that the Tregs act early, during the expansion phase of primary CD8 effectors, by fine tuning interleukin-2 exposure of CD8 memory precursors. This crucial new role of Tregs has implications for optimal vaccine development. In patients who are receiving prolonged antiretroviral treatment (ART), HIV can persist within a small pool of long-lived resting memory CD4 T cells infected with integrated latent virus. This latent reservoir involves distinct memory subsets. We provide results that suggest a progressive reduction of the size of the blood latent reservoir around a core of less-differentiated memory subsets (central memory and stem cell-like memory).This process appears to be driven by the differences in initial sizes and decay rates between latently infected memory subsets. Our results also suggest an extreme stability of the TSCM sub-reservoir, the size of which is directly related to cumulative plasma virus exposure before the onset of ART, stressing the importance of early initiation of effective ART. The presence of these intrinsic dynamics within the latent reservoir may have implications for the design of optimal HIV therapeutic purging strategies.

Aide T CD4

Lymphocytes T CD8 mémoires

Lymphocyte T CD4

Réservoir latent

Sous populations mémoires CD4

TSCM

Taux de décroissance

VIH

CD4 help

Memory CD8 T cells

CD4 T cells

Latent reservoir

HIV

Memory CD4 T cells

TSCM

Decay rates