Interleukin-21, acting beyond the immunological synapse,independently controls T follicular helper and germinal center B cells

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T cell-expressed microRNAs critically regulate germinal center T follicular helper cell function and maintenance in acute viral infection in mice

Constitutive T cell-intrinsic miRNA expression is required for the differentiation of naïve CD4⁺ T cells into Tfh cells, thus making it difficult to study the role of miRNAs in the maintenance of already established Tfh cells and ongoing germinal center (GC) responses. To overcome this problem, we here used temporally controlled ablation of mature miRNAs specifically in CD4⁺ T cells during acute LCMV infection in mice. T cell-intrinsic miRNA expression was not only critical at early stages of Tfh cell differentiation, but also important for the maintenance of already established Tfh cells. In addition, CD4⁺ T cell-specific ablation of miRNAs resulted in impaired GC B cell responses. Notably, miRNA deficiency also compromised the antigen-specific CD4⁺ T cell compartment, Th1 cells, Treg cells, and Tfr cells. In conclusion, our results highlight miRNAs as important regulators of Tfh cells, thus providing novel insights into the molecular events that govern T cell–B cell interactions and Th cell identity.     

Aire deficient dendritic cells promote the T follicular helper cells differentiation

Autoimmune regulator (Aire), primarily expressed in medullary thymic epithelial cells (mTECs), maintains central immune tolerance through the clearance of self-reactive T cells. Aire can also be expressed in dendritic cells (DCs), and DCs can mediate T follicular helper (T_FH) cell differentiation and self-reactive B cell activation through inducible costimulator molecule ligand (ICOSL) and interleukin 6 (IL-6), which can cause autoimmune diseases. To confirm whether Aire in DCs affects T_FH cell differentiation and to determine the role of Aire in the maintenance of peripheral immune tolerance, this study observed the effects of Aire deficiency on T_FH cells using Aire knockout mice. The results showed that Aire deficiency caused increased number of T_FH cells, both in vivo and in vitro. Further studies showed that Aire deficiency promoted T_FH differentiation through the upregulation of ICOSL and IL-6 in DCs. Thus Aire could suppress the expression of ICOSL and IL-6 to inhibit T_FH cell differentiation.     

Human germinal center T cells are unique Th cells with high propensity for apoptosis induction

Collaborative interactions between T(h) cells and B cells are necessary for the production of antibody responses to most protein antigens and for the generation of memory B cells in germinal centers (GCs). Although it is well established that T(h) cells are pivotal for the GC reaction, the mechanisms that control the homeostasis of T(h) cells during the GC response remain largely unknown. Here we show that, unlike other effector T cells, a significant number of CD4(+)CD45RO(+)CD57(+) T cells, which are the major T(h) cells residing in the GCs, are undergoing apoptosis in vivo. CD4(+)CD45RO(+)CD57(+) GC T cells exhibit similar sensitivities to apoptotic signals and to caspase inhibitors as immature thymocytes. Moreover, CD4(+)CD45RO(+)CD57(+) GC T cells express a unique profile of genes that control apoptosis and cell cycle, providing possible molecular mechanisms for the high rates of apoptotic death of these T(h) cells in the GCs.     

Direct evidence that human follicular dendritic cells (FDC) rescue germinal centre B cells from death by apoptosis.

It is supposed that FDC have a pivotal role in the rescue of germinal centre (GC) B lymphocytes from apoptosis. However, formal proof for this hypothesis has not as yet been presented. In the present study FDC and GC B cells were isolated from human tonsils and cultured. When brought into culture FDC and B cells rapidly formed spherical clusters. T cells were not observed inside these clusters. At different time points cultures of FDC and B cells were supravitally stained with Hoechst 33258 or acridine orange and examined by direct observation using fluorescence microscopy. Viable B cells appeared to be profoundly restricted to clusters, whereas cells not taking part in clusters all had an apoptotic appearance. The formation of clusters could be prevented by addition of MoAbs against CD11a (LFA-1 alpha) or CD49d (VLA-4 alpha), resulting in an apoptotic appearance of virtually all B lymphocytes. The present data demonstrate that a physical interaction between FDC and germinal centre B lymphocytes is able to rescue the latter from apoptotic cell death.     

Appearance and phenotype of murine follicular dendritic cells expressing VCAM‐1

The architecture of lymphoid follicles is determined by a series of interactions between lymphoid and follicular stromal cells. A cardinal population in the non‐lymphoid compartment is the follicular dendritic cell (FDC), whose communication with resting and activated B cells involves various adhesive interactions. The FDC phenotype variably includes the display of vascular cell adhesion molecule (VCAM‐1). In this report we investigated the appearance and follicular tissue distribution of VCAM‐1 in murine peripheral lymphoid tissues, and compared VCAM‐1 with other FDC markers using immunohistochemistry. Correlating the appearance of VCAM‐1 with other murine FDC‐associated markers (CR1.2 [complement receptor 1.2 or CD35/21] and FDC‐M1) revealed that the display of VCAM‐1 is restricted to a subset of CR1.2‐positive FDCs. We found that the expression of VCAM‐1 antigen in the spleen or peripheral lymph nodes on FDCs requires antigenic stimulus, and that it coincides with germinal center formation. The VCAM‐1 expression is associated with the appearance of mucosal addressin cell adhesion molecule (MAdCAM‐1), with some slight differences in occurrence. The appearance of VCAM‐1 and MAdCAM‐1 antigens on FDCs may serve as indicators of FDC activation. Anat Rec 268:160–168, 2002. © 2002 Wiley‐Liss, Inc.     

From SAP-less T cells to helpless B cells and back: dynamic T-B cell interactions underlie germinal center development and function

Operation of the immune system critically depends on intercellular communication among multiple cell types, frequently in the form of physical cell-cell interactions. Germinal centers (GCs) are highly organized tissue microdomains in which high affinity, class-switched, antibody-producing cells and humoral immune memory are generated. Critical underlying cell-cell interaction events include at the minimum binary interactions between CD4(+) T-helper cells and antigen-presenting dendritic cells (DCs), which ensure proper T-cell activation and acquisition of effecter potentials, and those between T-helper cells and antigen-activated B cells whereby the latter cells receive helper signals (e.g. CD40L) important for their proliferation, survival, and differentiation. How these critical cellular interaction events are molecularly regulated and dynamically orchestrated to support GC formation and function is still a study in progress. Signaling lymphocytic activation molecule (SLAM)-associated protein (SAP) has recently been defined as a pivotal molecule that controls cognate T-B interactions and GC formation. Detailed analysis of interaction and migration dynamics of SAP-deficient T cells has raised the interesting possibility that T cell:antigen-presenting cell interactions underlying GC development and function are regulated in a cell type- and spatiotemporal stage-specific manner. This has important implications for our understanding of synapse formation, helper signal delivery to B cells, follicular helper T-cell differentiation, and quality control of the GC reaction in general. A model of selective T-B interactions involving bi-directional feedback and feed-forward logic is proposed to underlie GC development and function.     

From dendritic cells to B cells dysfunctions during HIV‐1 infection: T follicular helper cells at the crossroads

T follicular helper (Tfh) cells are essential for B‐cell differentiation and the subsequent antibody responses. Their numbers and functions are altered during human and simian immunodeficiency virus (HIV/SIV) infections. In lymphoid tissues, Tfh cells are present in germinal centre, where they are the main source of replicative HIV‐1 and represent a major reservoir. Paradoxically, Tfh cell numbers are increased in chronically infected individuals. Understanding the fate of Tfh cells in the course of HIV‐1 infection is essential for the design of efficient strategies toward a protective HIV vaccine or a cure. The purpose of this review is to summarize the recent advance in our understanding of Tfh cell dynamics during HIV/SIV infection. In particular, to explore the possible causes of their expansion in lymphoid tissues by discussing the impact of HIV‐1 infection on dendritic cells, to identify the molecular players rendering Tfh cells highly susceptible to HIV‐1 infection, and to consider the contribution of regulatory follicular T cells in shaping Tfh cell functions.     

T cells that promote B-Cell maturation in systemic autoimmunity

Follicular helper T (Tfh) cells play an essential role in helping B cells generate antibodies upon pathogen encounters. Such T-cell help classically occurs in germinal centers (GCs) located in B-cell follicles of secondary lymphoid organs, a site of immunoglobulin affinity maturation and isotype switching. B-cell maturation also occurs extrafollicularly, in the red pulp of the spleen and medullary cords in lymph nodes, with plasma cell formation and antibody production. Development of extrafollicular foci (EF) in T-cell-dependent (TD) immune responses is reliant upon CD4(+) T cells with characteristics of Tfh cells. Pathogenic autoantibodies, arising from self-reactive B cells having undergone somatic hypermutation with affinity selection and class switching within GCs and EF, are major contributors to the end-organ injury in systemic autoimmunity. B cells maturing to produce autoantibodies in systemic autoimmune diseases, like those in normal immune responses, largely require T-helper cells. This review highlights Tfh cell development as an introduction to a more in-depth discussion of human Tfh cells and blood borne cells with similar features and the role of these cells in promotion of systemic autoimmunity.     

Recirculation of germinal center B cells: a multilevel selection strategy for antibody maturation

Summary:  Optimization of antibody affinity is a hallmark of the humoral immune response. It takes place in hundreds of transient microstructures called germinal centers (GCs). Their function and time-dependent behavior are subjects of active investigation. According to a generally accepted notion, their individual kinetics follows the average kinetics of all GCs present in the observed lymphatic tissue. In this review, we challenge this view and point out, with the help of mathematical simulations, that inferring the kinetics of individual GCs from cross-sectional evaluation of GC kinetics is virtually impossible. Thus, the time course of individual GCs is open to conjecture. For instance, one possible interpretation is that GCs exist for a time span considerably shorter than that of the observed average kinetics. We explore the implications of different temporal organizations of GCs in the light of the hypothesis that GC B-cell emigrants recolonize GC niches. This assumption leads to a view where GCs work in parallel but are linked by recirculation of B-cell emigrants. In this view, interleaved global and local competition provide for an implementation of multiple levels of B-cell selection in affinity maturation. The concepts of iteration, all-or-none behavior, and phasic mutation schedule are discussed in the light of this hypothesis.     

Follicular dendritic cells restrict interleukin-4 availability in germinal centers and foster memory B cell generation

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T Cell Help to B Cells in Germinal Centers: Putting the Jigsaw Together

The germinal center (GC) reaction supports the processes of affinity maturation and class switching in B cells that result in long-lasting humoral immunity. CD4⁺ T follicular helper cells (Tfh) participate in the GC reaction to help B cells. However, recent studies highlight the heterogeneity of CD4⁺ T cells in GCs, which confounds the understanding of Tfh cells. Based on many recent studies, we have tried to form a working model on the niche of Tfh cells in GCs. We have also addressed whether Tfh cells are a distinct lineage and how they may be generated to help B cells.     

Plasma cell differentiation during the germinal center reaction

Germinal centers (GCs) are formed in secondary lymphoid tissues upon immunization with T‐dependent antigens. In GCs, somatic hypermutation generates B cells with increased antibody affinity and these high‐affinity B cells preferentially differentiate into plasma cells, which home to bone marrow and confer long‐lived humoral immunity. Recent studies have shed new light on the cellular and molecular basis for initiating the transition from a GC B cell to a plasma cell. Here, we review recent progress in our understanding of how plasma cell generation during the GC reaction is regulated for inducing effective long‐term protective immunity and for preventing harmful autoimmunity.     

滤泡辅助性T细胞与相关疾病研究进展

滤泡辅助性T细胞(Tfh)是近几年发现的一种新的T细胞亚群,与Th1细胞、Th2细胞、Th17细胞及调节性T细胞(Tr)相互促进或拮抗,维持免疫系统的正常生理功能,其主要功能是辅助B细胞分化、发育和促进体液免疫应答,当Tfh细胞数量或功能紊乱时可引起自身免疫病、免疫缺陷病、肿瘤或感染性疾病的发生或加重.     

Primary germinal center-resident T follicular helper cells are a physiologically distinct subset of CXCR5hiPD-1hi T follicular helper cells

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T follicular helper cell heterogeneity: Time,space, and function

T follicular helper (Tfh) cells play a crucial role in orchestrating the humoral arm of adaptive immune responses. Mature Tfh cells localize to follicles in secondary lymphoid organs (SLOs) where they provide help to B cells in germinal centers (GCs) to facilitate immunoglobulin affinity maturation, class‐switch recombination, and generation of long‐lived plasma cells and memory B cells. Beyond the canonical GC Tfh cells, it has been increasingly appreciated that the Tfh phenotype is highly diverse and dynamic. As naive CD4⁺ T cells progressively differentiate into Tfh cells, they migrate through a variety of microanatomical locations to obtain signals from other cell types, which in turn alters their phenotypic and functional profiles. We herein review the heterogeneity of Tfh cells marked by the dynamic phenotypic changes accompanying their developmental program. Focusing on the various locations where Tfh and Tfh‐like cells are found, we highlight their diverse states of differentiation. Recognition of Tfh cell heterogeneity has important implications for understanding the nature of T helper cell identity specification, especially the plasticity of the Tfh cells and their ontogeny as related to conventional T helper subsets.