Identification of a novel subpopulation of germinal center B cells characterized by expression of IgD and CD70

CD27, which belongs to the tumor necrosis-factor receptor family, is expressed on germinal center (GC) but not on naive B cells, suggesting an important function of this molecule in the regulation of the GC reaction. We described here the expression of CD70, which is the ligand for CD27. We observed that in most tonsils, CD70 is only expressed on part of the IgD^?, CD38^? B cell population, which have been described as memory B cells. However, in 10 % of the tonsils tested, CD70⁺ IgD⁺ GC were found. The CD70⁺ GC B cells were small cells that also expressed CD44 and CD39, but were CD10^? and CD38^?, suggesting that they represent very recent immigrants that are in the process of forming a GC. The concordant expression of CD27 and its ligand CD70 on this primordial subset of GC B cells suggests an important role for CD27/CD70 interaction at this stage of GC formation.     

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.     

Engagement of CD20 suppresses apoptosis in germinal center B cells

In a screen of 67 monoclonal antibodies (mAb) included in the Blind Panel of B cell antibodies for the 5th International Workshop on Human Leukocyte Differentiation Antigens, only the CD20 mAb – included as a positive control for immunophenotyping studies – was found to suppress the spontaneous apoptosis which occurs in human germinal center (GC) B cells when placed in tissue culture at 37°C. Further detailed study using the 1F5 mAb confirmed this observation, showing that rescue from apoptosis via CD20, while not as efficient as that obtained on ligating CD40, was of similar magnitude to that achieved on engagement of surface immunoglobulin (sIg) by immobilized antibody. Also similar to anti-Ig, the CD20 mAb rescued from apoptosis without priming for the proliferation of GC B cells: this was quite different to its action on resting, non-GC B cells, where it provides a potent priming signal for cell cycle progression in response to IL-4 or anti-CD40. Unlike the survival signal engendered via sIg, CD20 engagement neither mobilized Ca²⁺ from intracellular stores or opening of a Ca²⁺ channel with 1F5, nor did it affect the ability of anti-Ig to open a Ca²⁺ gate in GC B cells. An unexpected feature of CD20-mediated rescue of GC B cells from apoptosis was a failure to turn on Bcl-2 expression.     

Identification of a tonsil IgD+ B cell subset with phenotypical and functional characteristics of germinal center B cells

We have identified and isolated a subpopulation of IgD⁺ B cells (IgD⁺ CD38⁺ B cells) from human tonsils which expresses the germinal center (GC)-associated surface markers CD10, CD38, CD75, CD77 and CD95/Fas. The heterogeneity of expression of several markers on IgD⁺ CD38⁺ B cells suggests that this population can be further subdivided into two discrete subtypes. On a functional basis, IgD⁺ CD38⁺ B cells behave as GC B cells as they rapidly and spontaneously undergo apoptosis in vitro and cannot be stimulated to synthesize DNA upon cross-linking of the antigen receptor. However, in contrast with most GC B cells, IgD⁺ CD38⁺ B cells have not completed Ig class switching since they predominantly secrete IgM following stimulation in vitro and lack surface expression of secondary isotypes. Immunoenzymatic staining performed on tonsil tissue sections revealed that IgD⁺ CD38⁺ B cells are located in two distinct histological structures: within the GC of a few classical secondary follicles, in which they appear as scattered cells, and within rare atypical GC, homogeneously constituted of IgD⁺ B cells. Taken together, our findings indicate that IgD⁺ CD38⁺ B cells constitute a novel subset of GC B cells. The possibility that these cells could represent an early stage of the follicular reaction or be generated in response to certain bacterial carbohydrate antigens is discussed.     

Antigen receptor-induced apoptosis of human germinal center B cells is targeted to a centrocytic subset

The outcome of the signals transduced through the B cell antigen receptor (BCR) depends both on their maturational stage and on the extent of receptor cross-linking. It is established that the BCR-mediated apoptosis of immature B cells represents an important mechanism for tolerance induction in the pre-immune B cell compartment. We show here that mature germinal center (GC) B cells can re-acquire sensitivity to BCR-induced cell death following CD40 ligation. In contrast, neither virgin nor memory B cells become susceptible to antigen receptor-triggered apoptosis upon CD40 stimulation, suggesting that this phenomenon may play a role in the shaping of the mature B cell repertoire in GC. Our data reveal that the death signal evoked through the BCR does not involve the Fcγ receptors, does not operate through the Fas/Fas ligand system, and can be blocked by interleukin-4. Finally, we found that the acquisition of sensitivity to the death-promoting effect of anti-Ig antibodies in CD40-stimulated GC B cell cultures correlates with the induction of a centrocytic phenotype. We propose that negative regulatory signals via the BCR may delete somatically mutated centrocytes with self-reactivity.     

Differentiation and apoptosis of human germinal center B-lymphocytes

An in vitro experimental model was developed to characterize the cellular and molecular factors that regulate germinal center (GC)B-cell differentiation and apoptosis. In the culture system that sustains the GC-B-cell survival, CD40L stimulation is essential for GC-B-cell proliferation and differentiation in the presence of 1L-2, IL-4, and IL-10. IL-2 and IL-4 promote proliferation of GC-B-cells, whereas IL-10 is required for generation of plasma cells. Generation of memory B cells requires CD40L, IL-2, IL-4, but not IL-10. There are two mechanisms that cause apoptosis. In the early stage, spontaneous apoptosis occurs in the absence of CD40 stimulation. Following CD40L stimulation, Fas-mediated apoptosis operates to eliminate GC-B-cells, unless activated GC-B-cells encounter a second signal via B-cell Ig receptors. Physiological significance of these findings is discussed.     

Early depletion of proliferating B cells of germinal center in rapidly progressive simian immunodeficiency virus infection

Lack of virus specific antibody response is commonly observed in both HIV-1-infected humans and SIV-infected monkeys with rapid disease progression. However, the mechanisms underlying this important observation still remain unclear. In a titration study of a SIVmac239 viral stock, three out of six animals with viral inoculation rapidly progressed to AIDS within 5 months. Unexpectedly, there was no obvious depletion of CD4(+) T cells in both peripheral and lymph node (LN) compartments in these animals. Instead, progressive depletion of proliferating B cells and disruption of the follicular dendritic cell (FDC) network in germinal centers (GC) was evident in the samples collected at as early as 20 days after viral challenge. This coincided with undetectable, or weak and transient, virus-specific antibody responses over the course of infection. In situ hybridization of SIV RNA in the LN samples revealed a high frequency of SIV productively infected cells and large amounts of accumulated viral RNA in the GCs in these animals. Early severe depletion of GC proliferating B cells and disruption of the FDC network may thus result in an inability to mount a virus-specific antibody response in rapid progressors, which has been shown to contribute to accelerated disease progression of SIV infection.     

IL-10 interrupts memory B cell expansion in the germinal center by inducing differentiation into plasma cells

Germinal center (GC) B cells undergo proliferation, somatic hypermutation and isotype switching in the course of differentiation into plasma cells to produce high-affinity antibodies. To understand the molecular mechanism regulating the expansion of memory B cells and the termination of expansion by differentiation into plasma cells, we investigated the effect of interleukin-2 (IL-2), IL-4, IL-10 and CD40 ligand (CD40L) on the differentiation of GC B cells in the defined culture system containing a follicular dendritic cell (FDC)-like cell line. IL-2, IL-4 and CD40L are required for the optimum proliferation and differentiation of GC B cells. When IL-10 was added to this culture condition, CD20⁺ CD38⁺ GC B cells sequentially differentiated into CD20⁺ CD38⁻ memory B cells and then CD20⁻ CD38⁺ plasma cells. In the absence of IL-10, the resulting CD20⁺ CD38⁻ memory B cells continued to proliferate and retained its phenotype. The proliferation of memory B cells was interrupted by addition of IL-10 which induced the differentiation into plasma cells. The expression of CD80 and CD86 was up-regulated in the memory B cells, compared to naive B cells and plasma cells. The identity of memory B cells generated in vitro from GC B cells was further substantiated since memory B cells generated in vivo displayed the identical pattern of proliferation and differentiation under the same culture condition. These results highlight the potent role of GCT helper cells in the expansion and differentiation of memory B cells by regulating different cytokine production.     

A subset of anti-CD21 antibodies promote the rescue of germinal center B cells from apoptosis

Germinal center cells (GCC) are programmed to die by apoptosis unless they receive a positive signal for rescue. The primary signal in vivo is believed to be dependent on interaction with antigen held as immune complexes on follicular dendritic cells (FDC), a subset of which express large amounts of CD23, a low-affinity receptor for IgE. Recombinant soluble CD23 (sCD23) and interleu-kin-1 have been found to potentiate the survival of GCC in vitro. Recently, CD23 was shown to interact specifically with a ligand other than IgE, namely CD21 (CR2/Epstein-Barr virus receptor). In the present study, we show that a subset of anti-CD21 monoclonal antibodies behave similarly to soluble CD23 in their effect on GCC inasmuch as they: (i) diminish the occurrence of apoptosis; (ii) promote a plasmacytoid appearance in rescued cells; (in) up-regulate expression of the Bcl-2 proto-oncogene. These findings indicate that FDC-derived CD23 exerts its effect on GCC via CD21.     

IL-2和IL-4联合诱导B细胞死亡受体CCR3的表达及其功能研究

目的　研究在IL 2和IL 4作用下 ,趋化性细胞因子受体CCR3在人生发中心 (germinalcenter,GC)B细胞上的表达及其功能特性。方法　采用流式细胞术检测人GCB细胞上CCR3表达和在CCR3配体eotaxin作用下B细胞的凋亡 ,实时定量RT PCR和Northernblot法检测GCB细胞内CCR3mRNA的表达 ,淋巴细胞趋化和黏附试验检测B细胞的趋化和黏附能力。结果　人GCB细胞极低表达趋化性细胞因子受体CCR3,经IL 2和IL 4作用后 ,GCB细胞高表达CCR3,但此时CCR3不能在其配体作用下诱导GCB细胞的趋化和黏附功能 ,而是诱导GCB细胞凋亡。结论　IL 2和IL 4联合诱导人GCB细胞CCR3表达 ,CCR3可能具有死亡受体的功能。     

Follicular dendritic cell networks of primary follicles and germinal centers: phenotype and function

Follicular dendritic cells (FDCs) were identified decades ago by their ability to retain immune complexes and more recent findings indicate that they are a source of B cell attractants and trophic factors. New imaging studies have shown that B cells closely associate with their dendritic processes during migration. Here we will review the properties of these specialized follicular stromal cells and provide an update on the requirements for their maturation into phenotypically distinct cells within germinal center light and dark zones. We will then discuss current understanding of how they help support the B cell immune response.     

Protein tyrosine phosphorylation is mandatory for CD40-mediated rescue of germinal center B cells from apoptosis

Spontaneous apoptosis in germinal center (GC) B cells can be arrested either by engaging cell surface immunoglobulin (Ig) with immobilized ligand or, more effectively, by treatment with soluble monoclonal antibody (mAb) directed against CD40. The present study examines the intracellular signal transduction pathways through which rescue from spontaneous apoptosis is engendered in GC B cells following ligation of surface CD40. Cross-linking the surface CD40 of GC B cells with mAb consistently resulted in enhanced tyrosine phosphorylation on a number of distinct substrates: this process could be blocked, in a dose-dependent fashion, by pre-treating GC B cells with the selective protein tyrosine kinase(s) (PTK) inhibitor, herbimycin A. Moreover, the pattern of phosphorylation on tyrosine observed following treatment with anti-CD40 was remarkably similar to that triggered by polyvalent anti-Ig. By contrast, anti-CD40 failed to stimulate the increase in inositol 1,4,5-trisphosphate and cytosolic free calcium observed in both GC B cells and resting B lymphocytes following ligation of surface Ig. The involvement of the signaling pathways generated in the rescue of GC B cells from apoptosis was studied by using selective inhibitors of PTK and of extracellular and intracellular Ca²⁺. Pre-incubation with the PTK inhibitor herbimycin A (5 μM) abrogated anti-CD40-mediated rescue of GC B cells from apoptosis, while genistein (40 μM) and the tyrphostins AG490 (10 μ M) and AG814 (25 μ M) significantly inhibited this process. Consistent with these results, herbimycin A (5 μM) abolished the expression of the 26 kDa bcl-2 protooncogene product, which confers resistance to apoptosis, normally observed following culture with anti-CD40. The Ca²⁺ chelators BAPTA and EGTA did not significantly affect CD40-promoted rescue. Taken together, these results indicate that CD40 of GC B cells is coupled to functional PTK but not to the phosphatidylinositol signaling pathway and that tyrosine phosphorylation is mandatory for CD40-mediated rescue of GC B cells from apoptosis.     

Re-expression of RAG-1 and RAG-2 genes and evidence for secondary rearrangements in human germinal center B lymphocytes

V(D)J recombination occurs in immature B cells within primary lymphoid organs. However, recent evidence demonstrated that the recombination activating genes RAG-1 and RAG-2 can also be expressed in murine germinal centers (GC) where they can mediate secondary rearrangements. This finding raises a number of interesting questions, the most important of which is what is the physiological role, if any, of secondary immunoglobulin (Ig) gene rearrangements. In the present report, we provide evidence that human GC B cells that have lost surface immunoglobulin re-express RAG-1 and RAG-2, suggesting that they may be able to undergo Ig rearrangement. Furthermore, we describe two mature B cell clones in which secondary rearrangements have possibly occurred, resulting in light chain replacement. The two clones carry both κ and λ light chains productively rearranged, but fail to express the κ chain on the cell surface due to a stop codon acquired by somatic mutation. Interestingly, the analysis of the extent of somatic mutations accumulated by the two light chains might suggest that the λ chain could have been acquired through a secondary rearrangement. Taken together, these data suggest that secondary Ig gene rearrangements leading to replacement may occur in human GC and may contribute to the peripheral B cell repertoire.     

Antigen targeting reveals splenic CD169+ macrophages as promoters of germinal center B‐cell responses

Ag delivery to specific APCs is an attractive approach in developing strategies for vaccination. CD169⁺ macrophages in the marginal zone of the spleen represent a suitable target for delivery of Ag because of their strategic location, which is optimal for the capture of blood‐borne Ag and their close proximity to B cells and T cells in the white pulp. Here we show that Ag targeting to CD169⁺ macrophages in mice resulted in strong, isotype‐switched, high‐affinity Ab production and the preferential induction and long‐term persistence of Ag‐specific GC B cells and follicular Th cells. In agreement with these observations, CD169⁺ macrophages retained intact Ag, induced cognate activation of B cells, and increased expression of costimulatory molecules upon activation. In addition, macrophages were required for the production of cytokines that promote B‐cell responses. Our results identify CD169⁺ macrophages as promoters of high‐affinity humoral immune responses and emphasize the value of CD169 as target for Ag delivery to improve vaccine responses.     

Lymphotoxin α1β2 expression on B cells is required for follicular dendritic cell activation during the germinal center response

CD19‐deficient mice were used as a model to study follicular dendritic cell (FDC) activation because these mice have normal numbers of FDC‐containing primary follicles, but lack the ability to activate FDCs or form GCs. It was hypothesized that CD19 expression is necessary for B‐cell activation and upregulation of membrane lymphotoxin (mLT) expression, which promotes FDC activation. Using VCAM‐1 and FcγRII/III as FDC activation markers, it was determined that the adoptive transfer of CD19⁺ wild‐type B cells into CD19‐deficient hosts rescued GC formation and FDC activation, demonstrating that CD19 expression on B cells is required for FDC activation. In contrast, CD19⁺ donor B cells lacking mLT were unable to induce VCAM‐1 expression on FDCs, furthermore FcγRII/III upregulation was impaired in FDCs stimulated with mLT‐deficient B cells. VCAM‐1 expression on FDCs, but not FcγRII/III, was rescued when CD19‐deficient B cells expressing transgenic mLT were cotransferred into recipient mice with CD19⁺, mLT‐deficient B cells, suggesting that FDC activation requires the CD19‐dependent upregulation of mLT on activated B cells. Collectively, these data demonstrate that activated B cells are responsible for the initiation of FDC activation resulting in a microenvironment supportive of GC development and maintenance.     

Affinity-based selection and the germinal center response

Interactions between B-cell antigen receptors (BCRs) and their ligands have a complexity and variability that is unparalleled within known biology. Each developing B cell undergoes gene rearrangements to generate a BCR encoded by a unique pair of immunoglobulin (Ig) variable region genes, which serves to make the antigen-binding capabilities of primary BCRs incredibly diverse. Further diversification of the BCR repertoire takes place when antigen-activated B cells enter the germinal center (GC) response and undergo somatic hypermutation (SHM) of their Ig variable region genes. To develop optimal antibody responses against foreign antigens, the key B-cell survival and differentiation decisions made in the GC are based primarily on the affinity of the BCR (and therefore subsequent antibodies) for foreign antigen. However, the secondary diversification of BCRs by SHM also carries the risk of generating new self-reactive specificities and thus autoantibody production. Herein, we review the role of antigen affinity/avidity in controlling pivotal events both leading up to and during the GC response. The emergence of self-reactivity during the GC response is also examined, with particular focus on the threat posed by cross-reactive GC B cells that bind both self and foreign antigen.     

The thioredoxin-1 inhibitor Txnip restrains effector T-cell and germinal center B-cell expansion

Thioredoxin-1 (Trx1) is a vital component for cellular redox homeostasis. In T cells, Trx1 donates electrons for the de novo synthesis of deoxyribonucleotides to allow rapid cell proliferation. The Trx-interacting protein (Txnip) binds to the reduced Trx1 and inhibits its activity. However, the role of Txnip in adaptive immunity in vivo is unknown. Here, we show that absence of Txnip increased proliferation of effector T cells and GC B-cell responses in response to lymphocytic choriomeningitis virus and Qβ virus-like particles, respectively, but did not affect development and homeostasis of T and B cells. While downregulation of Txnip and concomitant upregulation of Trx1 is critical for rapid T-cell expansion upon viral infection, re-expression of Txnip and consequently inhibition of Trx1 is important to restrain late T-cell expansion. Importantly, we demonstrated that T-cell receptor (TCR) engagement but not CD28 costimulation is critically required for Txnip downregulation. Thus, this study further uncovers positive and negative control of lymphocyte proliferation by the Trx1 system.