Receptor revision plays no major role in shaping the receptor repertoire of human memory B cells after the onset of somatic hypermutation.

In order to determine whether V gene replacement accompanies somatic hypermutation in the germinal center (GC) reaction in the human, we analyzed V(kappa)J(kappa) and V(lambda)J(lambda) joints and the kappa-deleting element in single lambda(+) naive and post GC B cells for rearrangements at the kappa and lambda loci. Among 265 lambda(+) post GC B cells, not a single unequivocal and only two potential examples of a cell that switched to lambda light chain expression after accumulation of (unfavorable) mutations in its productive V(kappa) rearrangement were observed. Taking the PCR efficiency into account, the frequency of such cells is likely below 3 %. In addition, heavy and light chain gene rearrangements were amplified and sequenced from the oligoclonal population of IgD-only peripheral blood post GC B cells which display extensive intraclonal sequence diversity. Among 61 IgD-only B cells belonging to 15 clones with intraclonal diversity, no combination of V gene rearrangements indicating receptor revision during clonal expansion was observed. Moreover, among 124 and 49 V(H) genes amplified from IgD-only and class-switched B cells, respectively, not a single example of V(H) revision through V(H) hybrid generation was detected. These results suggest that in the human GC reaction V gene replacement either does not usually accompany somatic hypermutation or is mostly counterselected.     

Single-cell PCR analysis of T helper cells in human lymph node germinal centers

The T helper cell population of human lymph node germinal centers (GCs) was analyzed for clonality and signs of antigen selection. Frozen sections of lymph node biopsies taken from three different individuals were used to micromanipulate single T cells from one particular GC for each of the specimens. T cell receptor (TCR) beta gene rearrangements were amplified from these single cells and directly sequenced. Although only unique rearrangements were amplified from T cells of GC2 and GC3, 11 of 28 potentially functional rearrangements amplified from GC1 originated from four different clones. In all three GCs, TCR gene rearrangements neither showed obvious biases in gene segment usage nor similarities in complementarity determining region 3 amino acid sequence. Thus, it appears that T lymphocytes in human GCs usually represent a diverse population of cells. Sequence analysis of V region genes did not provide evidence that in the human the process of somatic hypermutation acts on the TCRbeta loci. For one of the GCs (GC3), immunoglobulin heavy chain (IgH) gene rearrangements were amplified and sequenced from single micromanipulated GC B cells. The detection of clonal expansions accounting for more than half of the sampled B cells in addition to ongoing somatic hypermutation of Ig V region genes suggested that GC3 was a fully developed GC.     

Subtle differences in antibody responses and hypermutation of λ light chains in mice with a disrupted χ constant region

Analysis of λ light chain use in normal mice is made difficult by the dominant x light chain repertoire. We produced mice rendered deficient in x light chain expression by gene targeting and focused on questions concerned with the generation of λ light chain diversity. Whilst these mice compensate the x deficiency with increased λ titers, and their Ig level is therefore not significantly reduced, they show major differences in immunization titers, germinal center (GC) development and somatic hypermutation. After immunization, using antigens that elicit a restricted IgL response in normal mice, we obtained in the x^?/? mice elevated primary antibody titers but a subsequent lack in titer increase after repeated antigen challenge. Analysis of the Peyer's patches (PP) revealed a dramatically reduced cell content with rather small but highly active GC. Flow cytometric analysis showed different cell populations in the PP with enriched peanut agglutinin (PNA)^hi/CD45R(B220)⁺ B cells, implying that the apparent compensation for the lack of x light chain expression involves the GC microenvironment in cell selection, the initiation of hypermutation and high affinity expansion. The three Vλ genes, V1, V2 and Vx, are mutated in the GC B cells, but show no junctional diversity. In contrast, a reduced rate of Vλ hypermutation is found in the hybridoma antibodies, which appears to reflect a selection bias rather than structural constraints. However, mechanisms of somatic mutation and specificity selection can operate with equal efficiency on the few Vλ genes.     

Dendritic cells expand Epstein Barr virus specific CD8+ T cell responses more efficiently than EBV transformed B cells

Adoptive transfer of Epstein Barr virus (EBV) specific cytotoxic T lymphocytes (CTLs) has been successfully applied in the treatment of EBV associated post-transplant lymphoproliferative disease (PTLD). In most studies EBV transformed B cells (LCLs) have been used for the induction of EBV specific T cell lines. Application of this approach to other EBV associated tumors is difficult, because LCLs focus T cell expansion toward immunodominant EBV antigens that are not expressed in EBV associated Hodgkin's lymphoma and nasopharyngeal carcinoma. Therefore, we compared dendritic cells (DCs) with LCLs for CD8+ T cell stimulation against dominant and subdominant EBV antigens. DCs expanded tenfold more EBNA3A and LMP2 specific CD8+ T cells than LCL and also stimulated EBV specific CTL from PTLD patients. Both, DCs and LCLs stimulations led to the expansion of high affinity T cells, capable to target EBV transformed B cells. While LCLs and DCs expressed MHC class I and II products at similar levels, DCs showed a higher expression of costimulatory and adhesion molecules. This resulted in more efficient T cell conjugate formation with DCs than with LCLs. We propose the use of DCs for stimulation of EBV specific T cells in active or passive immunotherapy of EBV associated malignancies.     

Molecular characterization of post‐transplant lymphoproliferative disorders of donor origin occurring in liver transplant recipients

Post‐transplant lymphoproliferative disorders (PTLDs) represent a frequent complication of solid organ transplantation. Although most PTLDs arise from recipient lymphoid cells, a considerable fraction of cases may arise from donor B‐cells. In an attempt to clarify the histogenesis and pathogenesis of PTLDs derived from donor B‐cells, monoclonal PTLDs occurring in liver transplant recipients were chosen as a model to compare donor (D‐PTLDs) versus recipient PTLDs (R‐PTLDs). The tumour panel included nine D‐PTLDs and six R‐PTLDs. D‐PTLDs were early‐onset, EBV‐infected lymphoproliferations classified as polymorphic PTLD (P‐PTLD; n = 7) or diffuse large B‐cell lymphoma (DLBCL; n = 2) with tumour localization confined to the hepatic hilum. All R‐PTLDs were late‐onset DLBCLs and showed extrahepatic localization. A BCL‐6^?/MUM1⁺/CD138^+/? phenotype, consistent with a post‐germinal centre (GC) stage of pre‐terminal B‐cell differentiation, was observed in all D‐PTLDs and in 2/6 R‐PTLDs, whereas a BCL6⁺/MUM1^?/CD138^? profile, reminiscent of GC B‐cells, was detected in 4/6 R‐PTLDs. The presence of somatic IGHV hypermutation was observed in 6/9 D‐PTLDs and in 4/6 R‐PTLDs, suggesting derivation from antigen‐experienced B‐cells. IGHV4‐39 was the IGHV gene most frequently encountered, being rearranged in 3/9 D‐PTLDs. Among IGHV‐mutated PTLDs, a mutational profile suggesting antigen stimulation and/or selection was observed in 4/6 D‐s and in 2/4 R‐PTLDs. The presence of ongoing IGHV mutations was detected in 2/4 D‐PTLDs. Aberrant SHM was detected in 10/15 (66.7%) PTLDs, including 6/9 D‐PTLDs and 4/6 R‐PTLDs. Our findings suggest that (i) D‐PTLDs show a clinical presentation distinct from R‐PTLDs; (ii) immunophenotypic and genetic features of D‐PTLDs are consistent with mature, GC‐experienced B‐cells; (iii) transformed donor‐derived B‐cells may experience antigen‐driven stimulation and selection, and may acquire genetic lesions during neoplastic expansion in the recipient environment; and (iv) EBV infection and expression of viral oncoproteins may be relevant in the pathogenesis of D‐PTLDs. Copyright © 2009 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Human splenic marginal zone B cells lack expression of activation-induced cytidine deaminase

It has been speculated that somatic hypermutation of rearranged immunoglobulin variable (V) region genes does not only take place in the germinal center (GC) microenvironment, but also in the marginal zone (MZ) of the spleen, and that human peripheral blood IgM-positive B cells with somatically mutated V region genes may derive from mutating MZ B cells. As somatic hypermutation is strictly dependent on the enzyme activation-induced cytidine deaminase (AID), we used an AID-specific monoclonal antibody that is suitable for immunohistochemical staining to analyze human splenic MZ cells for AID expression. Analysis of tissue sections from 29 spleens revealed only very rare MZ cells (approx. 0.05%) showing AID staining, whereas in 25 of the spleen samples strong AID staining of GC B cells was observed. Thus, there are virtually no AID-expressing MZ B cells, indicating that somatic hypermutation does not take place at a significant level in the MZ. Consequently, it appears unlikely that the somatically mutated IgM B cells are generated in the splenic MZ. Moreover, the lack of AID-positive MZ B cells questions the recent speculation that B cell chronic lymphocytic leukemias with mutated V genes are derived from mutating MZ B cells.     

Fas receptor expression in germinal-center B cells is essential for T and B lymphocyte homeostasis

Fas is highly expressed in activated and germinal center (GC) B cells but can potentially be inactivated by misguided somatic hypermutation. We employed conditional Fas-deficient mice to investigate the physiological functions of Fas in various B cell subsets. B cell-specific Fas-deficient mice developed fatal lymphoproliferation due to activation of B cells and T cells. Ablation of Fas specifically in GC B cells reproduced the phenotype, indicating that the lymphoproliferation initiates in the GC environment. B cell-specific Fas-deficient mice also showed an accumulation of IgG1(+) memory B cells expressing high amounts of CD80 and the expansion of CD28-expressing CD4(+) Th cells. Blocking T cell-B cell interaction and GC formation completely prevented the fatal lymphoproliferation. Thus, Fas-mediated selection of GC B cells and the resulting memory B cell compartment is essential for maintaining the homeostasis of both T and B lymphocytes.     

Comparative analysis of the expression of the Epstein-Barr virus (EBV) anti-apoptotic gene BHRF1 in nasopharyngeal carcinoma and EBV-related lymphoid diseases

Epstein-Barr virus (EBV) has been identified in a wide range of neoplastic and non-neoplastic disorders. The EBV open reading frame BHRF1 encodes a protein with partial sequence and functional homology to the anti-apoptotic onco-protein Bcl-2 and may therefore have a role in the proliferation of EBV positive cells. We have developed a rat monoclonal antibody against pBHRF1, which can detect BHRF1 in paraffin sections. While a number of mutant versions of BHRF1 were recognised, the monoclonal did not detect the BHRF1 homologue encoded by Herpesvirus papio or two mutants with deletions in the BH2 region. This novel rat monoclonal antibody (6A9) was used to examine tissue sections from 39 cases of non-keratinising undifferentiated nasopharyngeal carcinoma (NPC), 6 cases of metastatic NPC, 7 cases of EBV-positive NPC with squamous differentiation from Chinese patients, 15 cases of EBV-positive post-transplant lymphoproliferative disorder (PTLD), 6 EBV-containing lymphoblastoid cell lines, and 2 cases of oral hairy leukoplakia (OHL). In 11 cases of undifferentiated NPC, RT-PCR data were available for comparison with the immunohistochemistry. Both cases of OHL and two cases of LCL were positive for BHRF1 but none of the PTLD showed positive staining. All cases of undifferentiated NPC were positive for Bcl-2 but only one BHRF1 positive cell was identified in 1 of 39 cases of primary undifferentiated NPC. The 6A9 antibody produced less background staining and no nuclear positivity compared with the commercially available mouse monoclonal 5B11. It is concluded that BHRF1 can not be detected by immunohistochemistry in NPC and therefore it appears not to play a significant anti-apoptotic role in the progression of this EBV-associated tumour. The 6A9 monoclonal appears to be superior to 5B11 for the detection of pBHRF1 in tissue sections.     

Cerebrospinal fluid T cell clones from patients with multiple sclerosis: recognition of idiotopes on monoclonal IgG secreted by autologous cerebrospinal fluid B cells

Due to somatic recombination and hypermutation, Ig variable heavy (V(H)) and light (V(L)) regions contain unique immunogenic determinants, idiotopes (Id), which can stimulate T cells. To address the relevance of this in a human disease, monoclonal IgG (mAb)-secreting B cell clones were established from the cerebrospinal fluid (CSF) of two patients with multiple sclerosis (MS). HLA-DR-restricted CD4(+) T cell lines and clones from CSF of both patients specifically recognized autologous CSF mAb. The CSF T cell clones produced IFN-gamma; some also produced TNF-alpha, IL-10 and IL-5. V(H) and V(L) on the monoclonal IgG derived from CSF B cells expressed amino acid replacements due to somatic mutations. A T cell epitope was mapped to a V(H) framework region, where an amino acid replacement was critical for the T cell recognition. The finding of Id-specific T cells and Id-bearing B cells in the CSF indicates that they coexist within the diseased organ, and provide a basis for the study of Id-driven T-B cell collaboration in a human autoimmune disease.     

Cellular origin of human B-cell neoplasms and Hodgkin's disease based on analysis of somatic hypermutations in the immunoglobulin variable region genes

In response to antigen stimulation, B cells undergo a germinal center(GC) reaction such as somatic hypermutations of the immunoglobulin variable region genes, which results in the production and selection of antigen-specific antibodies with increased affinity. Therefore, somatic hypermutations are considered to be a hallmark of GC B cells and their descendants. Pre-GC B cells(precursor B cells, immature B cells, naive B cells and CD5+ B cells) carry no somatic hypermutations, whereas GC B cells and post-GC B cells(memory B cells and plasma cells) express somatic hypermutations. This phenomenon is useful in identifying the cellular origin of various B-cell neoplasms. Precursor B-lymphoblastic leukemia/lymphoma, mantle cell lymphoma, and most B-CLL originate from pre-GC B cells, and follicular lymphoma, Burkitt's lymphoma, marginal zone B-cell lymphoma, diffuse large B-cell lymphoma and myeloma from GC B cells or post-GC B cells. Nodular lymphocyte-predominant Hodgkin's disease and most classical types of Hodgkin's disease are derived from GC B cells. Most human-B cell neoplasms including Hodgkin's disease are derived from GC B cells or their descendants. Molecular processes that modify the DNA of GC B cells, such as somatic hypermutation, class switching and receptor editing occur in the environment of the GCs, and increase the risk of malignant transformation.     

Immunization with immune complex alters the repertoire of antigen-reactive B cells in the germinal centers

The differentiation of memory B cells in germinal centers (GC) is selectively enhanced upon administration of antigen-antibody complexes. To characterize the repertoire of this response, we examined the rearranged immunoglobulin heavy chain variable (V_H) genes from mouse splenic GC after a single immunization with either antigen, nitrophenyl (NP) hapten coupled to keyhole limpet hemocyanin, or with a preformed complex of antigen with a monoclonal anti-NP antibody of γ1 isotype. Among antigen-immunized mice, NP-reactive GC B cell populations in the antigen-induced GC consisted mostly of cells expressing the canonical V186.2 gene which contained, on average, 0.8 point mutations/V_H gene by day 8 after immunization. These results are indicative of the beginning of somatic hypermutation and consistent with previously published analyses of NP antigen-driven GC. In contrast, the NP-specific B cells in GC that were elicited by administration of immune complex represented a heterogeneous cell population expressing nine different germ-line segments of the V186.2/V3 (J558) gene family, i.e. V23, V24.8, C1H4, V3, CH10, V165.1, V102, V671.5 and V186.2. Moreover, the average frequency of mutations in these genes was 1.7, reaching up to 4 mutations/V_H in some GC. Administration of the antigen NP in complex with specific antibody apparently alters the process of interclonal competition in the GC and results in loss of dominance by V186.2⁺ cells and nearly stochastic representation of diverse clono-types. These results suggest an important feedback regulation of the B cell repertoire by antibody and indicate a role for immune complexes in the activation of somatic hypermutation.     

p52 Activation in monomorphic B-cell posttransplant lymphoproliferative disorder/diffuse large B-cell lymphoma without BAFF-R expression

Posttransplantation lymphoproliferative disorders (PTLD) are associated with Epstein-Barr virus (EBV) and activate the NF-κB pathway. B-cell activating factor (BAFF) modulates cell growth and survival in non-Hodgkin's lymphomas. However, there are few studies of EBV, BAFF/BAFF-R signaling, and NF-κB1 and NF-κB2 pathway activation in PTLD. Diffuse large B-cell lymphomas (DLBCL) in two different clinical contexts, immunocompetent patients (DLBCL/IC; n = 30) or posttransplantation solid-organ recipients (DLBCL/PTLD; n = 21), were characterized histogenically as germinal center (GC) or non-germinal center (NGC). Expression of BAFF, BAFF-R, and NF-κB proteins p50 and p52 and the presence or absence of EBV were compared in these clinical contexts. Regardless of the GC or NGC pattern of DLBCL, BAFF-R was expressed in 37% of DLBCL/IC but in only 4.8% of DLBCL/PTLD. p52 was expressed in DLBCL/PTLD/NGC (12 of 19 cases) as compared with DLBCL/IC/NGC (0 of 18 cases). This pattern might be related to the presence of EBV and latent membrane protein 1 because p52 expression was observed primarily in EBV-positive DLBCL/PTLD cases expressing latent membrane protein 1. Thus, the activation profile or NGC pattern of DLBCL/PTLD was not associated with BAFF/BAFF-R expression, whereas nuclear p52 related to NF-κB2 pathway activation might be linked to EBV.     

The VH repertoire and clonal diversification of B cells in inflammatory myopathies

The contribution of antigen‐driven B‐cell adaptive immune responses within the inflamed muscle of inflammatory myopathies (IMs) is largely unknown. In this study, we investigated the immunoglobulin V_H gene repertoire, somatic hypermutation, clonal diversification, and selection of infiltrating B cells in muscle biopsies from IM patients (dermatomyositis and polymyositis), to determine whether B cells and/or plasma cells contribute to the associated pathologies of these diseases. The data reveal that Ig V_H gene repertoires of muscle‐infiltrating B cells deviate from the normal V_H gene repertoire in individual patients, and differ between different types of IMs. Analysis of somatic mutations revealed clonal diversification of muscle‐infiltrating B cells and evidence for a chronic B‐cell response within the inflamed muscle. We conclude that muscle‐infiltrating B cells undergo selection, somatic hypermutation and clonal diversification in situ during antigen‐driven immune responses in patients with IMs, providing insight into the contribution of B cells to the pathological mechanisms of these disorders.     

B lymphocytes and Epstein-Barr virus: the lesson of post-transplant lymphoproliferative disorders

Epstein-Barr virus (EBV) is a ubiquitous human gamma-herpes virus that establishes a life-long asymptomatic infection in immunocompetent hosts by colonizing memory B lymphocytes and hijacking cellular signaling pathways that regulate antigen-dependent B-cell activation and differentiation. In patients with solid organ or hematopoietic stem cell transplantation, the defect in EBV-specific immune responses may allow the outgrowth of EBV-carrying B lymphocytes that may give rise to a spectrum of different clinico-pathologic entities encompassed by the term post-transplantation lymphoproliferative disorders (PTLD). EBV-driven immortalization of B-cells is mediated by the cooperative activity of viral proteins that derange critical cellular pathways controlling growth and/or survival of B lymphocytes. Full transformation of infected B-cells is achieved by the contribution of poorly defined additional co-factors, including microenvironmental stimuli, genetic and epigenetic alterations. The quantification of circulating EBV DNA and EBV-specific T cells are valuable tools in the clinical monitoring of EBV-associated PTLD. The recent advances in elucidation of the mechanisms underlying EBV-induced growth transformation will be instrumental in guiding the design of novel approaches for the treatment of these often life-threatening lymphoproliferative disorders.     

Langerhans cells promote early germinal center formation in response to Leishmania‐derived cutaneous antigens

Efficient formation of early GCs depends on the close interaction between GC B cells and antigen‐primed CD4⁺ follicular helper T cells (T_FH). A tight and stable formation of T_FH/B cell conjugates is required for cytokine‐driven immunoglobulin class switching and somatic hypermutation of GC B cells. Recently, it has been shown that the formation of T_FH/B cell conjugates is crucial for B‐cell differentiation and class switch following infection with Leishmania major parasites. However, the subtype of DCs responsible for T_FH‐cell priming against dermal antigens is thus far unknown. Utilizing a transgenic C57BL/6 mouse model designed to trigger the ablation of Langerin⁺ DC subsets in vivo, we show that the functionality of T_FH/B cell conjugates is disturbed after depletion of Langerhans cells (LCs): LC‐depleted mice show a reduction in somatic hypermutation in B cells isolated from T_FH/B cell conjugates and markedly reduced GC reactions within skin‐draining lymph nodes. In conclusion, this study reveals an indispensable role for LCs in promoting GC B‐cell differentiation following cutaneous infection with Leishmania major parasites. We propose that LCs are key regulators of GC formation and therefore have broader implications for the development of allergies and autoimmunity as well as for future vaccination strategies.     

Ig gene diversification and selection in follicular lymphoma, diffuse large B cell lymphoma and primary central nervous system lymphoma revealed by lineage tree and mutation analyses

Follicular lymphoma (FL), diffuse large B cell lymphoma (DLBCL) and primary central nervous system lymphoma are B cell malignancies. FL and DLBCL have a germinal center origin. We have applied mutational analyses and a novel algorithm for quantifying shape properties of mutational lineage trees to investigate the nature of the diversification, somatic hypermutation and selection processes that affect B cell clones in these malignancies and reveal whether they differ from normal responses. Lineage tree analysis demonstrated higher diversification and mutations per cell in the lymphoma clones. This was caused solely by the longer diversification times of the malignant clones, as their recent diversification processes were similar to those of normal responses, implying similar mutation frequencies. Since previous analyses of antigen-driven selection were shown to yield false positives, we performed a corrected analysis of replacement and silent mutation patterns, which revealed selection against replacement mutations in the framework regions, responsible for the structural integrity of the B cell receptor, but not for positive selection for replacements in the complementary determining regions. Most replacements, however, were neutral or conservative, suggesting that if at all selection operates in these malignancies it is for structural B cell receptor integrity but not for antigen binding.     

Determining virological, serological and immunological parameters of EBV infection in the development of PTLD

Post-transplant lymphoproliferative disease (PTLD) in Epstein-Barr virus (EBV) seronegative solid organ transplant recipients remains a significant problem, particularly in the first year post-transplant. Immune monitoring of a cohort of high-risk patients indicated that four EBV seronegative transplant recipients developed early-onset PTLD prior to evidence of an EBV humoral response. EBV status has been classically defined serologically, however these patients demonstrated multiple parameters of EBV infection, including the generation of EBV-specific CTL, outgrowth of spontaneous lymphoblastoid cell lines, and elevated EBV DNA levels, despite the absence of a classic EBV antibody response. As EBV serology is influenced by both immunosuppression and cytomegalovirus immunoglobulin treatment, both the EBV-specific CTL response and elevated EBV levels are more reliable indicators of EBV infection post-transplant.     

Does AID aid AIDS?

During AIDS, the acquisition of mutations in the HIV-1 gp120 envelope glycoprotein leads to the switch from primary R5 (CCR5-using) to highly cytopathic X4 (CXCR4-using) HIV-1 variants. Based on the already known sequence homology between IgV genes and the gp120-coding region of the env gene, as well as on somatic hypermutation of multiple proto-oncogenes, the somatic hypermutation hypothesis for the mechanism of R5-X4 HIV-1 switching is proposed as follows. This switch takes place in the germinal center (GC) B cells due to the aberrant somatic hypermutation of the gp120-coding part of the HIV-1 env gene. Activation-induced cytidine deaminase (AID) is required for this process. Activation through IL4R and CD40 is required both for infection of GC B cells with HIV-1 and for induction of AID expression in the same cells. B cell infection with R5 HIV-1 variants is the limiting stage in the process of the viral phenotypic switch during the asymptomatic period of AIDS. Overall up-regulation of CXCR4 coreceptor on the GC B cells and the CD4(+) T cells surrounding the GC provides the predominant replication and acquisition of the newly formed X4 HIV-1 variants.