Bruton's tyrosine kinase regulates the activation of gene rearrangements at the lambda light chain locus in precursor B cells in the mouse.

Bruton's tyrosine kinase (Btk) is a nonreceptor tyrosine kinase involved in precursor B (pre-B) cell receptor signaling. Here we demonstrate that Btk-deficient mice have an approximately 50% reduction in the frequency of immunoglobulin (Ig) lambda light chain expression, already at the immature B cell stage in the bone marrow. Conversely, transgenic mice expressing the activated mutant Btk(E41K) showed increased lambda usage. As the kappa/lambda ratio is dependent on (a) the level and kinetics of kappa and lambda locus activation, (b) the life span of pre-B cells, and (c) the extent of receptor editing, we analyzed the role of Btk in these processes. Enforced expression of the Bcl-2 apoptosis inhibitor did not alter the Btk dependence of lambda usage. Crossing 3-83mudelta autoantibody transgenic mice into Btk-deficient mice showed that Btk is not essential for receptor editing. Also, Btk-deficient surface Ig(+) B cells that were generated in vitro in interleukin 7-driven bone marrow cultures manifested reduced lambda usage. An intrinsic defect in lambda locus recombination was further supported by the finding in Btk-deficient mice of reduced lambda usage in the fraction of pre-B cells that express light chains in their cytoplasm. These results implicate Btk in the regulation of the activation of the lambda locus for V(D)J recombination in pre-B cells.

Telomerase regulation and telomere dynamics in germinal centers.

Telomere length maintenance, usually executed by telomerase, is a prerequisite for an extended or infinite division potential. Nevertheless most telomerase positive normal cells exhibit telomere shortening. This study details the telomerase expression and telomere dynamics in purified tonsil B cell subsets during the germinal center (GC) reaction. Significant telomere lengthening was observed as naive B cells matured to centroblasts and when centroblasts matured further to centrocytes, resulting in an increase in telomere length of about 4 kbp determined by Southern blotting. Immunopurified cell populations were also studied by fluorescence in situ hybridization and flow cytometry (flow-FISH) confirming that the GC B cells exhibited lengthened telomeres. These data were further verified in unpurified tonsil cells by combining flow-FISH and immunophenotyping using selected surface markers. Centroblasts expressed high levels of telomerase activity, which was increased in centrocytes, whereas resting naive, activated naive and memory B cells were telomerase activity negative. Expression levels of the catalytic subunit (hTERT) RNA paralleled the telomerase activity levels. The unique telomere elongation in GC B cells permits extensive proliferation during the GC reaction and provides the memory cells with a substantial increase in division potential. Understanding the telomere biology of GC cells is important in defining requirements for telomere elongation in vivo, with implications for the normal immune system as well as for lymphomas, and could provide insights into how the division potential of cells can be manipulated in vitro.

Signals sustaining human immunoglobulin V gene hypermutation in isolated germinal centre B cells.

Affinity maturation of antibody responses depends on somatic hypermutation of the immunoglobulin V genes. Hypermutation is initiated specifically in proliferating B cells in lymphoid germinal centres but the signals driving this process remain unknown. This study identifies signals that promote V gene mutation in human germinal centre (GC) B cells in vitro. Single GC B cells were cultured by limiting dilution to allow detection of mutations arising during proliferation in vitro. Cells were first cultured in the presence of CD32L cell transfectants and CD40 antibody (the 'CD40 system') supplemented with combinations of cytokines capable of supporting similar levels of CD40-dependent GC B-cell growth [interleukin (IL)-10 + IL-1beta + IL-2 and IL-10 + IL-7 + IL-4]. Components of the 'EL4 system' were then added to drive differentiation, providing sufficient immunoglobulin mRNA for analysis. Analysis of VH3 genes from cultured cells by reverse transcription-polymerase chain reaction (RT-PCR)-based single-strand conformation polymorphism indicated that the combination IL-10 + IL-1beta + IL-2 promoted active V gene mutation whereas IL-10 + IL-7 + IL-4 was ineffective. This was confirmed by sequencing which also revealed that the de novo generated mutations were located in framework and complementarity-determining regions and shared characteristics with those arising in vivo. Somatic mutation in the target GC B-cell population may therefore be actively cytokine driven and not simply a consequence of continued proliferation. The experimental approach we describe should facilitate further studies of the mechanisms underlying V gene hypermutation.

Co-ligation of CD44 on naive human tonsillar B cells induces progression towards a germinal center phenotype.

The precise signaling pathways to induce a germinal center (GC) phenotype and somatic mutations in human B cells are presently not understood. Major phenotypical hallmarks of a human GC B cell are up-regulated expression of CD10 and CD95 together with a heterogeneous expression of CD77. Activation of resting human tonsillar B cells using anti-CD40 and anti-IgM antibodies normally only induces up-regulation of CD38 and CD71 but has no effect on the typical GC markers. However, we show here that an additional co-ligation of the glycoprotein CD44 on such tonsillar B cells up-regulated the typical human GC markers CD10, CD38, CD77 and CD95, and down-regulated CD24 and CD39 as well as induced progression towards apoptosis in these cells; all characteristics of GC B cells. These data indicate a functional role of CD44 during activation of human naive B lymphocytes and in the generation of GC B cells.

Terminal differentiation of human germinal center B cells in vitro.

In order to define an in vitro culture system allowing growth of single human germinal center B cells (GC-B), we have studied the proliferation and differentiation of human tonsillar GC-B, and subsets thereof, when cultured together with murine EL-4 thymoma cells in the "EL-4 system." The cells were analyzed and compared to resting tonsillar B cells with respect to phenotypic changes, proliferation, Ig secretion, intracellular Ig levels, and growth abilities under limiting dilution conditions. It was found that GC-B differentiated terminally to Ig-secreting cells with the phenotypic features of plasma cells in a similar manner to tonsillar resting B cells. The GC-B proliferated for 4-5 days, followed by a loss of GC-B phenotype and an increase in intracellular immunoglobulin levels. Over a 10-day culture period a larger proportion of the Ig produced by GC-B was IgG and IgA, as compared to resting B cells, indicating that these cells switched isotype more easily or had already switched in the germinal center prior to the culture period. Analysis of frequencies of Ig-producing cells revealed that 1/3.8 of GC-B and less than 1/10 of the centroblast B cell subpopulation (CB-B) differentiated toward Ig-producing cells when cultured in the EL-4 system whereas 1/1.25 and 1/1.5 of peripheral blood B cells (PBL-B) and resting tonsillar B cells did so, respectively. Taken together, these findings show that tonsillar GC-B differentiate in a similar manner to resting B cells when cultured in the EL-4 system, and we conclude that these conditions allow manipulation of GC-B in single cell cultures in vitro.

Human monoclonal antibodies specific for the tumour associated Thomsen-Friedenreich antigen.

Five hybridomas producing human monoclonal antibodies (MAbs) of IgA and IgM isotypes reacting with the tumour associated TF antigen were generated after in vitro immunisation or antigen specific isolation of normal peripheral blood B cells using asialoglycophorin, a TF containing antigen. All 5 antibodies produced by the hybridomas bound strongly to asialoglycophorin and to synthetic glycoprotein containing the TF-epitope, with preference to the beta form (Galb1-3GalNAc-beta-O-CETE-BSA) as compared to the alpha form (Galbl-3GalNAc-alpha-O-APE-HSA) in ELISA. Flow cytometry analysis revealed binding to carcinoma cell lines of different origin such as breast, colon, pancreas, ovary, bladder, lung and, in addition, to some tumour cell lines of haematopoietic origin. Immunohistochemical analysis of tumour tissues revealed staining patterns typical for mucins, and the antibodies were found to bind to glycoproteins among the MUC-1 positive high m.w. fraction shed from a TF antigen positive ovarian carcinoma cell line.

Telomerase activation in normal B lymphocytes and non-Hodgkin's lymphomas.

Activation of telomerase seems to be a prerequisite for immortalization and is found in permanent cell lines and most malignant tumors. Normal somatic cells are generally telomerase negative, except for bone marrow stem cells. Weak activity is also present in peripheral blood cells. In the present study strong telomerase activity was demonstrated in vivo in normal mature cells of the immune system, as well as in malignant lymphomas. Benign lymph nodes had lower telomerase activity than benign tonsils, which exhibited intermediate to high activity comparable with findings in malignant lymphomas. In benign tonsils the activity seemed to be restricted to germinal center B cells. In benign lymphoid tissues telomerase activity correlated with B-cell numbers and cell proliferation, but this was not observed in the lymphoma group. High-grade lymphomas exhibited higher levels of telomerase compared with low-grade cases. The data showed that in vivo activation of telomerase is a characteristic feature of germinal center B cells. Different signals for activation of telomerase are likely to exist, one of them being immune stimulation. The data suggest that telomerase activity in malignant lymphomas can be explained by an "induction and retention" model, ie, transformation occurs in a normal, mature B cell with reactivated telomerase, which is retained in the neoplastic clone.

Immunoglobulin production induced by CD57+ GC-derived helper T cells in vitro requires addition of exogenous IL-2.

Germinal centers (GC) are well-defined areas in lymphoid organs were B cells proliferate and differentiate in response to T-cell-dependent antigens. The GC comprises B cells, follicular dendritic cells, tangible body macrophages, and a low number of CD4+ T cells. A large portion of these T cells expresses CD57. We have examined the ability of the CD4+ CD57+ GC T cells to become activated and to take part in B cell activation processes. These T cells coexpress CD45RO, CD69, CD28, and upon mitogenic stimulation CD25. The cell population was found neither to contain nor to be able to produce any specific mRNA for IL-2, IL-4, and IFN-gamma upon activation. Levels of mRNA encoding CD40 ligand was also undetectable under similar conditions. Furthermore, in contrast to ordinary CD4+ T cells, this population expressing CD57 was unable to induce B cells to Ig production in the presence of pokeweed mitogen or SEA unless IL-2 was added to the cultures. However, despite their apparent lack of function CD4+ CD57+ GC T cells were found to rescue GC B cells from cell death in vitro to the same extent as CD4+ CD57+ Th cells. The phenotypical and functional differences found between these Th cells and regular Th-cells suggest that they either represent a T cell subset with distinct properties within the GC yet to be determined or that they represent T cells, late in the immune response, having lost most of their original functions and capabilities.

Monocyte-regulated IFN-gamma production in human T cells involves CD2 signaling.

Cooperation between monocytes and T lymphocytes is essential for several aspects of immunologic activation. We have utilized PHA and IL-2-activated human T cells to characterize the role of monocytes in the regulation of T cell-derived IFN-gamma production. The limited IFN-gamma production by isolated T cells in this culture system was increased more than 10-fold when monocytes were added. No influence of monocytes was observed on TNF production or T cell proliferation. Maximal level of IFN-gamma in the cell culture supernatants was obtained when monocytes were added within 12 h after activation of the T cells with IL-2 and PHA. Addition of monocytes 48 h after activation resulted in marginal production of IFN-gamma, suggesting that T cells are sensitive to the monocyte-related signal during a short time period after activation. Cell-to-cell contact between the T cells and accessory cells was found to be necessary for enhanced IFN-gamma production because separation of the cells with a semipermeable membrane abolished the effect. mAb blocking experiments suggested the involvement of the CD2/LFA-3 but not the LFA-1/ICAM-1 pathway in monocyte regulation of T cell synthesis of IFN-gamma. Chinese hamster ovary (CHO) cells transfected with LFA-3 (CHO-LFA-3) and HLA-DR4/LFA-3 (CHO-DR4/LFA-3) strongly enhanced T cell IFN-gamma production, whereas untransfected CHO cells, CHO cells transfected with ICAM-1 (CHO-DR4/ICAM-1), and HLA-DR4 (CHO-DR4) did not support IFN-gamma production. PCR analysis and in situ hybridization demonstrated enhanced IFN-gamma mRNA levels in T cells stimulated in the presence of CHO-DR4/LFA-3 compared with untransfected CHO cells, indicating that the CD2/LFA-3 pathway regulates IFN-gamma production at the mRNA level. CHO-LFA-3 and CHO-DR4/ICAM-1 cells mediated strong adhesion to T cells, whereas untransfected CHO cells and CHO-DR4 cells failed to mediate adhesion. This suggests that the ability of CHO-LFA-3 but not CHO-DR4/ICAM-1 cells to induce IFN-gamma production was attributed to signal transduction rather than cell adhesion only.