Ernst Lindhout

Triple check for antigen specificity of B cells during germinal centre reactions

Somatic hypermutation of the immunoglobulin variable genes during germinal reactions might permit the expansion of B-cell clones with unwanted (e.g. autoreactive) specificity. Here, Ernst Lindhout and colleagues propose three antigen-specific checkpoints that ensure the appropriate antigen specificity of activated B cells is maintained by regulating the activation, selection and further differentiation of B cells.

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 gcrminal centre (GC) B lymphocytes from apoptosis. However, formal proof for this hypothesis has not as yet been presented. In the present study F DC and GC B cells were isolated from humati tonsils and cultured. When brought into culture FDC and B cells rapidly formed spherical clusters. T cells were not observed inside these clusters. At dilTerent time points cultures of FDC and B cells were siipravitally stained with Hoechst 33258 or aeridine orange and examined by direct observation tising 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‐lα) or CD49d (VLA‐4α). resulting in an apoptotic appearance of virtually al B lymphocytes. The present data demonstrate that a physical interaetion between FDC and germinal centre B lymphocytes is able to rescue the latter from apoptotic cell death.

Follicular dendritic cells and apoptosis: Life and death in the germinal centre

SummaryThe germinal centre forms a specialized microenvironment thought to play a key role in the induction of antibody synthesis, affinity maturation of B cells and memory B cell formation. Clonal-expanded follicular B lymphocytes with mutated antigen receptors (centrocytes) have to be selected on the basis of their capacity to compete for binding to antigen held in limited amounts on the follicular dendritic cells. In this way, only high-affinity B cells are selected. Binding to a follicular dendritic cell is an unconditional prerequisite for centrocytes to survive. Cells that do not succeed in binding to a follicular dendritic cell die rapidly by apoptosis. Apoptosis is a common form of cell death characterized by the activation of an endonuclease culminating in nuclear destruction. The pathway by which apoptosis is triggered varies from cell type to cell type. However, for germinal centre B cells this process is still poorly understood.

An efficient procedure for the generation of human monoclonal antibodies based on activation of human B lymphocytes by a murine thymoma cell line

A new, efficient procedure for the generation of human monoclonal antibodies has been developed. The procedure is based on the activation of human B cells in microwells by murine thymoma EL4B5 cells. This mode of B cell stimulation leads to proliferation of at least one per eight of human B cells and to a high rate of antibody production. Subsequently, supernatants of the microwells are screened by ELISA for the presence of antibody of the desired specificity and B cells from selected wells are hybridized by electroporation. To optimize the procedure, the kinetics of the B cell expansion induced by EL4B5 cells were analysed. Counting and phenotyping of cultured cells at different time points indicated that the peak of B cell expansion occurred at day 5 for tonsil B cells (16-fold increase) and at day 7 for peripheral blood B cells (20-fold increase). The B cells did not merely proliferate but also differentiated, as indicated by loss of CD20 expression and increase of CD38 expression. At the peak of B cell expansion, B cells could be hybridized efficiently with myeloma cells. The majority of the resultant hybridomas secreted human immunoglobulin. The efficiency of the procedure is exemplified by the generation of hybridomas secreting human IgG against Haemophilus influenzae from limited numbers of either human tonsil B lymphocytes or peripheral blood B lymphocytes.

Improvement of EBV transformation and cloning efficiency of human B cells using culture supernatants from lymphoblastoid cell lines.

Exposure of human B cells to Epstein-Barr virus (EBV) usually results in low frequencies of transformed cells. The transformed cells can be cloned poorly by limiting dilution, even when feeder cells are used. In recent years it has become clear that growth and antibody production of EBV-transformed cells are influenced by auto- and paracrine growth factors. Therefore, supernatants from the lymphoblastoid B cell lines JY and Raji were used as a source of growth factors to investigate their effect during EBV transformation of human B cells and consequently on cloning by limiting dilution of these transformed cells. Initial experiments to clone three established EBV-transformed B cell lines showed a strong increase in outgrowth of the number of cells in the presence of the supernatant (range: 1 per 2-8 of the originally plated cells) as compared to cells cultured without the supernatant (range: 1 per 17-100 of the originally plated cells). Transformation efficiencies of freshly isolated tonsil B cells were not influenced by the supernatant and were generally less than 1%. In contrast, transformation efficiency was increased up to 9.4% if B cells were both transformed and cultured in the presence of the supernatant. Cloning efficiencies increased if the cells used were transformed in the presence of the supernatant. Best results were seen when the supernatant was present during transformation and cloning of the cells. The presence of the supernatant during transformation and/or cloning of the B cells dramatically enhanced the number of B cells secreting IgG. Cloning of two established tonsil B cell lines resulted in a large number of B cell clones.(ABSTRACT TRUNCATED AT 250 WORDS)