B-cell activation stimulated by monoclonal anti-Lyb2.1 antibody is mediated through a receptor distinct from the BSF-1 receptor

CD72-deficient mice reveal nonredundant roles of CD72 in B cell development and activation

CD72, a B cell surface protein of the C-type lectin superfamily, recruits the tyrosine phosphatase SHP-1 through its ITIM motif(s). Using CD72-deficient (CD72-/-) mice, we demonstrate that CD72 is a nonredundant regulator of B cell development. In the bone marrow of CD72-/- mice, there was a reduction in the number of mature recirculating B cells and an accumulation of pre-B cells. In the periphery of CD72-/- mice, there were fewer mature B-2 cells and more B-1 cells. In addition, CD72 is a negative regulator of B cell activation, as CD72-/- B cells were hyperproliferative in response to various stimuli and showed enhanced kinetics in their intracellular Ca2+ response following IgM cross-linking.

Surface immunoglobulin crosslinking activates a tyrosine kinase pathway in B cells that is independent of protein kinase C

It has been found that the principal biochemical pathway activated in B cells stimulated by antigen- or anti-immunoglobulin-mediated crosslinking of surface immunoglobulin is that resulting in hydrolysis of phosphatidylinositol bisphosphate with generation of diacylglycerol and inositol trisphosphate. Recent evidence suggests that surface immunoglobulin-mediated B-cell activation can proceed without detectable increases in the concentration of either diacylglycerol or intracellular Ca2+ concentration, implicating involvement of other non-protein-kinase-C/Ca2(+)-dependent signal-transduction pathways. Therefore, we sought evidence for activation of a signaling pathway that is associated with growth regulation in other cell types--i.e., the protein-tyrosine kinases. We now show that crosslinking of membrane immunoglobulin by mitogenic antibodies leads to rapid tyrosine phosphorylation of several cellular substrates, consistent with the induction of a tyrosine kinase activity. This increase in tyrosine phosphorylation is weakly (if at all) stimulated by other B-cell mitogens, including phorbol esters and ionophores, and does not require the presence of detectable protein kinase C. Furthermore, inhibition of anti-immunoglobulin-stimulated phosphatidylinositol bisphosphate hydrolysis does not inhibit activation of this tyrosine kinase-dependent pathway. These findings suggest that occupancy of the membrane immunoglobulin receptor may induce multiple pathways of activation.

Weak bases increase surface IgM expression in 70Z/3 B lymphoid cell line without increasing kappa gene expression

A murine B lymphoid cell line, 70Z/3, has proven to be a useful model to study the developmental transition from membrane immunoglobulin (mIgM)-negative to mIgM-positive B cells. 70Z/3 cells have normal intracellular levels of mu heavy chain but kappa mRNA is transcribed at a very low rate. Because both kappa and mu chains are required for IgM to localize on the external membrane the cells remain essentially mIgM negative. A number of biologic agents can stimulate kappa mRNA transcription leading to increased surface IgM expression. Pharmacologic agents which cause cytoplasmic alkalinization have also been shown to increase the level of surface IgM expression when assessed by FITC-labeled anti-IgM antibodies. This increase has been used to argue that cytoplasmic alkalinization is sufficient to stimulate 70Z/3 differentiation but previous studies did not measure kappa mRNA levels or rate of synthesis. In this study we set out to determine whether the increased FITC staining that follows cytoplasmic alkalinization results from increased surface IgM expression and whether that increase results from activation of kappa mRNA transcription. When cells were treated with methylamine, NH4Cl, or monensin there was transient cytoplasmic alkalinization. The levels of surface IgM expression were measured by flow cytometry of cells stained with FITC-labeled anti-mouse kappa and mu. Using this criterion, a 24-hr treatment with either weak bases or monensin increased the level of surface IgM. The increase in fluorescence was not the result of nonspecific binding or uptake by the cell because there was no increase in fluorescence when methylamine-treated cells were stained with FITC-labeled antibody directed against an antigen not found on these cells. Iodination of surface proteins confirmed that the increase in fluorescence was the result of increased levels of IgM protein on the cell surface. However, exposure of the cells to weak bases or monensin caused no increase in either the steady-state level of kappa light chain mRNA, or in the level of kappa protein. We conclude that the transient alkalinization is not sufficient to induce differentiation of the 70Z/3 cells.