A 30-kDa protein is disulfide linked to IgM on normal and neoplastic murine B lymphocytes

The composition of the intracellular domains of the B cell antigen receptor complex studied from the cytoplasmic side of the membrane

Immunoglobulins of the classes M and D function as antigen receptors on B lymphocytes. They are linked to other proteins to form B cell antigen receptor (BCR) complexes which transduce the signal triggered by the binding of antigen. In order to study the components that interact with BCR complexes in the cell it is essential that they are accessible to biochemical studies. Therefore, we have developed a simple and rapid method that allows the purification and labelling of B lymphocyte plasma membranes. For this, B cells are attached to polyacrylamide beads. Upon disruption of the cells, bead-bound membranes are obtained which expose the cytoplasmic side into the medium. The membrane proteins can then be radioiodinated and eluted with detergents. The combination of the improved methods for the preparation of bead-attached membrane patches and radiolabelling of the proteins has allowed for the first time an investigation into the cytoplasmic side of the BCR complex. All the subunits that had been previously described could be detected in 2D autoradiographs. Furthermore, it could be shown that the protein Ig-beta, which is part of an Ig-associated heterodimer, is predominantly labelled at the extracellular domain. The second component, Ig-alpha, is labelled to a higher degree at its intracellular domain. In addition, further proteins could be detected exclusively at the cytoplasmic side of the membrane. Results from 2D autoradiographs show that they may form heterodimers. These proteins are candidates for the interaction of BCR complexes with further members of the signalling cascade, such as protein tyrosine kinases and/or G proteins.

Changes in the expression of Ig-associated proteins on B lymphocytes activated by anti-IgM antibodies

Binding of antigen to receptor complexes on B cells elicits a cascade of intracellular signalling events leading to proliferation and, together with T-cell help, Ig secretion. Components of the antigen receptor (AgR) complex have been demonstrated to be either covalently bound or associated with surface Ig (sIg) molecules. The function of these proteins is still unknown. In order to address this question, we have stimulated B cells with anti-mu antibodies and have studied possible changes in the expression of AgR complexes. After anti-mu stimulation, the IgM molecules disappeared rapidly from the cell surface together with the covalently bound proteins. The IgM molecules were internalized and probably degraded. The IgM-associated heterodimer Ig-alpha/Ig-beta was also removed from the cells, leaving the IgD-associated heterodimer unaffected. Two proteins showed an enhanced association with sIg after 15 min and then were gradually removed from the cell surface. Two other proteins became increasingly attached to sIg. This association remained stable for the rest of the culture period (up to 4 h). Further studies are underway to characterize these proteins more closely and to examine possible interactions with downstream members of the signalling cascade.

Developmentally regulated association of a 56-kD member of the surface immunoglobulin M receptor complex

Immature and mature B cells differ in the signals generated and transduced through their antigen receptor, surface immunoglobulin M (sIgM). Whereas signals generated through sIgM on mature B cells initiate a program leading to the positive activation of these cells, signaling through this receptor at the immature stage of development leads to a state of induced unresponsiveness or tolerance. Our previous studies have described developmental differences in sIgM transmembrane signaling that are independent of ligand-receptor affinity. In an attempt to understand the molecular basis for signaling differences between immature and mature B cells, we have analyzed the sIgM receptor complex in neonatal and adult mouse splenic B cells. While previously described components of this complex do not exhibit marked developmentally regulated differences in their association with sIgM, we have identified a 56-kD protein that associates with sIgM in mature (antigen-responsive), but not immature (tolerance-sensitive) B cells. This protein (p56) associates with sIgM as a homodimer, is constitutively phosphorylated on tyrosine, and is coimmunoprecipitated with IgM but not IgD. The observed inability to iodinate p56 suggests it is an intracellular component of the receptor complex. Based upon its migration in one- and two-dimensional gel electrophoresis we show, however, that p56 is distinct from the blk, lyn, or fyn src family kinases that have been shown to be associated with sIgM in mature B cells. The developmentally regulated participation of p56 in the B cell antigen receptor complex suggests a role in the differential signaling mediated via sIgM on immature and mature B cells.

G protein mediated signal transduction: membrane immunoglobulin associated phosphoproteins identified in octyl-beta-glucoside lysates of normal B cells

Several recent studies have shown that the antigen receptors (mIgM and mIgD) on normal B cell surfaces are part of larger multimolecular complexes, as each is noncovalently coupled to at least two other proteins whose phosphorylation is inducible upon G protein activation. However, B cell receptor complexes appear to be extremely labile, so that extraction of membrane immunoglobulin (mIg) from cell lysates in physical association with noncovalently coupled proteins has been shown to be highly dependent on the choice of detergent. Recent progress has to a large extent been dependent upon the introduction of digitonin, a detergent in which B cell receptor complexes are at least partially stable, as an agent to solubilize B cell membranes. Studies presented here demonstrate that if another well known detergent, octyl-beta-D-glucopyranoside (octyl glucoside), is utilized in place of digitonin, mIg receptors are immunoprecipitated from B cell lysates in association with several newly identified proteins, whose phosphorylation is also G protein dependent. In particular we find three to four mIg associated phosphoproteins in the molecular weight range of 47 to 57 kDa, and at least two others at 82 and 112 kDa. Some of these proteins may correspond to polypeptides that have been functionally linked to mIg dependent signal transduction, but have not as yet been shown to be physically coupled to the receptor.

The B-cell antigen receptor of the five immunoglobulin classes

Several proteins associate with surface IgM to form the antigen receptor. We show that just two, the alpha and beta associated chains, are sufficient to reconstitute an IgM surface receptor in fibroblasts. Contrary to expectation, a common alpha chain associates with all five immunoglobulin classes. We propose that B-cell antigen receptors consist of a common alpha/beta heterodimer associated with each immunoglobulin class. But the classes differ both in the glycosylation of their associated alpha chain and in their dependence on alpha/beta for surface transport.