The internalization of the IgG2a antigen receptor does not require the association with Ig-alpha and Ig-beta but the activation of protein tyrosine kinases does

B cell depletion with anti-CD79 mAbs ameliorates autoimmune disease in MRL/lpr mice

MRL/lpr mice develop a spontaneous systemic lupus erythematosus-like autoimmune syndrome due to a dysfunctional Fas receptor, with contributions from other less well-defined genetic loci. The removal of B cells by genetic manipulation not only prevents autoantibody formation, but it also results in substantially reduced T cell activation and kidney inflammation. To determine whether B cell depletion by administration of Abs is effective in lupus mice with an intact immune system and established disease, we screened several B cell-specific mAbs and found that a combination of anti-CD79alpha and anti-CD79beta Abs was most effective at depleting B cells in vivo. Anti-CD79 therapy started at 4-5 mo of age in MRL/lpr mice significantly decreased B cells (B220(+)CD19(+)) in peripheral blood, bone marrow, and spleens. Treated mice also had a significant increase in the number of both double-negative T cells and naive CD4(+) T cells, and a decreased relative abundance of CD4(+) memory cells. Serum anti-chromatin IgG levels were significantly decreased compared with controls, whereas serum anti-dsDNA IgG, total IgG, or total IgM were unaffected. Overall, survival was improved with lower mean skin scores and significantly fewer focal inflammatory infiltrates in submandibular salivary glands and kidneys. Anti-CD79 mAbs show promise as a potential treatment for systemic lupus erythematosus and as a model for B cell depletion in vivo.

Results from modeling of B-Cell receptors binding to antigen

In the late 80's, Dintzis et al. conducted an experiment which showed that T-Cell independent activation of B-cells needs high-valence antigen and happens only in a narrow range of antigen concentration. These experiments were believed to be explained by the "immunon" theory that requires that a minimum number of receptors need to be cross-linked to activate a cell. However, the immunon theory does not take into account receptor dynamics and cannot explain the lack of immune response at high antigen concentration or low antigen valence. We propose instead a simple, new mechanism for the T-Cell independent activation of B-Cell, which includes receptor endocytosis. Our model focuses on the fact that for the majority of antigens where the B-Cell is activated with T-Cell help, the kinetic parameters for binding, unbinding and endocytosis must be tuned so that there is an equilibrium between the number of receptors bound on the surface of the B-Cell and the number of antigen-bound receptors endocytosed. This equilibrium mechanism is probably generic and will also occur even when the B-Cell is activated by antigen without T-Cell help. By computer modeling, we show that if we accept this hypothesis of the requirement for equilibrium between the two mechanisms of binding and endocytosis, then we can explain both the valence cutoff and the low and high zone tolerance seen in the Dintzis experiment.

A high-molecular-weight complex of membrane proteins BAP29/BAP31 is involved in the retention of membrane-bound IgD in the endoplasmic reticulum

B cell antigen receptors (BCRs) are multimeric transmembrane protein complexes comprising membrane-bound immunoglobulins (mIgs) and Ig-alpha/Ig-beta heterodimers. In most cases, transport of mIgs from the endoplasmic reticulum (ER) to the cell surface requires assembly with the Ig-alpha/Ig-beta subunits. In addition to Ig-alpha/Ig-beta, mIg molecules also bind two ER-resident membrane proteins, BAP29 and BAP31, and the chaperone heavy chain binding protein (BiP). In this article, we show that neither Ig-alpha/Ig-beta nor BAP29/BAP31 nor BiP bind simultaneously to the same mIgD molecule. Blue native PAGE revealed that only a minor fraction of intracellular mIgD is associated with high-molecular-weight BAP29/BAP31 complexes. BAP-binding to mIgs was found to correlate with ER retention of chimeric mIgD molecules. On high-level expression in Drosophila melanogaster S2 cells, mIgD molecules were detected on the cell surface in the absence of Ig-alpha/Ig-beta. This aberrant transport was prevented by coexpression of BAP29 and BAP31. Thus, BAP complexes contribute to ER retention of mIg complexes that are not bound to Ig-alpha/Ig-beta. Furthermore, the mechanism of ER retention of both BAP31 and mIgD is not through retrieval from a post-ER compartment, but true ER retention. In conclusion, BAP29 and BAP31 might be the long sought after retention proteins and/or chaperones that act on transmembrane regions of various proteins.

A distinct signaling pathway used by the IgG-containing B cell antigen receptor

The immunoglobulin G (IgG)-containing B lymphocyte antigen receptor (IgG-BCR) transmits a signal distinct from that of IgM-BCR or IgD-BCR, although all three use the same signal-transducing component, Igalpha/Igbeta. Here we demonstrate that the inhibitory coreceptor CD22 down-modulates signaling through IgM-BCR and IgD-BCR, but not that through IgG-BCR, because of the IgG cytoplasmic tail, which prevents CD22 phosphorylation. These results suggest that the cytoplasmic tail of IgG specifically enhances IgG-BCR signaling by preventing CD22-mediated signal inhibition. Enhanced signaling through IgG-BCR may be involved in efficient IgG production, which is crucial for immunity to pathogens.

Burst-enhancing role of the IgG membrane tail as a molecular determinant of memory

The basis of immune memory leading to heightened secondary antibody responses is a longstanding unanswered issue. Here we show that a single irreversible molecular change in the B cell antigen receptor, which is brought about by immunoglobulin M (IgM) to IgG isotype switching, is sufficient to greatly increase the extrafollicular proliferative burst of antigen-specific B cells. The unique membrane-spanning regions of IgG do not alter the T cell-dependent activation and proliferation of antigen-specific B cells in vivo, but markedly increase the number of progeny cells and plasmablasts that accumulate. These results establish a key molecular determinant of immunological memory and define an unexpected cellular basis by which it enhances the magnitude of secondary antibody responses.

Functional Fc epsilonRI engagement by a second secretory IgE isoform detected in humans

We have recently reported that besides the most abundant form epsilonS1, there exists another human secretory epsilon H chain isoform, epsilonS2, resulting from alternative splicing in the epsilonCH4 exon. Using a specific antibody targeted to the epsilonS2-specific C-terminal tailpiece, we now show that this second secretory IgE isoform (IgE-S2) is constitutively co-expressed with the classical secretory IgE-S1 by human myeloma cells. The epsilonS2 variant was also detected in tonsils and in the serum of three non-atopic donors, but was absent in the vast majority of sera of both atopic and non-atopic individuals tested, indicating rare serum expression. IgE-S2 is capable of binding to cells expressing Fc epsilonRI, the high-affinity receptor for IgE. Analysis of intracellular tyrosine phosphorylation signal, degranulation, and rate of receptor internalization suggest a quantitatively lower response by IgE-S2 compared to IgE-S1. The modest differences observed do not appear to overall affect the degranulation competency of IgE-S2, but suggest that the unique structure of the epsilonS2 tailpiece can exert an effect on the interaction with the alpha chain of Fc epsilonRI.

Role of transmembrane domains in the functions of B- and T-cell receptors

The antigen receptors on the surface of B- and T-lymphocytes are complexes of several integral membrane proteins, essential for their proper expression and function. Recent studies demonstrated that transmembrane (TM) domains of the components of these receptors play a critical role in their association and function. It was specifically demonstrated that in many cases point mutations in the TM domains can partially or completely disrupt the receptor surface expression and function. Here we review studies of the TM domains of B- and T-cell receptors. Furthermore, we use a novel method, PHDtopology, to provide estimates of the exact locations and lengths of the TM domains of the subunit components of these receptors. Most previous studies used single residue hydrophobicity as a criterion for determining the position and length of the TM domains. In contrast, PHDtopology utilizes a system of neural networks and the evolutionary information contained in multiple alignments of related sequences to predict the location, length, and orientation of transmembrane helices. Present results significantly differ from most published estimates of the TM domains of the B- and T-cell receptor components, primarily in the length of the TM domains. These results may lead to modification of putative TM motifs and re-interpretation of the results of studies using mutated TM domains. The availability of PHDtopology on the Internet would make it a valuable tool in the future studies of the TM domains of integral membrane proteins.

syk protein tyrosine kinase regulates Fc receptor gamma-chain-mediated transport to lysosomes

B- and T-cell receptors, as well as most Fc receptors (FcR), are part of a large family of membrane proteins named immunoreceptors and are expressed on all cells of the immune system. Immunoreceptors' biological functions rely on two of their fundamental attributes: signal transduction and internalization. The signals required for these two functions are present in the chains associated with immunoreceptors, within conserved amino acid motifs called immunoreceptor tyrosine-based activation motifs (ITAMs). We have examined the role of the protein tyrosine kinase (PTK) syk, a critical effector of immunoreceptor-mediated cell signalling through ITAMs, in FcR-associated gamma-chain internalization and lysosomal targeting. A point mutation in the immunoreceptor-associated gamma-chain ITAM affecting syk activation, as well as overexpression of a syk dominant negative mutant, inhibited signal transduction without affecting receptor coated-pit localization or internalization. In contrast, blocking of gamma-chain-mediated syk activation impaired FcR transport from endosomes to lysosomes and selectively inhibited the presentation of certain T-cell epitopes. Therefore, activation of the PTK syk is dispensable for receptor internalization, but necessary for cell signalling and for gamma-chain-mediated FcR delivery to lysosomes.

Inhibition of B-cell receptor-antigen complex internalization by FcgammaRIIB1 signals

Membrane-expressed immunoglobulins are B-cell receptors (BCR) for specific antigens (Ag). Upon Ag engagement of the BCR, B-cells are activated to internalize Ag-BCR complexes, process Ag and subsequently present Ag-peptides loaded in class II MHC. Due to the specific nature of the BCR, the cognate interaction between T-cells expressing Ag-specific T-cell receptor and these Ag-presenting B-cells occur in a highly regulated and precise manner. Accordingly, efficient control of T-cell activation may be achieved through regulation of Ag presenting B-cells. A potent form of regulation of lymphocyte responses is mediated by Ig end-product and anti-idiotypic antibodies via Fc-dependent mechanisms. In this communication, the authors present data that an anti-idiotype (anti-Id) Ab inhibits BCR-mediated internalization of specific Ag. Coupling of BCR to the cytoskeleton was also abortive in anti-Id Ab-treated B-cells. Inhibition by anti-Id Ab was dependent upon the presence of FcgammaRIIB1 on B-cells. As a result of anti-Id Ab suppression, B-cells were unable to initiate Ca2+ responses in Ag-specific T-cells. The results suggest that co-crosslinking of FcgammaRIIB1 and BCR inhibits cytoskeletal coupling and internalization of the Ag-BCR complex thereby preventing specific Ag presentation by B-cells. Anti-Id Ab may mediate a negative regulatory mechanism that suppresses B-cell-mediated Ag-specific T-cell activation.

A Tyrosine-Based Signal Present in Ig α Mediates B Cell Receptor Constitutive Internalization

B lymphocytes express Ag receptors (BCR) that are composed of ligand binding subunits, the membrane Igs, associated with Ig α/Ig β heterodimers. One main BCR function is to bind and to internalize Ags. Peptides generated from these internalized Ags may be presented to T lymphocytes. Here, we have analyzed the involvement of BCR Ig α/Ig β components in BCR constitutive endocytosis. The role of Ig α subunit in BCR constitutive endocytosis was first determined in the context of an IgM-based BCR. In contrast with BCR that contain wild-type Ig α, surface BCR lacking Ig α cytoplasmic domain were not constitutively internalized. The respective roles of Ig α and Ig β subunits were then analyzed by expressing chimeric molecules containing the cytoplasmic domains of either subunits in a B cell line. Only the Ig α cytoplasmic domain contained an internalization signal that allowed constitutive endocytosis of Ig α chimeras via coated pits and accumulation in sorting-recycling endosomes. This internalization signal is contained in its immunoreceptor tyrosine-based activation motif. These results indicate that Ig α, through its immunoreceptor tyrosine-based activation motif, may account for the ability of IgM/IgD BCR to constitutively internalize monovalent Ags.

Role of B-cell and Fc receptors in the selection of T-cell epitopes

The role of specific receptors in antigen internalization and presentation to helper T lymphocytes has been known for more than ten years. However, recent work indicates that internalization may not always be sufficient for antigen presentation. Indeed, antigen receptors such as B-cell receptors and Fc receptors may also be involved in the post-endocytic transport events that determine selectively the delivery of antigens to different endocytic compartments and thereby the presentation of different T-cell epitopes.

Antigen endocytosis and presentation mediated by human membrane IgG1 in the absence of the Ig(alpha)/Ig(beta) dimer

Membrane immunoglobulin (mIg) M and D heavy chains possess minimal (KVK) cytoplasmic tails and associate with the Ig alpha/Ig beta (CD79) dimer to achieve surface expression and antigen presentation function. In contrast, the cytoplasmic tail of mIgG is extended by 25 residues (gamma ct). We have tested the possibility that mIgG can perform antigen capture and presentation functions independently of the Ig(alpha)/beta dimer. We show that CD4/(gamma)ct chimeras are efficiently endocytosed partially dependent on a tyrosine residue in (gamma)ct. In addition, human mIgG was expressed on the surface of Ig(alpha)/Ig(beta)-negative non-lymphoid cells and mediated antigen capture and endocytosis. Antigen-specific human mIgG targeted antigen to MIIC-type vesicles in the Ig(alpha)/beta negative melanoma Mel JuSo and augmented antigen presentation 1000-fold, identical to the augmentation seen in Ig(alpha)/beta-positive B-cells expressing the same transfected mIgG. Thus, unlike mIgM, mIgG has autonomous antigen capture and presentation capacity, which may have evolved to reduce or eliminate the BCR's dependence on additional accessory molecules.

Engagement of the B lymphocyte antigen receptor induces presentation of intrinsic immunoglobulin peptides on major histocompatibility complex class II molecules

By means of the clonotypic variable region, the immunoglobulin (Ig) is a tumor-specific antigen on B cell neoplasms. We report that engagement of the B cell antigen receptor (BcR) promotes presentation of peptides derived from the B cell's intrinsic Ig to major histocompatibility complex (MHC) class II-restricted T cells. Thus, anti-Ig endowed normal, ex vivo B lymphocytes from H-2d, Ig constant heavy chain allotype b (IgCHb) mice with the capacity to stimulate an I-Ad-restricted T cell clone which recognizes the gamma 2ab 435-451 allopeptide. The corresponding self gamma 2aa peptide is cryptic and 6000-fold less antigenic than the gamma 2ab allopeptide. Even so, the syngeneic B cell lymphoma A20 which expresses surface(s) IgG2aa, was also recognized by the T cells after BcR ligation. Thus, anti-Ig triggered the disclosure of a cryptic tumor antigen determinant. We propose that autoantigens, by engaging the BcR of self-reactive B cells, induce presentation of intrinsic Ig peptides to which the T helper cell (Th) repertoire is not tolerant. In this way, B cells with anti-self potential may be activated without Th recognition of nominal autoantigen.

Endosomal targeting by the cytoplasmic tail of membrane immunoglobulin

Membrane-bound immunoglobulin (mIg) of the IgG, IgA, and IgE classes have conserved cytoplasmic tails. To investigate the function of these tails, a B cell line was transfected with truncated or mutated gamma2a heavy chains. Transport to the endosomal compartment of antigen bound by the B cell antigen receptor did not occur in the absence of the cytoplasmic tail; and one or two mutations, respectively, in the Tyr-X-X-Met motif of the tail partially or completely interrupted the process. Experiments with chimeric antigen receptors confirmed these findings. Thus, a role for the cytoplasmic tail of mIg heavy chains in endosomal targeting of antigen is revealed.

The roles of gamma 1 heavy chain membrane expression and cytoplasmic tail in IgG1 responses

In antibody responses, B cells switch from the expression of immunoglobulin (Ig) mu and delta heavy (H) chains to that of other Ig classes (alpha, gamma, or epsilon), each with a distinct effector function. Membrane-bound forms of alpha, gamma, and epsilon, but not mu and delta, have highly conserved cytoplasmic tails. Mutant mice unable to express membrane gamma1 H chains or producing tailless gamma1 H chains failed to generate efficient IgG1 responses and IgG1 memory. H chain membrane expression after class switching is thus required for these functions, and class switching equips the B cell antigen receptor with a regulatory cytoplasmic tail that naïve B cells lack.

Capture and processing of exogenous antigens for presentation on MHC molecules

Class I and class II MHC molecules bind peptides during their biosynthetic maturation and provide a continuously updated display of intracellular and environmental protein composition, respectively, for scrutiny by T cells. Receptor-mediated endocytosis, phagocytosis, and macropinocytosis all contribute to antigen uptake by class II MHC-positive antigen-presenting cells. Capture of antigenic peptides by class II MHC molecules is facilitated because antigen catabolism and class II MHC maturation take place in the same compartments or in communicating compartments of the endosome/lysosome system. These class II MHC-rich, multivesicular endosomes receive incoming antigen and can support not only antigen processing and class II MHC peptide loading but also the export of peptide/class II MHC complexes to the cell surface. A balance between production and destruction of antigenic peptides is achieved by the activity of local proteases and may be influenced by binding of antigen to other proteins both prior to the onset of processing (e.g. antibodies) and during antigen unfolding (e.g. MHC molecules). T cell determinants that can be released for MHC binding without a substantial processing requirement may be able to utilize a distinct minor population of cell surface class II MHC molecules that become available during peripheral recycling. Although peptides derived from exogenous protein sources are usually excluded from presentation on class I MHC molecules, recent evidence shows that this embargo may be lifted in certain professional antigen-presenting cells to increase the spectrum of antigens that may be displayed on class I MHC.

Initiation and processing of signals from the B cell antigen receptor

Current models of signal transduction from the antigen receptors on B and T cells still resemble equations with several unknown elements. Data from recent knockout experiments in cell lines and mice contradict the assumption that Src-family kinase and tyrosine kinases of the Syk/Zap-70 family are the transducer elements that set signaling from these receptors in motion. Using a functional definition of signaling elements, we discuss the current knowledge of signaling events from the BCR and suggest the existence of an as-yet-unknown BCR transducer complex.

Evidence for a preformed transducer complex organized by the B cell antigen receptor

The B cell antigen receptor (BCR) consists of the membrane-bound immunoglobulin (mIg) molecule and the Ig-alpha/Ig-beta heterodimer, which functions as signaling subunit of the receptor. Stimulation of the BCR activates protein tyrosine kinases (PTKs) that phosphorylate a number of substrate proteins, including the Ig-alpha/Ig-beta heterodimer of the BCR itself. How the PTKs become activated after BCR engagement is not known at present. Here, we show that BCR-negative J558L cells treated with the protein tyrosine phosphatase inhibitor pervanadate/H2O2 display only a weak substrate phosphorylation. However, in BCR-positive transfectants of J558L, treatment with pervanadate/H2O2 induces a strong phosphorylation of several substrate proteins. Treatment with pervanadate/H2O2 does not result in receptor crosslinking, yet the pattern of protein phosphorylation is similar to that observed after BCR stimulation by antigen. The response requires cellular integrity because tyrosine phosphorylation of most substrates is not visible in cell lysates. Cells that express a BCR containing an Ig-alpha subunit with a mutated immunoreceptor tyrosine-based activation motif display a delayed response. The data suggest that, once expressed on the surface, the BCR organizes protein tyrosine phosphatases, PTKs, and their substrates into a transducer complex that can be activated by pervanadate/H202 in the absence of BCR crosslinking. Assembly of this preformed complex seems to be a prerequisite for BCR-mediated signal transduction.

Compartmentalization of B-cell antigen receptor functions

Receptor tyrosine kinases (RTK), like the PDGF-receptor, translate information from the extracellular environment into cytoplasmic signals that regulate a spectrum of cellular functions. RTK molecules consist of ligand binding extracellular domains, cytoplasmic kinase domains and tyrosine phosphorylation sites [Ullrich and Schlessinger, 1990 (Cell 61, 203-212); Heldin, 1992 (EMBO J. 11, 4251-4259)]. Upon ligand-induced RTK oligomerization, the kinase domains will become activated and induce auto(trans)phosphorylation of a number of cytoplasmic tyrosine residues. These phosphorylated tyrosine residues are incorporated in distinct sequence motifs and act as specific docking sites for SH2 domain-containing proteins [Songyang et al., 1993 (Cell 72, 767-778)]. In contrast to single- or oligo-chain RTK, immunological receptors such as antigen receptors, FcR and cytokine receptors are multi-chain complexes in which distinct receptor functions appear to be compartmentalized in distinct polypeptides. Here, we summarize current knowledge on the structural and functional characteristics of the B-cell antigen receptor complex (BCR) and address the specific ability of accessory molecules to recruit intracellular signaling intermediates towards the activated receptor complex.

Non-tolerant B cells cause autoimmunity in anti-CD8 IgG2a-transgenic mice

Using a pair of gamma 2a/chi immunoglobulin genes, transgenic mice were generated to study tolerance induction in B cells that express IgG2a autoantibodies. The transgenic IgG2a specifically binds CD8 alpha chains of the CD8.2 allotype expressed on the surface of CD8+ T cells, but not CD8 molecules expressed by the CD8.1 allele. Thus, IgG2a transgenic mice expressing the CD8.1 allele were used as controls to monitor B cell development and mice expressing CD8.2 were used to study B cell tolerance. Both types of mice showed transgenic gamma 2a expression on the surface of B cells. Expression of endogenous heavy chain alleles was strongly inhibited in immature B cell subsets, whereas mature B cells co-expressed transgenic gamma 2a and endogenous IgM/D. The transgenic chi chain expression leads only to partial allelic exclusion of endogenous light chains. B cells that express high levels of transgenic CD8.2-specific IgG2a were identified using soluble CD8-Ig. In CD8.1+ and in CD8.2+ mice, we found no differences in expression and maturation of transgenic anti-CD8.2 IgG2a+ B cells. High levels of serum anti-CD8.2 IgG2a antibodies led to the elimination of CD8+ T cells, causing a severe defect in cytotoxic immune responses. These results show that tolerance induction is incomplete in the CD8.2+ mice, either because IgG2a+ B cells are resistant to censoring mechanisms or because the secreted CD8-specific IgG2a antibodies render the CD8 autoantigen inaccessible to the B cells. This contrasts strongly with the efficient induction of B cell tolerance in mice expressing anti-CD8.2 IgM autoantibodies.

Signaling difference between class IgM and IgD antigen receptors

Most mature B lymphocytes coexpress two classes of antigen receptor, IgM and IgD. The differences in the signal transduction from the two receptors are still a matter of controversy. We have analyzed B-cell lines expressing IgM or IgD antigen receptors with the same antigen specificity. Cross-linking of these receptors with either antigen or class-specific antibodies results in the activation of protein tyrosine kinases and the phosphorylation of the same substrate proteins. The kinetic and intensity of phosphorylation, however, was quite different between the two receptors when they were cross-linked by antigen. In membrane IgM-expressing cells, the substrate phosphorylation reached a maximum after one minute and diminished after 60 minutes, whereas in the membrane IgD-expressing cells, the substrate phosphorylation increased further over time, reaching its maximum at 60 minutes and persisting longer than 240 minutes after exposure to antigen. Recently prolonged signaling has been found to be responsible for signaling differences between tyrosine kinase receptors using otherwise similar signaling routes. Thus, the duration of a signal may be an important biological feature of signal-transducing cascades.

The B cell antigen receptor of class IgD induces a stronger and more prolonged protein tyrosine phosphorylation than that of class IgM

Most mature B lymphocytes coexpress two classes of antigen receptor, immunoglobulin (Ig)M and IgD. The differences in the signal transduction from the two receptors are still a matter of controversy. We have analyzed B cell lines expressing IgM or IgD antigen receptors with the same antigen specificity. Cross-linking of these receptors with either antigen, or class-specific antibodies, results in the activation of protein tyrosine kinases and the phosphorylation of the same substrate proteins. The kinetic and the intensity of phosphorylation, however, was quite different between the two receptors when they were cross-linked by antigen. In membrane IgM-expressing cells, the substrate phosphorylation reached a maximum after 1 minute and diminished after 60 minutes whereas, in the membrane IgD-expressing cells, the substrate phosphorylation increased further over time, reached its maximum at 60 minutes, and persisted longer than 240 minutes after exposure to antigen. As a result, the intensity of protein tyrosine phosphorylation induced by cross-linking of membrane IgD was stronger than that induced by membrane IgM. Studies of chimeric receptors demonstrate that only the membrane-proximal C domain and/or the transmembrane part of membrane-bound IgD molecule is required for the long-lasting substrate phosphorylation. Together, these data suggest that the signal emission from the two receptors is controlled differently.

Function of B-cell antigen receptor of different classes

Most mature B lymphocytes co-express two classes of antigen receptor, IgM and IgD. The differences in the signal transduction from the 2 receptors are still a matter of controversy. We have analysed B-cell lines expressing IgM or IgD antigen receptors with the same antigen specificity. Cross-linking of these receptors with either antigen or class-specific antibodies results in the activation of protein tyrosine kinases and the phosphorylation of the same substrate proteins. The kinetics and intensity of phosphorylation, however, were quite different between the 2 receptors when they were cross-linked by antigen. In membrane IgM-expressing cells, the substrate phosphorylation reached a maximum already after 1 min and diminished after 60 min whereas in the membrane IgD-expressing cells, the substrate phosphorylation increases further over time, reached its maximum at 60 min and persisted longer than 240 min after exposure to antigen. Recently prolonged signaling has been found to be responsible for signaling differences between tyrosine kinase receptors using otherwise similar signaling routes. Thus, the duration of a signal may be an important biological feature of signal transducing cascades.

Surface immunoglobulins mediate efficient transport of antigen to lysosomal compartments resulting in enhanced specific antigen presentation by B cells

A BCL1 immunoglobulin (Ig) transfectant, expressing wild-type surface (s)IgM with the TEPC-15 idiotype (T15-Id) and anti-phosphorylcholine (PC) specificity, was previously shown to present PC-conjugated hen egg-white lysozyme (PC-HEL) to a HEL-specific T cell hybridoma at a lower antigen (Ag) concentration than that required for native HEL. Two variant Ig transfectants, expressing T15-Id sIgM with substitutions either in the entire spacer, transmembrane (TM) domain and cytoplasmic tail (B186 variant) or in the NH2-terminal third of TM domain only (TM2 variant), failed to display this sIgM-mediated, enhanced presentation of PC-HEL at low concentrations. However, prolonged treatment with anti-T15-Id monoclonal antibody (mAb) led to a reduction of surface expression of the T15-Id sIgM in the wild-type and TM2 variant, but not in the B186 variant sIgM transfectants. Treatment with anti-T15-Id mAb also resulted in an increased intracellular accumulation of T15-Id sIgM in the wild-type transfectant, but not in the B186 variant. Subcellular fractionation analysis revealed that the ligands bound to the T15-Id sIgM are not efficiently transported to the dense lysosomal compartments in both B186 and TM2 transfectants, as compared to the wild-type sIgM transfectant. A significant increase in tyrosine phosphorylation after cross-linking of the T15-Id sIgM was observed only in the wild-type sIgM transfectant. These results suggest that, while the NH2-terminal third of the TM region is not involved in the process responsible for the ligand-induced reduction of surface expression of sIgM, it appears to be essential for subsequent transport of sIgM/ligand complexes to the lysosomal compartments, as well as efficient activation of tyrosine kinases. These results strongly suggest that sIg-mediated enhancement of specific antigen presentation reflects the ability of sIg to efficiently transport antigen to the lysosomal compartments, and possibly the activation of protein tyrosine kinases.