Fc gamma receptor type IIb induced recruitment of inositol and protein phosphatases to the signal transductory complex of human B-cell

Co-clustering of Fc gamma RIIb and B-cell receptor (BCR) inhibits cell activation by interrupting BCR stimulated signal transduction. The immunoreceptor tyrosine-based inhibitory motif (ITIM) of Fc gamma RIIb becomes tyrosyl phosphorylated (P-ITIM) upon co-clustering with BCR then P-ITIM interacts with several signalling molecules, some of which negatively regulate the cell activation process. The molecules recruited by the P-ITIM of human Fc gamma RIIb have not been characterised yet. In order to affinity isolate the potential functional partner molecules of human Fc gamma RIIb, synthetic peptides were designed to cover almost the entire intracellular Fc gamma RIIb domain, including Fc gamma RIIb2 specific sequences and stretches containing the phosphorylated and non-phosphorylated ITIM. We report here that several tyrosyl phosphorylated proteins bind to the P-ITIM peptide from both resting and activated B-cell lysates, the 53-56 kDa being the most prominent one. A fraction of the 53-56 kDa bands were identified as the protein tyrosine kinase (PTK), Lyn which also bound to ITIM peptide, pointing to its role in initiating Fc gamma RIIb-mediated negative regulation. Among the P-ITIM associated tyr phosphorylated components, the 145 kDa one was identified as the inositol polyphosphate 5-phosphatase, SHIP and the 72 kDa protein as the protein tyrosine phosphatase (PTP) SHP2, whereas SHP1 was not detected. Phosphatase activity assays showed that P-ITIM bound about five times higher SHIP and four times higher PTP activity than the ITIM containing peptide. Furthermore, we detected PKC and MAPK in both ITIM and P-ITIM peptides precipitated samples. Since human B-cells express both Fc gamma RIIb1 and Fc gamma RIIb2, differing in a 19 amino acid insert in the cytoplasmic tail of the former, we investigated the components binding to Fc gamma RIIb1 and Fc gamma RIIb2 specific sequences. Synthetic peptide representing Fc gamma RIIb1 and Fc gamma RIIb2 specific sequences weakly bound unidentified tyr phosphorylated proteins at 50-56 kDa, while the insert itself did not bind a detectable amount of protein. Neither of the ITIM or P-ITIM bound molecules were observed in samples precipitated with peptides corresponding to Fc gamma RIIb1 or Fc gamma RIIb2 specific sequences. These observations suggest that protein kinases associate with both ITIM and P-ITIM of human Fc gamma RIIb, Lyn being responsible for the tyrosyl phosphorylation of ITIM. SHIP and SHP2 phosphatases selectively bind to the phosphorylated ITIM. Based on these data we assume that SHIP and SHP2 recruited in vivo to the Fc gamma RIIb co-clustered BCR are responsible for the Fc gamma RIIb mediated negative regulation of human B-cell activation.

Membrane-bound ezrin is involved in B-cell receptor-mediated signaling: potential role of an ITAM-like ezrin motif

Ezrin is a cytoskeleton-plasma membrane linker molecule which is implicated in the T-cell antigen receptor signaling as one of the major tyrosine phosphorylated components. Its function in B-lymphocyte activation has not yet been clarified. Here we studied the potential involvement of ezrin in the B-cell receptor (BCR) signaling in BL41 Burkitt lymphoma cells. Our data demonstrate that ezrin, which shows predominantly cytosolic distribution in unstimulated cells, undergoes only a moderate tyrosine phosphorylation in response to BCR triggering, with no concomitant translocation of the protein from the cytosol to the plasma membrane. Instead, BCR-independent stimulants like oxidant stress induced by phenylarsine oxide, resulted in rapid redistribution of ezrin to the plasma membrane. When BCR triggering was preceded by membrane recruitment of ezrin, it became one of the main and earliest substrates of tyrosine kinases activated by BCR. No detectable influence on distribution or phosphorylation of ezrin was triggered by the tyrosine phosphatase inhibition by orthovanadate, suggesting that these effects of phenylarsine oxide are not attributable to its tyrosine phosphatase inhibitory capacity. The notion that BCR-mediated phosphorylation of ezrin negatively correlates with activation events such as phosphorylation of tyrosine kinase, syk and induction of calcium mobilization response, suggests that ezrin might be implicated in the regulation of transmembrane signaling and cellular responsiveness. As will be discussed, the regulatory function of ezrin may be due to an immunoreceptor tyrosine-based activation motif (ITAM)-like sequence.

Dermal microvascular endothelial cells express CD32 receptors in vivo and in vitro

Immune complexes are thought to be the major cause of cutaneous necrotizing vasculitis, but the mechanism of immune complex targeting to specific vessels is largely unknown. In myelomonocytic cells, immune complex binding and receptor-mediated endocytosis are mediated by Fc gamma R. We asked whether dermal microvascular endothelial cells (DMEC) express Fc gamma Rs. In cryostat sections of normal human skin, mAb IV.3 or AT10, both recognizing CD32 (Fc gamma RII), localizes to the luminal surface of DMEC of the superficial but not of the deep vascular plexus. All DMEC do not express CD16 (Fc gamma RIII) or CD64 (Fc gamma RI) molecules. Adult skin-derived DMEC in culture express CD32 (Fc gamma RII) molecules, as measured by FACS, but are negative for CD16 or CD64. HUVEC, tested for comparison, do not express CD16, 32, or 64 proteins. By reverse-transcriptase PCR and subsequent Southern blot analysis, the isoform of the CD32 molecule expressed on DMEC is determined as Fc gamma RIIa. HUVEC do not contain Fc gamma RIIa or Fc gamma RIIb mRNA. In DMEC, Fc gamma RIIa cross-linking results in immediate intracellular free Ca2+ ([Ca2+]i) concentration fluxes and in rapid internalization of the occupied receptors. We conclude that DMEC are equipped with fully functional Fc gamma RIIa molecules.

Dermal microvascular endothelial cells express CD32 receptors in vivo and in vitro

Immune complexes are thought to be the major cause of cutaneous necrotizing vasculitis, but the mechanism of immune complex targeting to specific vessels is largely unknown. In myelomonocytic cells, immune complex binding and receptor-mediated endocytosis are mediated by Fc gamma R. We asked whether dermal microvascular endothelial cells (DMEC) express Fc gamma Rs. In cryostat sections of normal human skin, mAb IV.3 or AT10, both recognizing CD32 (Fc gamma RII), localizes to the luminal surface of DMEC of the superficial but not of the deep vascular plexus. All DMEC do not express CD16 (Fc gamma RIII) or CD64 (Fc gamma RI) molecules. Adult skin-derived DMEC in culture express CD32 (Fc gamma RII) molecules, as measured by FACS, but are negative for CD16 or CD64. HUVEC, tested for comparison, do not express CD16, 32, or 64 proteins. By reverse-transcriptase PCR and subsequent Southern blot analysis, the isoform of the CD32 molecule expressed on DMEC is determined as Fc gamma RIIa. HUVEC do not contain Fc gamma RIIa or Fc gamma RIIb mRNA. In DMEC, Fc gamma RIIa cross-linking results in immediate intracellular free Ca2+ ([Ca2+]i) concentration fluxes and in rapid internalization of the occupied receptors. We conclude that DMEC are equipped with fully functional Fc gamma RIIa molecules.

Interaction of signaling molecules with human Fc gamma RIIb1 and the role of various Fc gamma RIIb isoforms in B-cell regulation

The low-affinity type-IIb IgG Fc-binding receptors (Fc gamma RIIb) are expressed on B cells. When cross-linked with mIgM Fc gamma RIIb are known to down-regulate B-cell activation by interrupting signal transduction upstream from G-protein-activated events. We have studied Fc gamma RII isoforms expressed on resting and activated B cells and the interaction of Fc gamma RIIb1 with molecules transducing the antigen receptor-mediated signals. Expression of Fc gamma RII isoforms was studied by reverse transcription and polymerase chain reaction. Resting B cells express both Fc gamma RIIb2 and Fc gamma RIIb1 isoforms. Activation with anti-IgM or IL-4 induces the splicing of Fc gamma RIIb1 mRNA, while the alternative splicing of Fc gamma RIIb2 mRNA is down-regulated, resulting in the surface expression of Fc gamma RIIb1. Functional differences were found between the two isoforms in inhibiting B-cell activation, suggesting that Fc gamma RIIb2 might influence the threshold of signals necessary for activation of resting B cells, while Fc gamma RIIb1 may regulate in later phases of antibody response. To explore the mechanism by which Fc gamma RII may uncouple antigen receptor-mediated signal transduction, we have investigated the association of signaling molecules with Fc gamma RII. Beside the protein tyrosine kinase (PTK) fyn, protein kinase C (PKC) was found to be co-isolated with Fc gamma RIIb1, suggesting a tight connection between these kinases and Fc gamma RII. We suggest that PKC might be responsible for the activation-induced phosphorylation of Fc gamma RII on serine residues.(ABSTRACT TRUNCATED AT 250 WORDS)

Rapid desensitization of B-cell receptor by a dithiol-reactive protein tyrosine phosphatase inhibitor: uncoupling of membrane IgM from syk inhibits signals leading to Ca2+ mobilization

B-cell antigen receptor (BCR)-mediated calcium response can be blocked by phenylarsine oxide (PAO), a dithiol group-reactive protein tyrosine phosphatase inhibitor. We have examined the mechanism of this inhibition in BL41 Burkitt lymphoma cells. PAO-dependent inhibition is not restricted to the BCR-mediated functions, as evidenced by the failure of the same cells to mobilize Ca2+ in response to CD19 cross-linking. In contrast, calcium response induced by a putative syk activator, H2O2, exhibited only a moderate sensitivity to PAO, demonstrating that PAO did not cause general suppression of all the functions leading to Ca2+ mobilization. BCR cross-linking or H2O2 treatment leads to the induction of almost complete non-responsiveness for the reciprocal stimulation. Since BCR cross-linking did not generate non-responsiveness to H2O2 in the presence of PAO, and PAO-treated cells remained responsive to syk activation by H2O2, we suppose that PAO may inhibit BCR-mediated signal transduction events upstream of syk activation. This assumption was supported by additional data, indicating that PAO was able to modulate functions of at least 2 different protein tyrosine kinase enzymes involved in BCR-mediated signaling. PAO induced rapid and dose-dependent tyrosine phosphorylation of lyn and selectively inhibited BCR-mediated tyrosine phosphorylation of syk. The results presented in this paper demonstrate that PAO may provoke cellular desensitization process by alteration of the signal transducer functions of lyn and syk tyrosine kinase enzymes.

Phenylarsine oxide (PAO) blocks antigen receptor-induced calcium response and tyrosine phosphorylation of a distinct group of proteins

Antigen receptor (AgR) crosslinking by antigens or AgR-specific antibodies induces a cascade of enzymatic events in lymphocytes which involves activation of several non-receptor tyrosine- and serine/threonine kinases, phosphatases, phospholipases, etc. Here we show data demonstrating that a thiol group-reactive protein tyrosine phosphatase (PTP) inhibitor, phenylarsine oxide (PAO), uncouples a crucial part of the signaling events induced by anti-IgM or anti-Leu-4 (CD3) in human tonsil B lymphocytes, BL41 and Daudi B cell lines and Jurkat T lymphoma cells. PAO treatment (10 microM) resulting in distinct modification of AgR-induced tyrosine phosphorylation pattern inhibited the AgR-mediated calcium response (Ca++ release and influx) of all of these cells completely. Since this treatment did not alter the cell viability and the binding capacity of the AgR crosslinking antibodies, alteration of the tyrosine phosphorylation pattern and blockage of the calcium response indicate prompt inactivation of essential signal transduction element(s).

Mapping and comparison of the interaction sites on the Fc region of IgG responsible for triggering antibody dependent cellular cytotoxicity (ADCC) through different types of human Fc gamma receptor

In the present study 3-iodo-4-hydroxy-5-nitrophenacetyl (NIP)-specific antibodies were compared for induction of antibody dependent lysis of NIP-derivatised red blood cells effected by pre-stimulated U937 or HL-60 cells and by K cells. The chimaeric antibodies have heavy chains corresponding to human IgG subclasses 1-4, and include site-directed mutants of IgG3 as well as the aglycosylated form of IgG3; a mouse IgG2b antibody and a site-directed mutant IgG2b were also examined. rIFN stimulated U937 or HL-60 cells express increased levels of Fc gamma R1 compared to unstimulated cells; PMA stimulated HL-60 and U937 cells express an increased level of Fc gamma R11 compared to unstimulated cells; K cells express Fc gamma R111. Using these effector cell populations and the target cells mentioned above, we have compared anti-NIP antibodies with different heavy chain constant domains for their ability to induce ADCC through human Fc gamma R1, Fc gamma R11 and Fc gamma R111. The results suggest that all three human Fc gamma receptors appear to recognise a binding site on IgG within the lower hinge (residues 234-237) and trigger ADCC via this site, but that each receptor sees this common site in a different way. The possibility that other amino acid residues also participate in the binding/triggering site(s) cannot be excluded.

New in vitro line from a human (B) non-Hodgkin lymphoma

An in vitro cell line (HT 58) has been established from a human (B) NHL xenograft. The lymphoma cells in culture retained their lymphoblastic appearance, DNA-content, IgM/lambda monoclonality and many immunophenotypic markers. The clonal chromosomal abnormalities involved the chromosomes 1, 2, 3 and 14. The cells expressed and produced chondroitin sulfate proteoglycans identified with mAbs that were raised against human articular cartilage CSPG. The cells also released IgM into the medium as well as substances that stimulated the proliferation of activated normal peripheral B-cells.

The two binding-site models of human IgG binding Fc gamma receptors

Fc receptors (FcR) are immunoglobulin-binding molecules that enable antibodies to perform several biological functions by forming a link between specific antigen recognition and effector cells. FcRs are involved in regulating antibody production as well. Most FcRs belong to the immunoglobulin superfamily, and show structural homology with each other and with their ligands. Recent data on the structure of IgG binding FcRs obtained from monoclonal antibodies and gene cloning studies, as well as on ligand binding capacity and fine specificity of the receptor binding site (or sites), are reviewed. The binding capacity and fine specificity of receptor binding sites, as well as the structure and conformation of the immunoglobulin ligands, play important roles in triggering FcR-mediated signals. In induction of signals, the interaction of the FcR with the CH2 domain of the IgGFc is decisive. The high-affinity Fc gamma RI possess one active binding site specific for contact residues that is located at the N-proximal end of the CH2 domain and is able to mediate both binding and signal transfer. The low-affinity Fc gamma RIII has two active binding sites: the CH3 domain-specific site, which mediates only binding; and the CH2 domain-specific site, which is responsible for binding and signaling. Similarly, the low-affinity Fc gamma RII on resting B cells has one site for CH2 and another for CH3 binding. The expression, release, and fine specificity of Fc gamma RII on B cells correlates with the cell cycle.

A protein structural change in aglycosylated IgG3 correlates with loss of huFc gamma R1 and huFc gamma R111 binding and/or activation

Glycosylated chimeric mouse-human anti-NIP IgG3 antibody produced by growth of the J558L mouse B cell plasmacytoma is characterised with respect to the single carbohydrate chain at Asn-297 in the CH2 domain indicating that the mouse cell glycosyl transferases dictate the pattern of glycosylation rather than the human CH region of the heavy chain. Additionally, three unusual alpha-galactose-containing oligosaccharides are reported. Only the Fc region has detectable carbohydrate. Aglycosylated anti-NIP IgG3 antibody has been produced by cell growth in the presence of the antibiotic tunicamycin. Functionally, whilst the glycosylated intact IgG3 interacts with human Fc gamma R111 expressed on human killer (K) cells to trigger antibody-dependent cellular cytotoxicity the aglycosylated intact IgG3 fails to trigger cell lysis, localising the site on IgG for triggering human Fc gamma R111 mediated functions to the CH2 domain. The monomeric aglycosylated trypsin Fc fragment inhibits human Fc gamma R1 recognition by U937 cells 115-fold less well (K50 = 2 microM) than does glycosylated Fc (K50 = 17 nM), confirming that aglycosylation disrupts the site for human Fc gamma R1 within the CH2 domain and indicating that the trypsin Fc fragments reflect the functional properties of the intact IgG glycoforms. Structurally, 1H NMR shows that the absence of carbohydrate at Asn-297 results in a small and localised protein structural change in the vicinity of the reporter group His-268 within the CH2 domain. The site on IgG for triggering human Fc gamma R111 mediated functions is then localised to the vicinity of His-268. The profound impact of aglycosylation on human Fc gamma R1 recognition implies structural disruption of the proposed site for human Fc gamma R1 in the lower hinge region of IgG (residues 234-239), proximal to His-268.

Functional and immunogenetic characterization of FcR-blocking antibody

The characteristics and functional importance of FcR-blocking antibodies and their production were investigated after immunization with whole blood, "buffy coat" and purified platelets. We studied the presence of FcR-blocking antibody in haemodialyzed, transfused patients waiting for kidney transplantation, and we found strong correlation between the blocking effect and better graft survival. We suggest that this blocking antibody does not attack FcR as primary target. Investigation of blocking activity of ten different immune sera on 50 healthy panel cells showed that target antigen has some polymorphic varieties. On basis of family studies it seems that the target antigen is not linked to HLA haplotype. The blocking effect of sera could be removed by absorption of CD8+ cells, B lymphocytes, platelets and granulocytes, but not with erythrocytes, monocytes, CD8- cells and NK cells.

Phosphorylation of type II Fc gamma receptor on activated human B lymphocytes

Activation of resting human B lymphocytes either by cross-linking their membranal IgM or by phorbol esters has been previously demonstrated to modulate the type II receptor for Fc gamma domains (Fc gamma RII): shortly after stimulation a decrease in IgG binding capacity and an enhancement of Fc gamma RII expression were observed. These were followed by the release of Fc gamma RII fragments from the cell membrane. Since protein phosphorylation is well-established signal transduction element, we examined whether Fc gamma RII may be a target of such activation induced phosphorylation. Resting (high density) and activated (low density) human tonsil B lymphocytes were stimulated either by cross-linking their surface IgM (sIgM) or by the phorbol ester TPA. This treatment induced specific phosphorylation of a 36 kd membrane protein. This polypeptide was shown to specifically bind to IgG-coated Sepharose beads or to monoclonal Fc gamma RII-specific antibody-coated Affi-Gel 10 beads; thus, it most probably corresponds to the Fc gamma RII of these cells. In addition, phosphorylation of a 20 kd protein with similar binding characteristics was also observed in several experiments. Both serine and tyrosine were the amino acids that underwent phosphorylation in the 36 kd Fc gamma RII. The extent of Fc gamma RII phosphorylation correlated with the increase in receptor expression as monitored by specific mAb binding and, at the same time, with the decrease in the capacity to bind IgG-sensitized erythrocytes. These results suggest that stimulation-induced phosphorylation of Fc gamma RII on B cells is an early signal transduction element involved in controlling B cell response.

Effector or target cell selection mediated by C3 bridges

Potential effector cells (including stimulated lymphocytes and cultured monocytes) and potential target cells of NK and AK type cytotoxic reactions (including several lymphoblastoid cell lines) cleave the third complement component (C3). As a result of expression of C3bA sites such cells are able to bind covalently the activated C3b through its metastable binding site and thereby become "armed" by the C3b. This permits C3b-bridge formation between these cells and CR1-bearing cells. The "effector selection" (i.e. when C3b is bound covalently to potential target cells) or "target selection" (when C3b is covalently bound to C3bA sites on potential effector cells) mediated by C3b bridges results in enhanced killing capacity. Macrophages activate and bind C3b as well; but the covalent binding of C3b by these cells inhibits Fc receptor mediated ADCC type killing.

Modulation of Fc receptors on human peripheral blood lymphocytes by antisera against beta 2 microglobulin, Ia or immunoglobulin

The association between Fc receptors and other surface molecules was examined by EA-rosette (EAR) inhibition experiments. Twenty to 30% EAR were detected in suspensions of peripheral blood lymphocytes from normal individuals. Anti-β₂ microglobulin (βMi) sera fully suppressed EAR whereas anti-Ig, anti-Ia sera and heat aggregated IgG inhibited only 50–60% EAR. Thus almost half of the detected EAR were apparently not surface Ig positive B cells. Rabbit and monkey anti-βMi sera suppressed EAR effectively whereas rat and chicken antisera, despite strong βMi binding capacity, inhibited EAR poorly. The latter result was ascribed on the basis of immunofluorescent analysis to inadequate capping of βMi. Incubation of PBL with whole antisera suppressed EAR to a similar degree at either 0° or 37°, whereas F(ab′)₂ fragments were inhibitory only at 37°. Taken together the results suggest that Fc receptors can be inhibited by antibodies with specificity against any cell surface antigen. The blocking mechanism may be due to steric hindrance by the Fc part of antibody molecules and/or F(ab′)₂ fragment mediated co-capping.