Fc gamma receptor II (CD32) on malignant B cells influences modulation induced by anti-CD19 monoclonal antibody

Antigenic modulation is one of many factors determining the effectiveness of monoclonal antibody (MoAb)-mediated therapy. To select the isotype of a CD19 MoAb most suitable for radioimmunotherapy of patients with B-cell malignancies, we studied the influence of MoAb isotype on modulation, after binding of the MoAb to different cell-line cells. The CD19-IgG1 MoAb was found to induce modulation of CD19 antigens on Daudi cell line cells more rapidly than did its IgG2a switch variant. We provide evidence that this difference in modulation rate is caused by the expression of Fc gamma receptor II (Fc gamma RII) on these cells. Experiments aimed at elucidating the mechanism of Fc gamma RII involvement in modulation induction by CD19-IgG1 showed that Fc gamma RII did not comodulate with CD19 MoAbs. However, cocrosslinking of CD19 and Fc gamma RII with CD19-IgG1 MoAb resulted in enhanced calcium mobilization in Daudi cells. This increased signal induction accompanies the enhanced capping and subsequent modulation of CD19 antigens. Because Fc gamma RII is expressed in varying densities on malignant B cells in all differentiation stages, our results have implications for the MoAb isotype most suitable for use in MoAb-based therapy of patients with B-cell malignancies.     

Anti-GPIIb/IIIa (CD41) monoclonal antibody-induced platelet activation requires Fc receptor-dependent cell-cell interaction

We studied platelet activation by UR1, a murine IgG1 anti-CD41 mAb. Like thrombin and crosslinked anti-Fc gamma RII mAb IV3, UR1 initiates prompt aggregation and Ca2+ mobilization. UR1 F(ab')2 fragments failed to activate, yet inhibited UR1 IgG-mediated activation. UR1-induced activation was blocked by anti-Fc gamma RII mAb. High viscosity (15% dextran or Ficoll), which impedes cell-cell interaction, inhibited activation by UR1. Cell-cell interaction was confirmed by cell-mixing studies. UR1 binding to platelets of one pool was blocked with UR1 F(ab')2 allowing UR1 binding only to Fc gamma RII. IV3 Fab fragments blocked ligand binding to Fc gamma RII on platelets of a second pool; thus, UR1 could bind only its epitope. UR1 initiated an immediate [Ca2+]i increase in the intermixed pools at low ionic strength. These studies indicate that UR1 IgG binds CD41 on one platelet to form immune complexes which then crosslink and stimulate Fc gamma RII on nearby platelets. Two other anti-CD41 mAb, 6C9 and C17, and two anti-CD9 mAb, AG1 and mAb7, activated platelets in a UR1-like manner. We propose that platelet Fc gamma RII crosslinking that follows the interaction of IgG-opsonized platelets may be a common mechanism by which anti-platelet antibodies activate platelets.     

Membrane glycoproteins and platelet cytoskeleton in immune complex- induced platelet activation

To clarify the mechanism of platelet activation by immune complexes and the possible involvement of surface glycoproteins (GPs), we studied platelet activation induced by heat-aggregated IgG (HAG). We examined the effects of monoclonal antibodies (MoAbs) against GPIb, GPIIb/IIIa, and the Fc receptor on resting platelets and on platelets stimulated by HAG. HAG increased the cytosolic ionized calcium concentration ([Ca2+]i) and stimulated protein (P47 and P20) phosphorylation, phosphatidic acid (PA) synthesis, serotonin secretion, and platelet aggregation. IV.3, an anti-Fc gamma RII receptor MoAb, inhibited HAG binding to platelets and all subsequent platelet responses. Like IV.3, MoAbs against GPIIb/IIIa (Tab, 10E5, AP-3) or GPIb (AP-1, 6D1) strongly inhibited platelet activation by HAG. However, while anti-GPIIb/IIIa MoAbs inhibited binding of IV.3 and HAG to platelets, anti-GPIb MoAbs had little effect on platelet binding of IV.3 or HAG. These observations suggest a close topographical and functional association of GPIIb/IIIa with Fc gamma RII in the platelet response to HAG. Cytochalasin B, an inhibitor of actin polymerization, also inhibited platelet activation but not HAG or IV.3 binding. Measurement of the fluorescence of 7-nitrobenz-2-oxa-1,3-(NBD)-phallacidin, a specific marker for filamentous actin (F-actin), showed that both cytochalasin B and AP-1 blocked the increase of F-actin induced by HAG. The common effects of anti-GPIb MoAbs and of cytochalasin B suggest that unlike the activity of GPIIb/IIIa, the ability of anti-GPIb to inhibit the activation of platelets by immune complexes is associated with perturbation of the cytoskeleton.     

Transfection of an Fc gamma receptor cDNA induces T cells to become phagocytic.

The human receptor Fc gamma RIIA for the Fc portion of IgG (Fc gamma) was expressed in a human T-cell line and conferred on these cells the ability to perform IgG antibody-stimulated phagocytosis. Crosslinking Fc gamma RIIA with anti-Fc gamma RII monoclonal antibody also induced tyrosine phosphorylation of multiple proteins including Fc gamma RIIA, ZAP-70, p72SYK, and phospholipase C gamma 1 subunit and an increase in intracellular Ca2+ concentration. The T cell receptor-associated zeta-chain was not tyrosine-phosphorylated after crosslinking of Fc gamma RIIA, suggesting that the Fc gamma RIIA-mediated signals were independent of CD3. Fc gamma RIIA-mediated signal transduction was defective in a transfected mutant T-cell line exhibiting reduced expression of the tyrosine kinases LCK and FYN. These studies indicate that certain T cells can assume phagocytic properties after transfection of cDNA encoding an Fc gamma receptor with the capability of inducing a phagocytic signal.     

Platelet activation by immobilized monoclonal antibody: evidence for a CD9 proximal signal.

Anti-CD9 monoclonal antibodies (MoAbs) are reported to activate human platelets through stimulation of the Fc gamma II receptor. We show here that nonstimulatory F(ab')2 fragments of the anti-CD9 MoAb 50H.19 induce dense-granule release and dose-dependent platelet aggregation when attached to polystyrene latex beads. Cross-linking F(ab')2 fragments of MoAb 50H.19 by F(ab')2 fragments of goat anti-mouse IgG does not result in platelet aggregation unless the second antibody is bound to latex beads, indicating that immobilization, and not cross-linking of the stimulus, is critical to the initiation of the CD9 signal. In contrast, F(ab')2 fragments of the second antibody readily induce the aggregation of platelets treated with the anti-Fc gamma II receptor MoAb IV.3. Immobilization of MoAb per se is insufficient to induce an activation signal because intact and F(ab')2 fragments of nonstimulatory MoAb directed to glycoprotein Ib and HLA class I do not become stimulatory when attached to beads. CD9-induced activation requires cytoskeletal rearrangement because it is inhibited by cytochalasin B. Aggregation is blocked by inhibitors of the thromboxane pathway, indicating that CD9 activates phospholipase C indirectly through prior activation of phospholipase A2.     

Monocyte Fc gamma receptor recognition of cell-bound and aggregated IgG

Monocyte and macrophage Fc gamma receptors are important components in the recognition of IgG-coated cells and IgG-containing immune complexes. Two proteins have been identified on human peripheral blood monocytes that can function as Fc gamma receptors, Fc gamma RI (70 Kd) and Fc gamma RII (40 Kd). We studied the role of Fc gamma RI and Fc gamma RII on human monocytes by examining their binding of IgG-sensitized cells (human IgG anti-D-coated RBCs and rabbit IgG-sensitized sheep RBCs) and their binding of human trimeric IgG. To examine the function of monocyte Fc gamma RII, we used an anti-Fc gamma RII monoclonal antibody (MoAb) that competes for the Fc gamma RII ligand binding site. Preincubation of monocytes with saturating concentrations of anti-Fc gamma RII MoAb did not alter the recognition of IgG (anti-D)-sensitized human RBCs by monocytes. Furthermore, ligand-binding studies demonstrated that anti-Fc gamma RII antibody altered neither the number nor the affinity of monocyte-binding sites for human IgG trimer. Anti-Fc gamma RII inhibited monocyte binding of rabbit IgG-sensitized sheep RBCs, but only at low ionic strength or temperature when increased numbers of monocyte Fc gamma RII were expressed. At low ionic strength and 4 degrees C, anti-Fc gamma RII also partially inhibited monocyte binding of human trimeric IgG. Thus, monocyte Fc gamma RII does not appear to recognize IgG-sensitized RBCs or trimeric IgG at physiologic temperatures and ionic strength. The data suggest that Fc gamma RI is the primary Fc gamma receptor on monocytes involved in the binding of IgG (anti-D)-sensitized erythrocytes and low mol wt complexes of IgG.     

Investigation of the mechanisms of monoclonal antibody-induced platelet activation.

Antiplatelet antibodies can activate platelets causing platelet aggregation and the release reaction. However, the pathway of activation by these antibodies is unknown and several potential mechanisms are possible. In this report, we describe studies investigating potential pathways of platelet activation by IgG antibodies. We tested 16 different IgG monoclonal antibodies (MoAbs) against a variety of platelet surface components and found that six antibodies were capable of causing platelet aggregation and release. These included MoAbs against glycoprotein (GP) IIb/IIIa, CD9, GPIV, and two other not well-characterized platelet components. There was no relationship between the number of platelet binding sites and the ability of an MoAb to activate the platelets. By adding intact and F(ab')2 preparations of the MoAb to control or Fc receptor-blocked platelets, we found that in all instances the MoAbs initiated platelet activation via interacting with the platelet Fc receptors. Clustering of the platelet protein components using a secondary antibody did not cause activation. Studies into the pathway of Fc-dependent activation demonstrated that the MoAbs were capable of activating platelets by occupying Fc receptors on adjacent platelets (interplatelet activation), as well as on the same platelet (intraplatelet activation).     

Human platelet aggregation by murine monoclonal antiplatelet antibodies is subtype-dependent

Twenty murine monoclonal antibodies (MoAbs) generated against different human platelet antigens induced clumping of human platelets in plasma and buffer. Whereas one MoAb could agglutinate platelets, clumping for 19 MoAbs was blocked by metabolic inhibitors, indicating that these induce platelet activation. Fifteen MoAbs were of IgG1, two of IgG2a, and two of IgG2b subtype. F(ab')2 fragments of these did not evoke an aggregatory response, but specifically inhibited aggregations by and binding of their respective intact MoAbs to platelets. Single-platelet counting technology indicated that the MoAbs bind through their antigen- binding and Fc domains mainly to the surface of the same platelet, rather than cause interplatelet-binding. Despite these similarities, the mechanism of action was nevertheless subtype-dependent. Aggregation induced by all IgG1 antibodies could consistently be prevented by blocking the Fc gamma II-receptor, whereas aggregations induced by all IgG2 antibodies still occurred with blocked Fc-receptor, provided functional complement was present. We therefore conclude that platelet activation by MoAb-binding is initiated by antigen recognition followed by an Fc domain-dependent step, which involves the Fc gamma II-receptor for IgG1-type MoAbs and complement-binding for IgG2-type MoAbs. Thus, antibodies of different subtypes can aggregate platelets via different pathways.     

Neutrophils express the high affinity receptor for IgG (Fc gamma RI, CD64) after in vivo application of recombinant human granulocyte colony-stimulating factor.

Fc receptors are important effector molecules of neutrophilic granulocytes (polymorphonuclear neutrophils [PMN]), connecting phagocytic cells and the specific immune response. Neutrophils from healthy donors express the low-affinity receptors for IgG Fc gamma RII (CD32) and Fc gamma RIII (CD16), but not the high-affinity receptor Fc gamma RI (CD64). The latter has been found on neutrophils from patients with certain bacterial infections and can be induced in vitro after incubation with interferon-gamma. We show here that neutrophils strongly express Fc gamma RI after in vivo application of recombinant human granulocyte colony-stimulating factor (rhG-CSF). PMN from patients receiving rhG-CSF displayed higher cytotoxicity against Daudi lymphoma cells in vitro compared with control patients and with healthy donors. Fab fragments against Fc gamma RII (monoclonal antibody [MoAb] IV.3) inhibited neutrophil-mediated cytotoxicity of healthy donors but not of patients during rhG-CSF therapy. Therefore, expression of Fc receptors by PMN was investigated by flow cytometry and the mean fluorescence intensity (MFI) was compared. After staining with MoAb 32.2 against Fc gamma RL, the median MFI of neutrophils from G-CSF patients (median, 4.78; range, 2.40 to 8.50; n = 5) was significantly higher (P = .002 and P = .001, respectively) than the median MFI of patients not receiving G-CSF (median, 1.23; range, 1.01 to 1.58; n = 6) and the median MFI of healthy donors (median, 1.04; range, 0.67 to 1.12; n = 6). Fc gamma RI disappeared after the discontinuing of the G-CSF injections, but was reinduced during the next treatment cycle with rhG-CSF. The high expression of Fc gamma RI during rhG-CSF therapy correlated with enhanced cytotoxicity. In vitro incubation with rhG-CSF also enhances cytotoxicity, but only minor increments in Fc gamma RI expression were observed. Thus, during in vivo application of rhG-CSF neutrophils acquire an additional potent receptor for mediating tumor cell killing in vitro by induction of the high-affinity receptor for IgG (Fc gamma RI, CD64).     

Granulocyte Fc gamma receptor recognition of cell bound and aggregated IgG: effect of gamma-interferon.

Granulocyte Fc gamma receptors are important components in the recognition of IgG-coated cells and immune complexes. Two proteins have been identified on resting human granulocytes which function as Fc gamma receptors, Fc gamma RII (CD32) and Fc gamma RIII (CD16). A third protein, Fc gamma RI (CD64), is not constitutively expressed on resting granulocytes, but can be induced by activation with gamma-interferon. We examined the role of these three Fc gamma receptors on human granulocytes in the binding of both IgG-sensitized erythrocytes and soluble oligomeric IgG. In these studies we employed anti-Fc gamma receptor antibodies which complete for the Fc gamma RII and Fc gamma RIII ligand binding sites. Preincubation of granulocytes with saturating concentrations of high-affinity anti-Fc gamma RII monoclonal antibody did not alter the recognition of IgG sensitized human cells by granulocytes. Furthermore, ligand binding studies demonstrated that anti-Fc gamma RII antibody altered neither the number nor the affinity of granulocyte binding sites for human trimeric IgG. In contrast, Fab anti-Fc gamma RIII inhibited the binding of both IgG (anti-D) sensitized human RBCs and IgG sensitized sheep RBCs. Similarly, a reduction in the expression of Fc gamma RIII by treatment with phosphatidyl-inositol specific phospholipase C reduced PMN recognition of IgG-sensitized cells. Also, anti-Fc gamma RIII decreased the number of granulocyte binding sites for human IgG trimer without a change in receptor affinity. Fc gamma RI, which was induced by gamma-IFN, increased granulocyte recognition of both IgG sensitized RBCs and IgG trimer. These data suggest that Fc gamma RIII is the primary Fc gamma receptor on granulocytes which recognizes IgG sensitized RBCs and low molecular weight complexes of IgG. With gamma-interferon activated granulocytes, Fc gamma RI appears to enhance this recognition process.     

Neutrophil activation through high-affinity Fc gamma receptor using a monomeric antibody with unique properties.

The high-affinity, type I Ig Fc receptor (Fc gamma RI) for human IgG1, human IgG3, murine IgG2a, and murine IgG3 is highly expressed on monocytes, neutrophils (PMN) in certain disease states, and phagocytes treated with interferon-gamma (IFN-gamma). We studied the activation of the human PMN oxidative burst and stimulated fluid pinocytosis induced by three monoclonal antibodies (MoAbs) directed against Fc gamma RI (CD64) to study the role of this receptor in Fc-mediated cellular activation. All three MoAbs were capable of triggering PMN activation from IFN-gamma-treated PMN when cross-linked with goat antimurine Ig reagents. However, MoAb 197 alone demonstrated a concentration-dependent activation of the oxidative burst without the use of a second cross-linking antibody. The oxidative burst and stimulated fluid pinocytosis responses induced by monomeric MoAb 197 could be elicited only after the IFN-gamma induction of approximately 8,000 Fc gamma RI receptor equivalents and did not occur in freshly isolated or control-cultured PMN. Competitive blocking of Fc binding of MoAb 197 by human IgG or purified Fc fragments inhibited cellular activation. We believe the ability of MoAb 197 to activate these oxidative burst and fluid pinocytic responses was because of its murine IgG2a subclass, which allowed it to function as a trivalent anti-Fc gamma RI antibody binding through the combination of its two FAB regions and the Fc domain. This study demonstrates that the cross-linking of CD64 can activate PMN oxidative and endocytic responses and supports a role for Fc gamma RI in the human neutrophil inflammatory response.     

Characterization of Fc gamma receptors on a human erythroleukemia cell line (HEL).

It has been established that human platelets express a single class of Fc gamma receptors that has been designated Fc gamma RII. However, the function of this receptor on these cells and its regulation are less certain. Studies to further investigate Fc gamma RII on platelets are limited by the inability to culture platelets in vitro. Therefore, identification of a human cell line that expresses Fc gamma RII as its only Fc gamma receptor as well as other platelet characteristics would be of potential importance. To this end, we examined Fc gamma receptor expression by the human erythroleukemia (HEL) cell line, which expresses platelet/megakaryocyte surface proteins. Flow cytometry studies on HEL cells with anti-Fc gamma receptor monoclonal antibodies revealed that, similar to platelets and megakaryocytes, Fc gamma RII is the only Fc gamma receptor expressed on the cell surface. Furthermore, Northern blot analysis revealed that Fc gamma RII is the only Fc gamma receptor mRNA present. Stimulation with dimethylsulfoxide (DMSO) or 12-O-tetradecanoylphorbol-13-acetate (TPA) did not alter Fc gamma RII protein or mRNA expression. Ligand binding studies with [125I]IgG trimer indicated that HEL cells express 92,240 +/- 5030 binding sites per cell, with a kd of 1.94 +/- 0.31 x 10(-8) M. Similar to human platelets, HEL cells preferentially bound oligomeric IgG, and this binding was ionic strength dependent. These observations are similar to those previously observed with Fc gamma RII on human platelets and suggest that the HEL cell Fc gamma receptor is similar, if not identical to the platelet Fc gamma RII receptor. HEL cells may serve as a model for the study of platelet/megakaryocyte Fc gamma RII.     

Thrombosis and shock induced by activating antiplatelet antibodies in human Fc gamma RIIA transgenic mice: the interplay among antibody, spleen, and Fc receptor

Transgenic mouse lines were created that express Fc gamma RIIA on platelets and macrophages at human physiologic levels, and they were used to explore the consequences in vivo of activating antiplatelet antibodies. Anti-CD9 antibody activated platelets of Fc gamma RIIA transgenic (tg) mice and, following injection in vivo, caused more rapid severe thrombocytopenia than nonactivating antiplatelet antibody. Anti-CD9 injected into Fc gamma RIIA tg crossed with FcR gamma-chain knockout (gamma-KO) mice caused thrombosis and shock in all mice, and death in 16 of 18 mice. The shock depended on platelet Fc receptor density and antibody dose. On histologic examination, the lung vasculature of anti-CD9-treated Fc gamma RIIA tg x gamma-KO mice contained extensive platelet-fibrin thrombi. Thrombosis and shock in Fc gamma RIIA tg mice in the context of the FcR gamma-chain knockout suggested the importance of the interplay of intravascular platelet activation and splenic clearance. Reduction of splenic clearance surgically (splenectomy) or functionally (monoclonal antibody treatment) also facilitated anti-CD9-mediated shock in Fc gamma RIIA tg mice. The spleen, which clears nonactivating antibody-coated platelets leading to thrombocytopenia, appears to play a protective role in the thrombosis and shock observed with activating antiplatelet antibody. The data indicate that antibodies, which activate platelets in an Fc gamma RIIA-dependent manner, can lead to thrombosis, shock, and death. Furthermore, antibody titer, platelet Fc receptor density, and splenic clearance are likely important determinants of the outcome. (Blood. 2000;96:4254-4260)     

The loss of Fc gamma RIIIb in paroxysmal nocturnal hemoglobinuria is functionally replaced by Fc gamma RII

Neutrophils from patients with paroxysmal nocturnal hemoglobinuria (PNH) show a deficiency for the glycosylphosphatidylinositol- (GPI) linked Fc gamma receptor IIIb (Fc gamma RIIIb, CD16). The functional consequences of this defect are not clear. Here, we examined Fc gamma RIIIb-deficient neutrophils for their activation via Fc gamma receptors. Hydrogen peroxide (H2O2) production and change of intracellular free calcium [Ca2+]i were used as parameters for cell activation. Fc gamma RII and Fc gamma RIIIb stimulation was reached by cross-linking using fragments of monoclonal antibodies or incubation with monoclonal IgG cryoglobulin complexes. In parallel to the deficiency of Fc gamma RIIIb expression, H2O2 production and [Ca2+]i influx were decreased after cross-linking of Fc gamma RIIIb in PNH neutrophils compared with that for normal neutrophils. Stimulation via Fc gamma RII was not affected. Cryoglobulin complexes previously shown to activate normal neutrophils predominantly via Fc gamma RIIIb stimulated PNH neutrophils at a level not significantly weaker than controls. But this activation was mediated only via Fc gamma RII as shown by blocking studies. The results suggest that the loss of GPI- anchored Fc gamma RIIIb is functionally replaced by Fc gamma RII during the immune complex stimulation of PNH neutrophils. Therefore, the equipment of neutrophils with pleomorphic Fc gamma receptors prevents an immunodeficiency in PNH.     

Humanized mouse models of FcR clearance in immune platelet disorders

Transgenic mouse lines expressing physiologic levels of human platelet Fc receptor (FcR) for IgG, Fc gamma RIIA, on platelets and macrophages were generated. Anti-CD9 antibody activated platelets of Fc gamma RIIA transgenic mice and, following injection in vivo, caused rapid and severe thrombocytopenia compared with nonactivating antiplatelet antibody. Anti-CD9 injected in Fc gamma RIIA transgenic mice crossed with FcR gamma-chain knockout (gamma-KO) mice caused thrombosis and shock in all mice, and death in 16 of 18 mice. Histologic examination of lung vasculature of anti-CD-treated Fc gamma RIIA transgenic x gamma-KO mice showed extensive platelet-fibrin thrombi. Taken together, these observations suggest that in Fc gamma RIIA transgenic x gamma-KO mice there is an important interplay of intravascular platelet activation and splenic clearance. Reduction of splenic clearance surgically or functionally also facilitated anti-CD-9-mediated shock in Fc gamma RIIA transgenic mice. Thus, antibodies that activate platelets in an Fc gamma RIIA-dependent manner lead to thrombosis, shock, and death. These mouse model findings have implications for human immune-mediated thrombocytopenic disorders. Genetic factors may be important in the interindividual variability seen clinically, and with nonactivating platelet antibody the spleen is largely responsible for the thrombocytopenia. This is likely the case in typical idiopathic thrombocytopenic purpura (ITP). For several other immune thrombocytopenic disorders, the spleen probably plays a second, protective role in removing antibody-coated platelets from the circulation.     

Polymorphisms of protein tyrosine phosphatase CD148 influence FcγRIIA-dependent platelet activation and the risk of heparin-induced thrombocytopenia

Heparin-induced thrombocytopenia (HIT) is due primarily to IgG antibodies specific to platelet factor 4/heparin complexes (PF4/Hs) that activate platelets via FcγRIIA. CD148 is a protein tyrosine phosphatase that regulates Src kinases and collagen-induced platelet activation. Three polymorphisms affecting CD148 (Q276P, R326Q, and D872E) were studied in HIT patients and 2 control groups, with or without antibodies to PF4/Hs. Heterozygote status for CD148 276P or 326Q alleles was less frequent in HIT patients, suggesting a protective effect of these polymorphisms. Aggregation tests performed with collagen, HIT plasma, and monoclonal antibodies cross-linking FcγRIIA showed consistent hyporesponsiveness of platelets expressing the 276P/326Q alleles. In addition, platelets expressing the 276P/326Q alleles exhibited a greater sensitivity to the Src family kinases inhibitor dasatinib in response to collagen or ALB6 cross-linking FcγRIIA receptors. Moreover, the activatory phosphorylation of Src family kinases was considerably delayed as well as the phosphorylation of Linker for activation of T cells and phospholipase Cγ2, 2 major signaling proteins downstream from FcγRIIA. In conclusion, this study shows that CD148 polymorphisms affect platelet activation and probably exert a protec-tive effect on the risk of HIT in patients with antibodies to PF4/Hs.     

Activation via the CD3 and CD16 pathway mediates interleukin-2-dependent autocrine proliferation of granular lymphocytes in patients with granular lymphocyte proliferative disorders.

Granular lymphocytes (GLs) in patients with GL-proliferative disorders (GLPDs) are known to express the interleukin-2 receptor (IL-2R) beta chain (p70-75) constitutively and to proliferate in response to stimulation with IL-2 via the beta chain. In this report, we found that the anti-CD3 monoclonal antibody (MoAb) OKT3 could induce the proliferation of GLs from patients with T-cell lineage GLPDs (T-cell receptor-alpha beta+/CD3+16+), but not that of natural killer (NK) cell lineage GLs (T-cell receptor-alpha beta-/CD3-16+). In contrast, the anti-CD16 MoAb 3G8 that reacts with NK-lineage GLs could induce the proliferation of these GLs but not that of GLs with a T-cell phenotype. Furthermore, the anti-CD16 MoAbs CLB FcR gran1 (VD2) and OK-NK, which react with both T- and NK-lineage GLs, induced the proliferation of GLs with both T- and and NK-cell phenotypes. The proliferative response induced via the CD3 or IgG Fc receptor III (Fc gamma RIII: CD16) pathway was shown to be associated with the IL-2-dependent autocrine pathway by various findings, including the induction of endogenous IL-2 production, the coexpression of the IL-2R alpha chain (p55) and the IL-2R beta chain, and the inhibition of GL proliferation by anti-IL-2 or anti-IL-2R MoAb. These results suggest that GL proliferation is mediated at least partly through the IL-2-dependent autocrine pathway, and that the TCR/CD3 complex in T-cell phenotype GLs and the Fc gamma RIII in both T- and NK-cell phenotype GLs play a role in their activation in GLPDs.     

Platelet activation by cross-linking HLA class I molecules and Fc receptor.

The effect on platelet activation of monoclonal antibodies directed against common determinants of the HLA class I heavy chain molecule was studied. Cross-linking W6/32, an anti-HLA class I of IgG2a subclass, led to platelet activation. Two other antibodies of the same subclass did not have this effect on platelets. The lack of activity of the F(ab')2 fragments suggests that the activation signal is mediated by the platelet Fc receptor (Fc gamma RII). Indeed, except for a higher sensitivity of W6/32 to aspirin and apyrase, activations by cross-linking IV-3 (an anti-Fc gamma RII) and W6/32 are similar at the level of InsP3 formation, calcium mobilization, pH modifications, and activation of protein kinase C and myosin kinase. When HLA class I molecules and Fc gamma RII are cross-linked together, platelet activation occurs. This is not observed when a control IgG2a is substituted for W6/32 or when CD9 and Fc receptor are cross-linked together. This suggests that HLA class I molecules and Fc gamma RII synergize to activate platelets.     

Human Fc gamma RIII: cloning, expression, and identification of the chromosomal locus of two Fc receptors for IgG.

A cDNA clone encoding a human receptor for the Fc portion of IgG (Fc gamma R), Fc gamma RIII or CD16, was isolated from a human leukocyte library by a transient expression-immunoselection procedure. This cDNA (pGP5) encodes a 46-kDa phosphatidylinositol-linked cell surface protein with CD16 determinants and affinity for human IgG. The deduced protein sequence is most homologous to the murine receptor Fc gamma RII alpha, with slightly less homology to the human receptors Fc gamma RII and Fc epsilon RI. The cDNA hybridizes to a 2.2 kilobase mRNA in human leukocytes and a cloned human natural killer cell line. Fc gamma RIII is mapped to chromosome 1 by spot-blot analysis of sorted human chromosomes. Hybridization of Fc gamma RII and Fc gamma RIII probes to restriction digests of human genomic DNA separated by pulsed-field gel electrophoresis demonstrates physical linkage of the two genes within a maximum distance of 200 kilobases. The results identify a locus for at least two Fc gamma R genes on human chromosome 1.     

Insertion of cytoplasmic tyrosine sequences into the nonphagocytic receptor Fc gamma RIIB establishes phagocytic function

Receptors for the Fc domain of IgG on cells of hematopoietic lineage perform important functions, including stimulation of the ingestion of IgG-coated cells. In examining the function of Fc gamma receptor isoforms by transfection into COS-1 cells, we have observed that Fc gamma RIIA induces the binding and phagocytosis of IgG-sensitized RBCs (EA) and that transfected COS-1 cells can serve as a model for examining the molecular structures involved in mediating a phagocytic signal. We now report that COS-1 cell transfectants expressing the isoforms Fc gamma RIIB1 and Fc gamma RIIB2 and a Fc gamma RIIA mutant without a cytoplasmic tail efficiently bind EA but do not mediate their phagocytosis. Furthermore, wild-type Fc gamma RIIA, but not Fc gamma RIIB1 or Fc gamma RBII2, was phosphorylated on tyrosine upon receptor activation. Tyrphostin 23, which alters tyrosine kinase activity, inhibited the phagocytosis of EA and reduced the phosphorylation of Fc gamma RIIA on tyrosine. Fc gamma RIIB1 and Fc gamma RIIB2 contain one copy of the cytoplasmic sequence YXXL/I implicated in signal transduction, whereas Fc gamma RIIA contains two copies. We therefore inserted YXXL/I sequences at different sites in Fc gamma RIIB2. Low levels of phagocytosis were observed in a Fc gamma RIIB2 mutant bearing the Fc gamma RIIA sequence YMTL and higher levels of phagocytosis were observed in a second Fc gamma RIIB2 mutant that contained both the upstream YMTL and an additional downstream tyrosine-containing motif. Activation of this mutant receptor also induced receptor tyrosine phosphorylation. Thus, these studies indicate that both the number and placement of YXXL sequences in the cytoplasmic domain of the Fc gamma RII receptor family affect both receptor tyrosine phosphorylation and phagocytic competence.