Cell surface distribution of Fc receptors II and III on living human neutrophils before and during antibody dependent cellular cytotoxicity

Microscopic techniques have been employed to study the cell surface distributions of the immunoglobulin Fc receptors (FcR) II and III on living human neutrophils. Fluorescein-or rhodamine-conjugated monoclonal IgG or Fab fragments directed against FcRII (CDw32) and FcRIII (CD16) were employed to label receptors. FcRII and III were found to be uniformly distributed at neutrophil surfaces during resting conditions. During neutrophil polarization and migration FcRII but not FcRIII preferentially accumulated at the uropod. Sheep erythrocytes (SRBCs) were opsonized with IgG and then incubated with neutrophils. When neutrophils were labeled prior to target addition, FcRII but not FcRIII were found to cluster at the target-effector interface. Little or no clustering of FcRs was observed if labeling was performed after target binding. SRBC oxidation was observed using Soret band illumination during transmitted light microscopy. Time-lapse studies of FcRII distribution and target oxidation were performed. FcRII formed clusters at target effector interfaces prior to target oxidation. Three lines of evidence suggest that clustering is not a general plasma membrane response. Firstly, FcRIII do not cluster lannic acid-modified erythrocytes avidly bound to neutrophils but did not trigger clustering of FcRII. Furthermore, irrelevant neutrophil membrane labels were unaffected by the presence of IgG-opsonized erythrocytes. We suggest that FcRII clustering is one important component leading to the oxidative destruction of target cells.     

The 40-kDa Fc gamma receptor (FcRII) on human neutrophils is essential for the IgG-induced respiratory burst and IgG-induced phagocytosis

Neutrophils express two types of receptor for the Fc region of IgG, FcRII and FcRIII. Per neutrophil, 10,000 to 20,000 molecules of FcRII (40 kDa) and 100,000 to 200,000 molecules of FcRIII (50 to 80 kDa) are expressed. Via these receptors, neutrophils bind IgG complexes that contain more than one IgG molecule. This binding activates functional processes, such as the respiratory burst and phagocytosis. We studied the contribution of FcRII and FcRIII in the activation of these processes, using well-defined complexes (both large and small) in combination with mAb against FcRII and FcRIII. Small (dimeric) IgG complexes appeared to bind via FcRIII. However, binding to FcRIII alone, when FcRII is blocked by an anti-FcRII mAb, did not induce a respiratory burst. Induction of the respiratory burst by a large immune complex, such as Staphylococcus aureus Wood opsonized with IgG antibodies, was mediated by binding to FcRII, because it was blocked by an anti-FcRII mAb but not by an anti-FcRIII mAb. This indicates that these IgG-opsonized bacteria can cross-link FcRII and activate the cells without the need to adhere to the FcRIII. The respiratory burst induced by IgG-latex was not inhibited by an anti-FcRII mAb, because the avidity for FcRII of IgG-latex, a particle of the same size as a Staphylococcus but with a two to three times higher IgG content, is increased by its simultaneous binding to FcRIII. This enhanced avidity results in removal of anti-FcRII mAb from the FcRII by IgG-latex. This increased avidity of large complexes for FcRII, created by concurrent binding to FcRIII, is not necessary for activation of human neutrophils, because neutrophils from patients with paroxysmal nocturnal hemoglobinuria, with about 10% of the normal FcRIII expression, showed a normal metabolic response upon addition of IgG-latex. Phagocytosis of IgG-opsonized 14C-labeled S. aureus Wood was inhibited equally well by anti-FcRII mAb and by anti-FcRII in combination with anti-FcRIII mAb. Thus, FcRII is not only essential for the IgG-induced activation of the NADPH oxidase system, but also for the IgG-induced phagocytosis.     

Fc receptor heterogeneity: immunofluorescent studies of B, T, and "third population" lymphocytes in human blood with rabbit IgG b4/anti-b4 complexes.

IgG Fc receptors on human peripheral blood lymphocytes (PBL) were characterized by immunofluorescence studies with defined rabbit IgG b4 allotype/anti-allotype complexes. Three discrete types of Fc receptor-bearing cells, totaling approximately 33% of PBL, were identified. Fc receptors of the three types differed in their sensitivity to trypsin and in either absolute or localized density (topography) as determined by variable requirements for anti-IgC cross-linking in order to visualize bound complexes microscopically. The question of additional heterogeneity related to differences in individual Fc receptor affinity for complexed IgG was not approached in this study. Ten to 15% of PBL had pronase-sensitive, trypsin-resistant Fc receptors readily detected by direct immunofluorescence by using large fluorescein-conjugated complexes prepared near equivalence. Double label and lymphocyte fractionation experiments established this population to be largely distinct from suface IgM+ B cells and T cells, and identical to EA Ripley rosette-forming cells. Approximately 50% of surface IgM+ B cells and approximately 10% of T cells had lower density Fc receptors identified by indirect immunofluorescence with small complexes prepared in antigen excess or by cross-linking fluorescein-conjugated complexes with anti-rabbit IgG anti-serum. An additional approximately 15% peripheral T and B cells had very low density Fc receptors detectable by complexing the IgG on the cell surface by sequential incubations of cells with b4 IgG and anti-b4. Fc receptors on B and T cells were sensitive to both pronase and trypsin digestion. The heterogeneity of IgG Fc receptors on different lymphocyte subpopulations as defined by these these experiments may be of relevance for further analysis of normal and abnormal immune function.     

Selective modulation of two human monocyte Fc receptors for IgG by immobilized immune complexes

Two types of IgG FcR, FcRI and FcRII, are constitutively expressed by human monocytes. FcRI (identified by mAb 32.2) binds human (h) IgG, FcRII (identified by mAb IV.3) has a low affinity for hIgG but interacts strongly with murine (m) IgG1. These receptors can be assayed by using indicator E sensitized by hIgG (EA-hIgG) or mIgG1 (EA-mIgG1), respectively. We further characterized these two FcR by modulation studies by using substrate-immobilized immune complexes containing rabbit IgG, goat IgG, or one of the mouse Ig classes or subclasses. After incubating monocytes in microtiter wells containing such immune complexes, binding of the two types of indicator red cells on the apical surface of the monocytes was quantitated using a photometric assay employing the pseudoperoxidase activity of E. No effect on the binding of sensitized E was observed after incubation of monocytes with immune complexes containing mouse IgE, IgA, or IgM, or F(ab')2 fragments of rabbit IgG. High concentrations of immune complexes containing IgG of mouse, rabbit, or goat, however, were able to induce a decrease in binding of both types of sensitized E, suggestive of modulation of both FcRI and FcRII. At lower concentrations of immune complexes, more selective patterns of modulation emerged. Under these conditions, immune complexes containing mIgG1 or mIgG2b, or, surprisingly, goat IgG induced a selective decrease in the binding of EA-mIgG1 (FcRII modulation), while immune complexes containing mIgG2a or rabbit IgG mainly affected the binding of EA-hIgG (FcRI modulation). By using anti-FcR mAb IV.3, it was confirmed that FcRII was modulated from the apical surface of monocytes after incubation on immune complex coated substrates. Selectivity of FcR-modulation was demonstrated by showing that under these conditions binding of anti-C receptor mAb, and several other anti-monocyte mAb did not decrease.     

Binding characteristics of dimeric IgG subclass complexes to human neutrophils

Immune complexes were prepared by incubation of human IgG paraproteins with F(ab')2 fragments of the mAb K35 against the kappa-L chain of human IgG. The composition of these complexes was analyzed by centrifugation over sucrose gradients, by gel filtration, by RIA with either IgG Sepharose or K35 Sepharose and by double-labeling studies. The results indicated that the complexes consist of saturated tetramers composed of two IgG molecules cross-linked by two F(ab')2 fragments of the mAb. These complexes were used to study the binding of the different IgG subclasses to human neutrophils at 4 degrees C. Human neutrophils bound IgG3 complexes approximately three times faster than IgG1 complexes. Binding of IgG2 or IgG4 dimers to the neutrophils was undetectable. The same number of IgG1 complexes and IgG3 complexes bound to the neutrophils, but considerable inter-donor variation was found (mean number of Fc gamma R per neutrophil: 190,000, range 120,000 to 400,000). The Ka for the binding of IgG1 complexes to neutrophils (median 11 x 10(7) M-1) was lower than the Ka for the binding of IgG3 complexes (median 47 x 10(7) M-1). Competition studies between labeled IgG1 complexes or IgG3 complexes and unlabeled complexes showed that the Fc gamma R of human neutrophils do not display an IgG subclass specificity. Incubation of neutrophils with a mAb against the FcRIII completely blocked the binding of IgG1 complexes and IgG3 complexes. Incubation with a mAb against the FcRII reduced the affinity of the complexes for the neutrophils but had no effect on the maximum number of complexes bound. This indicates that one complex may bind simultaneously to one FcRIII and to one FcRII.     

Comparative studies on FcR (FcRII, FcRIII, and FcR alpha) functions of murine B cells

Distribution of FcR II, FcRIII, and FcR alpha on murine splenic B cells was examined by using FITC-labeled heat-aggregated IgG of each subclass and IgA. Almost 60 to 80% of B cells expressed both FcRII and FcRIII. However, FcR alpha was expressed on only a small proportion (6%) of B cells that co-expressed FcRII. By inhibition assays with the use of cold IgG of each subclass and IgA in addition to anti-FcRII mAb (2.4G2), it was found that IgG1, IgG2a, and IgG2b utilized the same receptor (FcRII), whereas IgG3 and IgA bound only to their unique receptors, FcRIII and FcR alpha, respectively. Immune complexes IC prepared by IgG1, IgG2a, IgG2b, and IgA anti-TNP mAb with TNP-coupled SRBC inhibited the polyclonal Ig secretion and proliferative responses of B cells stimulated with either IL-4 or LPS. The inhibition of B cell activation was associated with the blockade of the membrane depolarization. Moreover, IC prepared by these antibodies caused production of suppressive B cell factor (SBF) as is the case with rabbit IgG antibody to SRBC, and SBF thus prepared regulated antibody responses in an isotype-nonspecific manner. In contrast, no inhibition for these responses or production of SBF was attained by the IC of IgG3 antibody. We concluded that FcRII and FcR alpha mediates a suppressive signal for B cells by acting on the initial step of activation, whereas FcRIII lacks this activity.     

Modulation of Fc gamma receptors on the human macrophage cell line U-937

Macrophage receptors for the Fc portion of IgG play an important role in host defense, inflammation, and the pathophysiology of autoimmune disorders. We studied one important function of Fc gamma receptors--the ability to bind IgG ligand. Direct binding experiments analyzed by nonlinear regression were consistent with monomeric and trimeric IgG binding to a single class of receptors. Indirect binding experiments were also consistent with this interpretation and revealed that both IgG ligands completely inhibited the binding of the other. In addition, we used an anti-Fc gamma RII monoclonal antibody known to compete for the Fc gamma RII ligand binding site and known to inhibit IgG trimer binding to other cells. At concentrations of antibody which saturated all Fc gamma RII sites, no inhibition of IgG trimer binding to U-937 was observed. This was evident despite the observation that the numbers of Fc gamma RI and Fc gamma RII, determined by equilibrium binding of monomeric IgG and anti-Fc gamma RII antibody, respectively, were similar on U-937. Monoclonal antibodies were used to compare the expression and modulation of Fc gamma receptor proteins with their ability to bind monomeric and trimeric IgG ligands. Dexamethasone and gamma-interferon regulated U-937 Fc gamma RI protein expression and IgG ligand binding to a similar degree. In contrast, the expression of Fc gamma RII was not altered by dexamethasone. Interferon-gamma primarily stimulated Fc gamma RI, as determined both by reactivity with monoclonal antibody (227 +/- 26%) and by monomeric IgG ligand binding (350 +/- 151%). In addition, dexamethasone inhibited by 33% the gamma-interferon effect on Fc gamma RI protein and by 56% the effect on Fc gamma RI binding of monomeric IgG. Preincubation of U-937 with anti-Fc gamma RII antibody did not alter the effect of dexamethasone or gamma-interferon on IgG trimer binding. These data indicate that on U-937 cells Fc gamma RII does not function in the recognition of small molecular weight immune complexes and that Fc gamma RI is the Fc gamma receptor responsible for the binding of both monomeric and trimeric human IgG. Furthermore, Fc gamma RI is the major Fc gamma receptor on U-937 that is modulated by both gamma-interferon and glucocorticoids.     

Human T cell activation induced by a monoclonal mouse IgG3 anti-CD3 antibody (RIV9) requires binding of the Fc part of the antibody to the monocytic 72-kDa high-affinity Fc receptor (FcRI)

The mitogenic activity of anti-CD3 mouse monoclonal antibodies (mAb) in cultures of human peripheral blood mononuclear cells (PBMC) depends on the ability of the mAb to interact with CD3 molecules on the T cells, and with Fc receptors (FcR) on monocytes. Two types of FcR with distinct specificity for murine (m) IgG subclasses are involved: a 72-kDa receptor (FcRI) binds mIgG2a and a 40-kDa receptor (FcRII) binds mIgG1. In this study we examined the mitogenic activity of mIgG3 anti-CD3 mAb RIV9. In cultures of human PBMC, the mAb induced T cell proliferation and interleukin 2 production. We found that subjects, unresponsive to mIgG2a anti-CD3 (e.g., OKT3), were also RIV9 nonresponders. In contrast, nonresponders to mIgG1 anti-CD3 (e.g., anti-Leu4) had a normal response to RIV9. Our results therefore suggested that anti-CD3 mAb of the mIgG2a and mIgG3 subclass bind to the same monocytic FcR. Human monomeric IgG, which has been shown to bind to FcRI only, blocked T cell proliferation induced by mIgG2a and mIgG3 anti-CD3, but had no effect on T cell proliferation induced by mIgG1 anti-CD3. In contrast, a mAb (IV.3) to FcRII, which blocks ligand binding of the receptor, blocked the mitogenic activity of mIgG1 anti-CD3 antibodies, but had no effect on T cell proliferation induced by mIgG3 anti-CD3 or by mIgG2a anti-CD3. Binding of RIV9 to FcR of responder monocytes could be demonstrated in immunofluorescence. Monocytes from the RIV9 nonresponder subjects however were unable to bind the Fc portion of this antibody. The binding of fluorescein (FITC)-conjugated mIgG3 or FITC-conjugated mIgG2a to responder monocytes could be inhibited by human monomeric IgG and by mIgG2a and mIgG3, but not by the mAb to FcRII. The results demonstrate that mIgG3 binds to FcRI on human monocytes and that this binding is needed for the mitogenic activity of mIgG3 anti-CD3.     

Aglycosylation of human IgG1 and IgG3 monoclonal antibodies can eliminate recognition by human cells expressing Fc gamma RI and/or Fc gamma RII receptors.

Aglycosylated human IgG1 and IgG3 monoclonal anti-D (Rh) and human IgG1 and IgG3 chimaeric anti-5-iodo-4-hydroxy-3-nitrophenacetyl (anti-NIP) monoclonal antibodies produced in the presence of tunicamycin have been compared with the native glycosylated proteins with respect to recognition by human Fc gamma RI and/or Fc gamma RII receptors on U937, Daudi or K562 cells. Human red cells sensitized with glycosylated IgG3 form rosettes via Fc gamma RI with 60% of U937 cells. Inhibition of rosette formation required greater than 35-fold concentrated more aglycosylated than glycosylated human monoclonal anti-D (Rh) antibody. Unlabelled polyclonal human IgG and glycosylated monoclonal IgG1 and anti-D (Rh) antibody inhibited the binding of 125I-labelled monomeric human IgG binding by U937 Fc gamma RI at concentrations greater than 50-fold lower than the aglycosylated monoclonal IgG1 anti-D (Rh) (K50 approximately 3 x 10(-9) M and approximately 6 x 10(-7) M respectively). Similar results were obtained using glycosylated and aglycosylated monoclonal human IgG1 or IgG3 chimaeric anti-NIP antibody-sensitized red cells rosetting with Fc gamma RI-/Fc gamma RII+ Daudi and K562 cells. Rosette formation could be inhibited by the glycosylated form (at greater than 10(-6) M) but not by the aglycosylated form. Haemagglutination analysis using a panel of murine monoclonal antibodies specific for epitopes located on C gamma 2, C gamma 3 or C gamma 2/C gamma 3 interface regions did not demonstrate differences in Fc conformation between the glycosylated or aglycosylated human monoclonal antibodies. These data suggest that the Fc gamma RI and Fc gamma RII sites on human IgG are highly conformation-dependent and that the carbohydrate moiety serves to stabilize the Fc structure rather than interacting directly with Fc receptors.     

Mast cell membrane antigens and Fc receptors in anaphylaxis: II. Functionally distinct receptors for IgG and for IgE on mouse mast cells

The present work was aimed at analyzing the functional relationships between mouse mast cell receptors for IgG and IgE antibodies. It was based on a study of the inhibition of IgG1-and IgE-induced passive mast cell degranulation produced by various immunoglobulin preparations capable of interfering with Fc receptors. Rat myeloma IgE, a high-affinity ligand for IgE receptors, was used to search for a possible participation of IgE receptors in IgG1-dependent degranulation. Mouse myeloma IgG, which inhibited only weakly IgG1-mediated reactions, had no chance to compete successfully with high-affinity IgE antibodies, but aggregated HGG was found to behave as a high-affinity ligand for IgG receptors. This enabled us to search for a possible participation of IgG receptors in IgE-dependent degranulation. The results show that rat myeloma IgE and aggregated HGG specifically inhibited IgE-induced and IgG1-induced reactions, respectively, but failed to inhibit reactions not requiring free Fc receptors. The conclusion was that receptors for IgG and for IgE are functionally independent on mouse mast cells, and are both expressed on the same cells.     

Two distinct classes of IgG Fc receptors on a human monocyte line (U937) defined by differences in binding of murine IgG subclasses at low ionic strength

We have defined two distinct classes of IgG Fc receptors (FcR) on cells of a human monocytic line (U937) by analyzing the direct binding of murine IgG subclasses in medium of low ionic strength. Four lines of evidence support this contention. The binding of aggregated murine IgG2b (AggmIgG2b) to U937 and Daudi cells was enhanced at low ionic strength, whereas monomeric murine IgG2a (mIgG2a) did not bind to Daudi cells and its high affinity binding to U937 cells was unaffected by changes in ionic strength. Double reciprocal inhibition experiments with U937 cells indicated that the binding of both ligands was inhibited 30 to 135 times more efficiently by the homologous ligand than by the heterologous one. That is, the binding of 125I-AggmIgG2b was inhibited 50% by 3.5 micrograms/ml of AggmIgG2b and 100 micrograms/ml of mIgG2a. Similarly, the binding of 125I-mIgG2a was inhibited 50% by 2.5 micrograms/ml of mIgG2a and only 44% by 243 micrograms/ml of AggmIgG2b. A monoclonal antibody of the IgG2b subclass raised against an IgG FcR on K562 cells inhibited binding to U937 cells of AggmIgG2b but not of mIgG2a. Trypsinization of U937 cells abrogated by 32% the binding of mIgG2a but did not affect the binding of AggmIgG2b. Human IgG inhibited binding of both AggmIgG2b and mIgG2a to U937 cells. We propose that the newly recognized FcR that binds AggmIgG2b is the human homologue of the murine macrophage IgG2b/1 FcR (FcRII), and that the previously described 72,000 dalton high-affinity FcR on U937 cells that binds mIgG2a is the human equivalent of the murine macrophage IgG2a FcR (FcRI).     

Introduction of purified hexosaminidase A into Tay-Sachs leukocytes by means of immunoglobulin-coated liposomes.

To determine whether ligand-receptor interactions could engender the selective uptake by deficient cells of enzyme-laden liposomes, aggregated human IgG was used to coat liposomes which had previously trapped purified hexosaminidase A (Hex A). By a new, high-yield procedure, Hex A was purified 7000-fold from human placenta: the homogeneous protein had a pI of 5.4, permitting nonelectrostatic trapping in the aqueous interstices of anionic multilamellar liposomes (molar ratios of phosphatidyl-choline-dicetyl phosphate-cholesterol, 7:2:1). Trapped Hex A was separated from free enzyme by means of Sephadex G-200 chromatography: 1.3 +/- 0.3 mUnits of Hex A/mumol of phospholipid became associated with liposomes and trapped glucose, utilized as a marker of the aqueous compartment. Once sequestered, the enzyme remained latent until lamellae were disrupted by Triton X-100. Presence of enzyme in aqueous compartments was proved by the demonstration of increased trapping (0.02-1.33 mUnits/mumol of phospholipid) with increments in like-sign repulsion of the bilayers produced by increasing molar ratios of anionic dicetyl phosphate (5-20%). To provide for ligand-receptor interaction with surface Fc receptors of human polymorphonuclear leukocytes (PMN's), liposomes were coated by heat-aggregated (62 degrees C, 10 min) human IgG. PMN's from Tay-Sachs patients genetically deficient in Hex A activity readily incorporated exogenous Hex A provided in this fashion. PMN's exposed to enzyme-laden liposomes coated with aggregated IgG incorporated significantly more Hex A than when the enzyme was presented in uncoated liposomes or in liposomes coated with native IgG, which engages Fc receptors with less avidity. Free enzyme was not endocytized. Acquisition of specific Hex A isozyme activity by cells (determined by DEAE-cellulose chromatography) was not due to surface adsorption since cytochalasin B, which prevents phagocytosis but not surface adherence; blocked uptake. Incorporation of the isozyme by deficient cells was also demonstrated by starch gel electrophoresis, and ultrastructural studies showed that the immunoglobulin-coated, Hex A-containing liposomes were taken up into PMN lysosomes after membrane fusion. The studies indicate that liposomes coated with surface ligands may be used to introduce enzyme or other materials into deficient cells possessing appropriate surface receptors.     

Studies on the Fc gamma receptor of the murine macrophage-like cell line P388D1. II. Binding of human IgG subclass proteins and their proteolytic fragments.

Binding studies of human IgG proteins to murine P388D1 cells indicated that they bind to an apparently homogeneous Fc receptor population. The association constant was 0.89 x 10(6)M-1 at 22 degrees C and was comparable to the binding affinities of homologous murine IgG2a and IgG2b. The number of receptor sites was found to be approximately 6 x 10(5)/cell. Fc gamma 1 and Fc gamma 3 fragments bound with an affinity comparable to that of the parent proteins. The P388D1 receptors could discriminate between the human IgG subclasses; the relative cytophilic activity was IgG3 greater than IgG1 greater than IgG4 and IgG2 was devoid of binding activity. Fragments corresponding to the C gamma 2 and C gamma 3 domains of human IgG1 were both unable to bind to the P388D1 receptors either alone or in equimolar combination. This suggests that the cytophilic site may be formed cooperatively by interaction between the two domains. The integrity of the hinge region appeared to be essential for full expression of cytophilic activity since reduction of the hinge-region disulfides in both human IgG1 and its Fc fragment markedly decreased their binding affinity. In addition, a mutant IgG1 molecule lacking the hinge region was significantly less cytophilic than its normal counterpart.     

Human IgG Fc receptor (hFcRII; CD32) exists as multiple isoforms in macrophages, lymphocytes and IgG-transporting placental epithelium.

We previously isolated cDNA clones from a human monocyte library that encoded one member of a family of low-affinity surface receptors for the Fc domain of IgG (hFcRII-A). To investigate possible structural and functional heterogeneity among these receptors, we have now isolated two additional cDNAs (hFcRII-B and hFcRII-C) from a human placental library, placenta being a good source of FcR-bearing macrophages and epithelial cells. Three cDNAs encoded related but distinct transmembrane glycoproteins containing two immunoglobulin-like domains; however, transfected cells produced receptors that were indistinguishable on the basis of ligand binding or reactivity with anti-hFcRII monoclonal antibodies. The sequences of hFcRII-A and -B were most closely related and were identical except for several amino acid substitutions and one small internal deletion. While the ectodomain of hFcRII-C was identical to hFcRII-B, its cytoplasmic tail was unrelated but highly homologous to the corresponding domain of the receptor isoform (mFcRII-B2) found in murine macrophages. Thus, human FcRII may be derived from at least two alternatively spliced genes. Northern blots revealed little difference in the pattern of expression of hFcRII isoforms among various myeloid and lymphoid cells or cell lines. However, the blots--as well as in situ hybridization and immunohistochemistry--demonstrated that hFcRII-C (along with a second monocyte marker, the c-fms encoded CSF-1 receptor) was expressed in placental syncytiotrophoblasts. Since syncytiotrophoblasts comprise the IgG-transporting epithelium of the placental villus, these findings suggest that FcR found in the immune system and in certain epithelia may be structurally or functionally related.     

Internalization and degradation of macrophage Fc receptors during receptor-mediated phagocytosis

Macrophage receptors for the Fc domain of immunoglobulin G (IgG) can mediate the efficient binding and phagocytosis of IgG-coated particles. After internalization, phagocytic vacuoles fuse with lysosomes, initiating the degradation of their contents. Using specific monoclonal and polyclonal antireceptor antibodies, we have now analyzed the internalization and fate of Fc receptors during the uptake of IgG- coated erythrocytes and erythrocyte ghosts by mouse peritoneal macrophages. Receptor-mediated phagocytosis led to the selective and largely irreversible removal of Fc receptors (greater than 50%) from the macrophage plasma membrane. The expression of several other plasma membrane proteins (including a receptor for complement), recognized by a series of antimacrophage monoclonal antibodies, was affected only slightly. Interiorized Fc receptors were rapidly and selectively degraded. This was demonstrated by a series of turnover studies in which Fc receptor was immunoprecipitated from lysates of 125I-labeled macrophages. These experiments were made possible by the development of a polyclonal rabbit antiserum, raised against isolated Fc receptor, which recognized the receptor even in the presence of bound ligand. In control cells, the receptor turned over with a t1/2 of approximately 10 h; after phagocytosis, greater than 50% of the receptors were degraded with a t1/2 of less than 2 h. The turnover of other unrelated plasma membrane proteins was unaffected (t1/2 of 18-23 h) under these conditions.     

Evidence for the sorting of endocytic vesicle contents during the receptor-mediated transport of IgG across the newborn rat intestine

Fc receptors on the luminal membranes of intestinal epithelial cells in the neonatal rat mediate the vesicular transfer of functionally intact IgG from the intestinal lumen to the circulation. In addition, there is a low level of nonselective protein uptake, but in this case transfer does not occur. To determine whether a specialized class of endocytic vesicles could account for the selective transfer of IgG, mixtures of IgG conjugated to ferritin (IgG-Ft) and unconjugated horseradish peroxidase (HRP) were injected together into the proximal intestine of 10-d-old rats, and the cellular distribution of these two different tracers was determined by electron microscopy. Virtually all apical endocytic vesicles contained both tracers, indicating simultaneous uptake of both proteins within the same vesicle. However, only IgG-Ft bound to the apical plasma membrane, appeared within coated vesicles at the lateral cell surface, and was released from cells. HRP did not bind to the luminal membrane and was not transferred across cells but was confined to apical lysosomes as identified by acid phosphatase and aryl sulfatase activities. To test the possibility that the binding of IgG to its receptor stimulated endocytosis, HRP was used as a fluid volume tracer, and the amount of HRP taken up by cells in the presence and absence of IgG was measured morphologically and biochemically. The results demonstrate that endocytosis in these cells is constitutive and occurs at the same level in the absence of IgG. The evidence presented indicates that the principal selective mechanism for IgG transfer is the binding of IgG to its receptor during endocytosis. Continued binding to vesicle membranes appears to be required for successful transfer because unbound proteins are removed from the transport pathway before exocytosis. These results favor the proposal that IgG is transferred across cells as an IgG-receptor complex.     

The human low affinity Fcgamma receptors IIa, IIb, and III bind IgG with fast kinetics and distinct thermodynamic properties.

Fcgamma receptors (FcgammaRs) are expressed on all immunologically active cells. They bind the Fc portion of IgG, thereby triggering a range of immunological functions. We have used surface plasmon resonance to analyze the kinetic and thermodynamic properties of the interactions between the ectodomains of human low affinity FcgammaRs (FcgammaRIIa, FcgammaRIIb, and FcgammaRIIIb-NA2) and IgG1 or the Fc fragment of IgG1. All three receptors bind Fc or IgG with similarly low affinities (K(D) approximately 0.6-2.5 microm) and fast kinetics, suggesting that FcgammaR-mediated recognition of aggregated IgG and IgG-coated particles or cells is mechanistically similar to cell-cell recognition. Interestingly, the Fc receptors exhibit distinct thermodynamic properties. Whereas the binding of the FcgammaRIIa and FcgammaRIIb to Fc is driven by favorable entropic and enthalpic changes, the binding of FcgammaRIII is characterized by highly unfavorable entropic changes. Although the structural bases for these differences remain to be determined, they suggest that the molecular events coupled to the binding differ among the low affinity FcgammaRs.     

The mononuclear cell in human blood which mediates antibody-dependent cellular cytotoxicity to virus-infected target cells. II. Identification as a K cell.

Studies were carried out to determine whether the mononuclear cell in human blood which mediates antibody-dependent cellular cytotoxicity (ADCC) to herpes simplex virus (HSV)-infected target cells has surface Fc receptors which participate in the reaction. The F (ab')2 fragment of human IgG antibody was inactive both in ADCC and in complement-mediated cytolysis, but retained the capacity to neutralize infectious virus, to agglutinate erythrocytes coated with viral antigens, and to bind to the surface of virus-infected cells. Treatment of sensitized virus-infected target cells with staphylococcus protein A, which has affinity for the Fc epitope of IgG, strongly reduced their susceptibility to lysis by ADCC in a dose-dependent relationship. These findings indicate that the Fc portion of IgG antibody to the virus is necessary for cytotoxicity. Treatment of blood mononuclear cells with either heat-aggregated gamma-globulin or HSV immune complexes inhibited effector cell activity. The presence of "third party" cellular immune complexes also strongly inhibited ADCC. Adsorption of mononuclear cells to plastic surfaces coated with soluble third party immune complexes resulted in a significant reduction in effector cell activity. These findings demonstrate that the ADCC effector cell possesses surface Fc receptors which are utilized in the ADCC reaction. The presence of Fc receptors on the surface of the effector cell indicates that it is a K cell rather than a null cell.     

A novel Fc gamma R-defined, IgG-containing organelle in placental endothelium

Placental transfer of IgG from maternal circulation to that of the fetus is crucial for fetal and newborn immunity. This process requires that IgG broach two cellular layers of the placenta. IgG transport across the first layer, the syncytiotrophoblast, is almost certainly mediated by the MHC-related FcR for IgG, FcRn. The second layer, the villus endothelium, was until recently thought to allow IgG movement nonspecifically by constitutive transcytosis in caveolae. However, we recently showed that villus endothelium expressed a separate FcR for IgG, the inhibitory motif-bearing Fc gammaRIIb2 seen most notably on macrophages and as a minor fraction of the Fc gammaRIIb expressed on B cells. Now, by quantitative microscopy, we find Fc gammaRIIb2 to be expressed abundantly in an unidentifiable and likely novel organelle of the villus endothelium, unassociated with caveolae. About half of these Fc gammaRIIb2 organelles contain IgG; the remainder lack IgG. The majority fraction (approximately 80%) of IgG-containing organelles is associated with Fc gammaRIIb. No IgG-containing organelles are associated with caveolin. These findings are compatible with Fc gammaRIIb-mediated transfer of IgG across the villus endothelium, independent of caveolae.