Binding sites for Fc gamma receptors on immunoglobulin G and factors influencing their expression

The Fab portion of immunoglobulin G contributes to its binding to Fcγ receptor III

Most cells active in the immune system express receptors for antibodies which mediate a variety of defensive mechanisms. These receptors interact with the Fc portion of the antibody and are therefore collectively called Fc receptors. Here, using high-speed atomic force microscopy, we observe interactions of human, humanized, and mouse/human-chimeric immunoglobulin G1 (IgG1) antibodies and their cognate Fc receptor, FcγRIIIa. Our results demonstrate that not only Fc but also Fab positively contributes to the interaction with the receptor. Furthermore, hydrogen/deuterium exchange mass spectrometric analysis reveals that the Fab portion of IgG1 is directly involved in its interaction with FcγRIIIa, in addition to the canonical Fc-mediated interaction. By targeting the previously unidentified receptor-interaction sites in IgG-Fab, our findings could inspire therapeutic antibody engineering.

Dynamic Views of the Fc Region of Immunoglobulin G Provided by Experimental and Computational Observations

The Fc portion of immunoglobulin G (IgG) is a horseshoe-shaped homodimer, which interacts with various effector proteins, including Fcγ receptors (FcγRs). These interactions are critically dependent on the pair of N-glycans packed between the two C_H2 domains. Fucosylation of these N-glycans negatively affects human IgG1-FcγRIIIa interaction. The IgG1-Fc crystal structures mostly exhibit asymmetric quaternary conformations with divergent orientations of C_H2 with respect to C_H3. We aimed to provide dynamic views of IgG1-Fc by performing long-timescale molecular dynamics (MD) simulations, which were experimentally validated by small-angle X-ray scattering and nuclear magnetic resonance spectroscopy. Our simulation results indicated that the dynamic conformational ensembles of Fc encompass most of the previously reported crystal structures determined in both free and complex forms, although the major Fc conformers in solution exhibited almost symmetric, stouter quaternary structures, unlike the crystal structures. Furthermore, the MD simulations suggested that the N-glycans restrict the motional freedom of C_H2 and endow quaternary-structure plasticity through multiple intramolecular interaction networks. Moreover, the fucosylation of these N-glycans restricts the conformational freedom of the proximal tyrosine residue of functional importance, thereby precluding its interaction with FcγRIIIa. The dynamic views of Fc will provide opportunities to control the IgG interactions for developing therapeutic antibodies.

The thioredoxin system of Helicobacter pylori

This paper describes the purification of thioredoxin reductase (TR) and the characterization, purification, and cloning of thioredoxin (Trx) from Helicobacter pylori. Purification, amino acid sequence analysis, and molecular cloning of the gene encoding thioredoxin revealed that it is a 12-kDa protein which possesses the conserved redox active motif CGPC. The gene encoding Trx was amplified by polymerase chain reaction and inserted into a pET expression vector and used to transform Escherichia coli. Trx was overexpressed by induction with isopropyl-1-thio-beta-D-galactopyranoside as a decahistidine fusion protein and was recovered from the cytoplasm as a soluble and active protein. The redox activity of this protein was characterized using several mammalian proteins of different architecture but all containing disulfide bonds. H. pylori thioredoxin efficiently reduced insulin, human immunoglobulins (IgG/IgA/sIgA), and soluble mucin. Subcellular fractionation analysis of H. pylori revealed that thioredoxin was associated largely with the cytoplasm and inner membrane fractions of the cell in addition to being recovered in the phosphate-buffered saline-soluble fraction of freshly harvested cells. H. pylori TR was purified to homogeneity by chromatography on DEAE-52, Cibacron blue 3GA, and 2',5'-ADP-agarose. Gel filtration revealed that the native TR had a molecular mass of 70 kDa which represented a homodimer composed of two 35-kDa subunits, as determined by SDS-polyacrylamide gel electrophoresis. H. pylori TR (NADPH-dependent) efficiently catalyzed the reduction of 5,5'-dithiobis(nitrobenzoic acid) in the presence of either native or recombinant H. pylori Trx. H. pylori Trx behaved also as a stress response element as broth grown bacteria secreted Trx in response to chemical, biological, and environmental stresses. These observations suggest that Trx may conceivably assist H. pylori in the process of colonization by inducing focal disruption of the oligomeric structure of mucin while rendering host antibody inactive through catalytic reduction.

Effects of limited reduction on disulfide bonds in human IgA1 and IgA1 fragments

Human IgA occurs in body fluids as monomers, dimers and secretory IgA (sIgA). Besides the cysteine residues in intra-domain, inter-chain and inter-subunit disulfide bonds IgA molecules contain several cysteine residues with unknown function and reactivity. Limited reductions on serum IgA1 and secretory IgA1 with glutathione revealed that four cysteine residues per monomer or subunit were part of labile bonds. Six cysteine residues were reduced in F(ab')2 fragments and about three in Fc fragments, but none in Fab fragments, indicating that the labile bonds occur in the Fc fragment. By SDS-PAGE analyses of reduced proteins labile inter-alpha chain bond(s) were detected in F(ab')2 and F(abc)2 fragments but not in Fc fragments and intact IgA1, thus showing the importance of the CH3 domains for the structural stability of the hinge region. Nine cysteine residues per IgA1 were reduced with 0.01 M DTT and a large proportion of the IgA1 myeloma proteins formed half-molecules consisting of an alpha- and a light chain, but sIgA1 remained intact. This indicates a relative stability of heavy to light chain and inter-subunit bonds. Reductions in the presence of 2% SDS disrupted several intra-chain bonds. Binding studies with (CH2)2-specific monoclonal antibodies, which detect an epitope expressed only on IgA molecules with disulfide linked alpha chains, were in accordance with the SDS-PAGE results. A new model for the location of labile and more stable disulfide bonds is discussed.

Regulation of antibody production mediated by Fc gamma receptors, IgG binding factors, and IgG Fc-binding autoantibodies

Fc receptors (FcRs) are immunoglobulin-binding structures that enable antibodies to perform a variety of functions by forming connections between specific recognition and effector cells. Besides eliciting cytotoxicity, inducing secretion of mediators and endocytosis of opsonized particles, FcRs are involved in the regulation of antibody production, both as integral membrane proteins and as soluble molecules released from the cell surface. Most FcRs belong to the same family of proteins as their ligands (immunoglobulin superfamily). This review contains recent data obtained by use of monoclonal antibodies and cloning studies on FcRs and FcR-like molecules. The importance of fine specificity of receptor binding site(s)--that of the conformation of FcRs and their ligands in triggering signaling mechanisms--is analyzed. The regulatory function of membrane-bound and -released FcRs; the correlation between cell cycle, FcR expression, and release; as well as the possible mechanisms of these phenomena are discussed.

Co-operation between the pair of C gamma 2 domains in Clq-binding by rabbit IgG

The single site binding constants of rabbit IgG and its plasmin-derived fragments F(acb)2, Facb and F(ab)2 for human C1q were measured by the sedimentation velocity method. The intact IgG and F(acb)2 having the paired C gamma 2 domains gave an identical association constant at 20 degrees C (Ka) of 3.02 X 10(4) M-1 in the presence of a physiological concn of salt and on the basis of six sites per C1q. The C1q-binding affinity was found to be decreased to 1.04 X 10(4) M-1 in the reduced, monomerized fragment Facb. Under the same conditions F(ab)2, which is completely unable to activate the classical complement cascade, gave an apparent C1q-affinity of 0.36 X 10(4) M-1. The results, together with previous observations, led us to the conclusion that the C1q-binding site of rabbit IgG is constituted associatively by the pair of C gamma 2 domains, each of which providing a limited, complementary part of the binding free energy between IgG and C1q.

CH2 and CH3 domain deleted IgG1 paraproteins inhibit differently Fc receptor mediated binding and cytolysis

Domain deleted paraproteins are suitable tools to study the interaction between IgG domains and Fc receptor (FcR) binding sites. The effect of the C gamma 2 or C gamma 3 domain deleted paraproteins was compared on antibody dependent cellular cytotoxicity (ADCC) and on FcR mediated rosette formation. The C gamma 2 domain deleted paraprotein (TIM) had no significant effect on lymphocyte or monocyte mediated ADCC, while the C gamma 3 domain deleted paraprotein (SIZ) inhibited both types of cytotoxicity. FcR dependent rosette formation was also inhibited by SIZ but TIM was ineffective. The data further confirm our previous results suggesting a significant role of C gamma 2 domain in the transfer of killing signal in ADCC and that of C gamma 3 domain in the high affinity binding to lymphocyte FcR.

Isolation and partial characterization of a fragment corresponding to the dimeric form of the CH2 domain of rabbit IgG

A fragment corresponding to the intact dimeric form of the CH2 domain of rabbit IgG, including the hinge region disulfide linkage, was obtained by plasmin digestion of crystalline Fc derived from IgG by the action of papain. Identification and assessment of purity of the fragment was established by SDS-PAGE, amino acid composition analysis, N-terminus sequence and C-terminus amino acid analysis and SDS-urea-PAGE of the reduced fragment. The fragment retains serologic reactivity with anti-Fc specific antisera. Comparison of deglycosylation by endoglycosidase F indicates a more open special relationship between the two CH2 domains in the fragment than in Fc.

Modulation of IgG effector functions by a monovalent fragment of staphylococcal protein A

The monovalent V-1 fragment of protein A (fSpA) with a mol. wt of 13,000 obtained from an u.v. mutant of Staphylococcus aureus Cowan I strain was proved to be able to modulate significantly some of the effector functions of IgG, such as complement fixation, catabolism, attachment to Fc receptors and antibody-dependent cell-mediated cytotoxicity. Moreover fSpA-like protein A obtained from the A676 strain is mitogenic and enhances NK activity of human peripheral lymphocytes. The efficiency of fSpA was found to be lower than that of protein A with regard to its ability to inhibit complement fixation, EA rosette formation and antibody-dependent cell-mediated cytotoxicity. Both protein A and fSpA had the same efficiency in activation of the complement system after reaction with human or guinea pig IgG, and in increasing the IgG catabolism. Unlike fSpA the monovalent B fragment of protein A (with mol. wt of 7000) was not able to inhibit EA rosette formation and antibody-dependent cell-mediated cytotoxicity. The results recommend fSpA, substituting for protein A, as a molecular probe for the investigation of IgG antibody and lymphocyte effector functions.

Localisation of the monocyte-binding region on human immunoglobulin G

Earlier studies, which provided indirect evidence for the involvement of the C gamma 2 domain of human immunoglobulin G (IgG) in human immunoglobulin G (IgG) in human monocyte binding, have been extended to further localise the site of interaction on human IgG. A number of IgGs from several different species and fragments of human IgGs were assayed for ability to inhibit the interaction of radio-labelled human IgG and the human monocyte. By comparison of the amino-acid sequences of those IgGs found to exhibit relatively tight, intermediate or weak binding to human monocyte Fc receptors we are able to postulate a possible monocyte-binding site on human IgG. In addition, the results have implications for the applicability of monoclonal antibodies and antisera when used in the presence of human monocytes and possibly macrophages.

Co-operative interaction of subcomponents of the first component of complement with IgG: a functional defect of dimeric Facb from rabbit IgG

By following dissociation kinetics of radiolabelled C1q from rabbit IgG antibody-sensitized sheep red blood cells (SRBC) before and after its incorporation in the C1 complex, it was demonstrated that the binding stability is markedly enhanced by the presence of the C1r2-C1s2 subunit of C1 which by itself exhibits no significant binding capacity to immune complexes. The dissociation of C1q was decreased by up to 95%, the extent of decrease being pronounced as the cell surface IgG antibody density increased. However, such a stabilizing effect of C1r2-C1s2 was largely abolished when SRBC sensitized with the dimeric fragment F(acb)2 lacking C gamma 3 was used as the C1 binder, whereas the dissociation rate of uncomplexed C1q from F(acb)2-sensitized cells was similar to that from whole IgG-sensitized cells. It was also shown that, although the C1r2-C1s2 subunit is dissociated selectively from C1 bound to either IgG- or F(acb)2-sensitized cells in the presence of EDTA, it is held on much longer by the former cells than the latter cells. These results were taken to indicate that, although the C1 fixation by immune complexes of IgG is undertaken primarily by the interaction between C1q and the C gamma 2 domain, it is also strengthened by the secondary interaction between the C1r2-C1s2 subunit of C1 and the C gamma 3 domain or a structure which is dependent on the pair of C gamma 3 domains.

Mapping the functional topography of Fc gamma with monoclonal antibodies: localization of epitopes interacting with the binding sites of Fc receptor on human K cells

A panel of monoclonal antibodies (mAb) specific for the C gamma 2, C gamma 3 or inter C gamma 2/C gamma 3 domain epitopes was tested for inhibition of antibody-dependent cellular cytotoxicity (ADCC) specific for anti-D IgG-coated erythrocytes. Significant inhibition of ADCC was demonstrable for some antibodies having specificity for C gamma 2 or C gamma 3 domain epitopes, while others gave no inhibition. Fab fragments of a representative C gamma 2-specific antibody (A55) and C gamma 3-specific antibody (x3a8) retained their inhibitory capacity in lymphocyte-mediated ADCC, but only A55 Fab inhibited monocyte-mediated lysis. Furthermore, the Fab portion of A55 completely abolished the complement-dependent enhancement of ADCC mediated by concanavalin A-stimulated cells, while x3a8 Fab had no effect in this system. On the other hand, x3a8 Fab inhibited the binding of anti-D IgG-sensitized erythrocytes to lymphocytes while A55 Fab did not influence this latter interaction. The results suggest that C gamma 2 domain-FcR interaction is essential for the triggering of lytic process both in lymphocyte and in monocyte-mediated ADCC, while C gamma 3 domain has no role in the latter but is responsible for the appropriate contact between effector lymphocytes and target cells. A site in the region of Lys274 appears to be critical for triggering of both lymphocyte and monocyte-mediated ADCC.

Fc receptor--more answers, more questions

Fc receptors, belonging to the most important surface structures of a number of cells participating in the immune processes, have been intensely studied during the past decade. The present review summarizes the contemporary knowledge of the specificity and heterogeneity of Fc receptors and of factors influencing their expression, and includes some views on their function. In addition, it mentions their relationship to other cell surface structures, expression of Fc receptors during ontogeny of the organism and in certain diseases. Finally, data concerning the isolation and biochemical characterization of the Fc receptor molecule are presented.

The monocyte binding domain(s) on human immunoglobulin G

Monocyte binding has previously been assigned to the C gamma 3 domain of human immunoglobulin G (IgG) largely on the ability of the pFc' fragment to inhibit the monocyte-IgG interaction. This ability is markedly reduced compared to the intact parent IgG. We find this result with a conventional pFc' preparation but this preparation is found to contain trace contamination of parent IgG as demonstrated by reactivity with monoclonal antibodies directed against C gamma 2 domain and light-chain epitopes of human IgG. Extensive immunoaffinity purification of the pFc' preparation removes its inhibitory ability indicating that this originates in the trace contamination of parent IgG (or Fc). Neither of the human IgG1 paraproteins TIM, lacking the C gamma 2 domain, or SIZ, lacking the C gamma 3 domain, are found to inhibit the monocyte-IgG interaction. The hinge-deleted IgG1 Dob protein shows little or no inhibitory ability. Indirect evidence for the involvement of the C gamma 2 domain in monocyte binding is considered. We suggest finally that the site of interaction is found either on the C gamma 2 domain alone or between the C gamma 2 and C gamma 3 domains.

Differential reduction of the inter-chain disulfide bonds of rat immunoglobulin E: relation to biological activity

Monoclonal rat IgE was reduced over a range of dithiothreitol (DTT) concns. The number of disulfide bonds reduced and their location in the IgE molecule were studied. One millimolar DTT was found to split the two inter-heavy-chain disulfide bonds of the C epsilon 2 domain while increasing DTT concn to 10 mM split the two inter-heavy-light-chain disulfide bridges. Therefore, the sensitivities to reduction of disulfide bonds in rat IgE were found to be the opposite of those in human IgE. In addition, the results indicated the absence, in rat IgE, of the intra-epsilon-chain labile disulfide bond of the C epsilon 1 domain, which is reduced by 2 mM DTT in human IgE. Circular dichroism studies showed significant modifications, mainly of tertiary structure, for rat IgE reduced with 10 mM DTT, but not for IgE reduced with 1 mM DTT. The ability to block passive sensitization with reaginic antibody was not modified when IgE was reduced with 1 mM DTT (which split the two inter-heavy-chain disulfide bonds), but was lost when inter-heavy-light-chain bridges were reduced with 10 mM DTT. In addition, a non-covalent epsilon-chain dimer was found to have the same blocking activity as native IgE (or IgE reduced with 1 mM DTT). Therefore, the results suggest that reduction of most or all the inter-chain disulfide bonds, in rat as in human IgE, induces changes in quaternary structure, more especially in the relationship between the Fab and Fc parts of the molecule, leading to steric blockade, by Fab, of the binding sites for mast cells present on Fc.

Localization of the binding site on IgG for solubilized placental Fc gamma receptor

Placental Fc gamma R (FcR) inhibited the rosette formation between monocytes and rabbit IgG-sensitized erythrocytes (EA), whereas the rosette formation with granulocytes was not impaired. Staphylococcal protein A (SpA) inhibited the rosette formation with both cell types. Results obtained in absorption and agglutination experiments showed that SpA blocked the binding of FcR to IgG, and Cl did not. Furthermore, FcR did not interfere with the binding of SpA to IgG, whereas C1 affected this binding. FcR apparently bind to the C gamma 3 region. Since FcR inhibited the binding of EA to monocytes, the monocyte FcR binding site is probably also located within the C gamma 3 region.

The interaction of immune serum globulin and immune globulin intravenous with complement

The in vitro anticomplementary activity of untreated and heat-aggregated (63 degrees C, 10 min) immune serum globulin (ISG) and immune globulin intravenous (IGIV) prepared by partial reduction and alkylation have been evaluated by three assays, C3 activation, binding to C1q and enhancement of alternative pathway lysis of rabbit erythrocytes. Crossed immunoelectrophoresis was used to quantitatively measure the ability of ISG and IGIV to activate endogenous C3 in normal serum. Binding to C1q was determined according to the ability to inhibit binding of 125I-C1q to solid phase IgG. ISG and IGIV enhancement of lysis of rabbit erythrocytes by normal human serum adsorbed with rabbit erythrocytes in the presence of MgEGTA was used to determine activity in the alternative complement pathway. Unheated IGIV at 10 mg/ml only marginally activated endogenous C3 in normal serum, had about a 5-fold lower affinity for 125I-C1q (Ki = 138 to 356 microM vs Ki = 62.5 microM for ISG), but was very similar in ability to ISG on a weight basis in enhancing complement alternative pathway activity (RCH50 = 0.23 to 0.40 mg for IGIV vs 0.17 mg for ISG). Heat-aggregated IGIV at 5 mg/ml in normal human serum was about 2-fold less effective than heat-aggregated ISG in the activation of C3 in normal serum and had approximately 2- to 3-fold lower affinity in the C1q binding assay (Ki = 45 to 83 nM for heat-aggregated IGIV vs Ki = 14.6 nM for heat-aggregated ISG). These data suggest that IGIV prepared by chemical modification retains sufficient specific receptor activity to allow in vivo efficacy in complement-mediated amplification of host defense reactions, but is safe for intravenous use due to a lower capacity to initiate nonspecific complement activation.

Selective action of D-penicillamine on guinea pig peritoneal macrophage Fc gamma receptors for homologous, monomeric IgG1

Guinea pig oil-induced peritoneal exudates were pretreated with D-penicillamine. The binding of homologous, monomeric IgG2 and IgG1 to normal and pretreated exudates was examined. Whereas the 7S IgG2-IgG2 Fc gamma receptor interaction remains unaffected by the pretreatment, the binding of IgG1 to the IgG Fc gamma receptor population was affected. The significance of the selective effect of D-penicillamine is discussed.

The functions of endogenous C1q, a subcomponent of the first component of complement, as a receptor on the membrane of macrophages

C1q, the Fc-recognizing subcomponent of the first component of complement is synthesized by peritoneal macrophages. During the secretion phase C1q serves as an Fc-binding protein in the membrane of macrophages. The Fc-mediated rosette formation was inhibited in a dose-dependent manner when macrophages were pretreated with anti-C1q F(ab')2, whereas C3b rosette formation was not affected. Furthermore, preincubation of peritoneal macrophages with anti-C1q F(ab')2 abolished, dose- and time-dependently, the polyanion-mediated stimulation of secretion of lysosomal enzymes. Polyanion-induced enzyme release was prevented after incubation of polyanions with highly purified C1q. The inhibition of Fc receptor activity by polyanions (i.e. dextran sulfate, liquoid, polyvinyl sulfate) is completely reversed upon treatment of these macrophages with protamine. These findings are compatible with the hypothesis that C1q produced by macrophages serves in the macrophage membrane as an endogenous receptor for Fc and polyanionic molecules. Thus, C1q mediates cell-bound biological receptor functions before it is released from these cells and is incorporated into the macromolecular C1 complex.