Chimeric Fc receptors identify functional domains of the murine high affinity receptor for IgG.

Chimeric Fc gamma R have been generated between the mouse high affinity receptor for IgG (Fc gamma RI) and the low affinity receptor for IgG (Fc gamma RII) by exchanging the first two domains of the three-domain extracellular structure of Fc gamma RI with the homologous two-domain extracellular structure of Fc gamma RII. Studies of the affinity and specificity of binding of mouse Ig classes to these receptors defined functional regions of Fc gamma RI and showed some surprising results. After removal of the third extracellular domain of Fc gamma RI, the remaining two domains (domains 1 and 2) retained the capacity to bind Ig in the form of immune complexes, however, they bound monomeric IgG2a with a reduced affinity. Surprisingly, these two domains in the absence of the third domain bound not only IgG2a but also IgG1 and IgG2b, i.e., the third domain of Fc gamma RI suppresses the intrinsic capacity of the first two domains to act as a low affinity Fc gamma RII-like molecule. Linking the third extracellular domain of Fc gamma RI to the two extracellular domains of Fc gamma RII resulted in a receptor that retained the specificity and affinity of Fc gamma RII. Thus, the removal of domain 3 from Fc gamma RI resulted in the conversion of Fc gamma RI to an "Fc gamma RII-like" receptor. These findings indicate that domains 1 and 2 of Fc gamma RI form an Ig-binding motif, and although domain 3 is not essential for Fc binding by Fc gamma RI, it plays a crucial role in determining the specific high affinity interaction of Fc gamma RI with IgG2a.     

Human Fc gamma RI and Fc gamma RII interact with distinct but overlapping sites on human IgG.

Cellular receptors for IgG (Fc gamma R) mediate important protective functions. By using site-specific mutants of a chimeric antibody (mouse V H domain and L chain; human IgG3 C H domains), we have demonstrated that human Fc gamma RI interacts with a site in the lower hinge of human IgG (residues 234 to 237) and that this interaction dictates Fc gamma RI-mediated superoxide generation. Mutations at position 235 resulted in the most profound reductions in Fc gamma RI recognition. We have also mapped an interaction site for Fc gamma RII to the same region; however, mutations at position 234 and 237 resulted in the greatest reductions in Fc gamma RII recognition. The two receptors appear to recognize overlapping but nonidentical sites on the lower hinge of IgG. Deviations from the optimal motif 234-Leu-Leu-Gly-Gly-237 may then explain the human IgG subclass specificity profile for human Fc gamma RI and Fc gamma RII.     

IgY: a key isotype in antibody evolution

Immunoglobulin Y (IgY) is central to our understanding of immunoglobulin evolution. It has links to antibodies from the ancestral IgM to the mucosal IgX and IgA, as well as to mammalian serum IgG and IgE. IgY is found in amphibians, birds and reptiles, and as their most abundant serum antibody, is orthologous to mammalian IgG. However, IgY has the same domain architecture as IgM and IgE, lacking a hinge region and comprising four heavy‐chain constant domains. The relationship between IgY and the mucosal antibodies IgX and IgA is discussed herein, in particular the question of how IgA could have contributed to the emergence of IgY. Although IgY does not contain a hinge region, amphibian IgF and duck‐billed platypus IgY/O, which are closely related to IgY, do contain this region, as does mammalian IgG, IgA and IgD. A hinge region must therefore have evolved at least three times independently by convergent evolution. In the absence of three‐dimensional structural information for the complete Fc fragment of chicken IgY (IgY‐Fc), it remains to be discovered whether IgY displays the same conformational properties as IgM and IgE, which exhibit substantial flexibility in their Fc regions. IgY has three characterised Fc receptors, chicken Ig‐like receptor AB1 (CHIR‐AB1), the chicken yolk sac IgY receptor (FcRY) and Gallus gallus Fc receptor (ggFcR). These receptors bind to IgY at sites that are structurally homologous to mammalian counterparts; IgA/FcαRI for CHIR‐AB1, IgG/FcRn for FcRY and IgE/Fc?RI and IgG/FcγR for ggFcR. These resemblances reflect the close evolutionary relationships between IgY and IgA, IgG and IgE. However, the evolutionary distance between birds and mammals allows for the ready generation of IgY antibodies to conserved mammalian proteins for medical and biotechnological applications. Furthermore, the lack of reactivity of IgY with mammalian Fc receptors, and the fact that large quantities of IgY can be made quickly and cheaply in chicken eggs, offers important advantages and considerable potential for IgY in research, diagnostics and therapeutics.     

Recombinant human IgG1-murine IgE chimeric Ig. Construction, expression, and binding to human Fc gamma receptors

We have constructed a set of chimeric Ig by exchanging corresponding H chain C domains between human (hu) IgG1 and murine (m) IgE. We used this set of Ig to dissect the interaction of individual Ig domains with human Fc gamma receptors. Only one of the chimeras, epsilon/C gamma 2,3 (an mIgE with C epsilon 3 and C epsilon 4 replaced by C gamma 2 and C gamma 3 from huIgG1), binds tightly to the human Fc gamma RI on U937 cells. We found that epsilon/C gamma 2,3 has only twofold lower affinity for Fc gamma RI as compared to huIgG1. The gamma/C epsilon 4 (huIgG1 with C epsilon 4 replacing C gamma 3) binds weakly to Fc gamma RI. The other chimeric Ig, epsilon/C gamma 3, epsilon/C gamma 2, and gamma/C epsilon 3, as well as mIgE do not bind detectably to Fc gamma RI. From these data we conclude that the C gamma 2 domain is crucial for binding and contains the majority of the binding site for Fc gamma RI on IgG1. The C gamma 3 domain makes a smaller contribution to the binding, and the C gamma 1 domain and the hinge region have very little effect on the Fc gamma RI-IgG1 interaction. The chimeric epsilon/C gamma 2,3 and huIgG1 both mediate the formation of rosettes between K562 cells and antigen-sensitized E with similar concentration dependences. These results suggest similar ability to bind to Fc gamma RII. The other chimeric Ig do not cause rosettes in this assay system. Hence, both C gamma 2 and C gamma 3 seem to be required for binding to Fc gamma RII, but the C gamma 1-hinge region has no detectable effect.     

Crystal structure of Fcγ receptor I and its implication in high affinity γ-immunoglobulin binding

Fcγ receptors (FcγRs) play critical roles in humoral and cellular immune responses through interactions with the Fc region of immunoglobulin G (IgG). Among them, FcγRI is the only high affinity receptor for IgG and thus is a potential target for immunotherapy. Here we report the first crystal structure of an FcγRI with all three extracellular Ig-like domains (designated as D1, D2, and D3). The structure shows that, first, FcγRI has an acute D1-D2 hinge angle similar to that of FcεRI but much smaller than those observed in the low affinity Fcγ receptors. Second, the D3 domain of FcγRI is positioned away from the putative IgG binding site on the receptor and is thus unlikely to make direct contacts with Fc. Third, the replacement of FcγRIII FG-loop ((171)LVGSKNV(177)) with that of FcγRI ((171)MGKHRY(176)) resulted in a 15-fold increase in IgG(1) binding affinity, whereas a valine insertion in the FcγRI FG-loop ((171)MVGKHRY(177)) abolished the affinity enhancement. Thus, the FcγRI FG-loop with its conserved one-residue deletion is critical to the high affinity IgG binding. The structural results support FcγRI binding to IgG in a similar mode as its low affinity counterparts. Taken together, our study suggests a molecular mechanism for the high affinity IgG recognition by FcγRI and provides a structural basis for understanding its physiological function and its therapeutic implication in treating autoimmune diseases.     

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.     

Fc receptors and immunoglobulin binding factors

Receptors for the Fc portion of Ig (Fc receptors, FcR) are found on all cell types of the immune system. Three types of FcR react with IgG: Fc gamma RI is a high-affinity receptor binding IgG monomers whereas Fc gamma RII and Fc gamma RIII are low-affinity receptors binding IgG immune complexes; the three types of Fc gamma R are members of the Ig superfamily. Two FcR react with IgE:Fc epsilon RI is a multichain receptor binding IgE with high affinity; it is composed of an IgE-binding alpha chain, homologous to Fc gamma RIII, and of gamma and beta chains that are necessary for receptor expression and signal transduction. The low-affinity Fc epsilon RII is the only FcR described so far that is not a member of the Ig superfamily but resembles animal lectins; it is composed of a transmembrane chain with an intracytoplasmic NH2 terminus. Fc alpha R has homology with Fc gamma R and is a member of the Ig superfamily. Receptors for IgM and IgD are not characterized yet. Finally, Ig transport is made by FcR-like molecules such as the poly-Ig receptor or an MHC-like receptor found on neonatal intestine. A remarkable property of most FcR is the fact that they are released in cell supernatants and circulate in biological fluids as immunoglobulin binding factors (IBF) generated either by cleavage at the cell membrane or by splicing of FcR transmembrane exon. Immunoglobulin binding factors may interfere with Ig-mediated functions and have direct immunoregulatory activities. Involvement of FcR or IBF has been postulated in several diseases, and monoclonal antibodies to FcR are beginning to be used in therapeutics, particularly to target cytotoxic effector lymphocytes and monocytes to tumor cells.     

A novel human immunoglobulin Fc gamma Fc epsilon bifunctional fusion protein inhibits Fc epsilon RI-mediated degranulation

Human mast cells and basophils that express the high-affinity immunoglobulin E (IgE) receptor, Fc epsilon receptor 1 (Fc epsilon RI), have key roles in allergic diseases. Fc epsilon RI cross-linking stimulates the release of allergic mediators. Mast cells and basophils co-express Fc gamma RIIb, a low affinity receptor containing an immunoreceptor tyrosine-based inhibitory motif and whose co-aggregation with Fc epsilon RI can block Fc epsilon RI-mediated reactivity. Here we designed, expressed and tested the human basophil and mast-cell inhibitory function of a novel chimeric fusion protein, whose structure is gamma Hinge-CH gamma 2-CH gamma 3-15aa linker-CH epsilon 2-CH epsilon 3-CH epsilon 4. This Fc gamma Fc epsilon fusion protein was expressed as the predicted 140-kappa D dimer that reacted with anti-human epsilon- and gamma-chain specific antibodies. Fc gamma Fc epsilon bound to both human Fc epsilon RI and Fc gamma RII. It also showed dose- and time-dependent inhibition of antigen-driven IgE-mediated histamine release from fresh human basophils sensitized with IgE directed against NIP (4-hydroxy-3-iodo-5-nitrophenylacetyl). This was associated with altered Syk signaling. The fusion protein also showed increased inhibition of human anti-NP (4-hydroxy-3-nitrophenylacetyl) and anti-dansyl IgE-mediated passive cutaneous anaphylaxis in transgenic mice expressing human Fc epsilon RI alpha. Our results show that this chimeric protein is able to form complexes with both Fc epsilon RI and Fc gamma RII, and inhibit mast-cell and basophil function. This approach, using a Fc gamma Fc epsilon fusion protein to co-aggregate Fc epsilon RI with a receptor containing an immunoreceptor tyrosine-based inhibition motif, has therapeutic potential in IgE- and Fc epsilon RI-mediated diseases.     

Expression of a functional high-affinity IgG receptor, Fc gamma RI, on human mast cells: Up-regulation by IFN-gamma

Biologically relevant activation of human mast cells through Fc receptors is believed to occur primarily through the high-affinity IgE receptor Fc epsilon RI. However, the demonstration in animal models that allergic reactions do not necessarily require Ag-specific IgE, nor the presence of a functional IgE receptor, and the clinical occurrence of some allergic reactions in situations where Ag-specific IgE appears to be lacking, led us to examine the hypothesis that human mast cells might express the high-affinity IgG receptor Fc gamma RI and in turn be activated through aggregation of this receptor. We thus first determined by RT-PCR that resting human mast cells exhibit minimal message for Fc gamma RI. We next found that IFN-gamma up-regulated the expression of Fc gamma RI. This was confirmed by flow cytometry, where Fc gamma RI expression on human mast cells was increased from approximately 2 to 44% by IFN-gamma exposure. Fc epsilon RI, Fc gamma RII, and Fc gamma RIII expression was not affected. Scatchard plots were consisted with these data where the average binding sites for monomeric IgG1 (Ka = 4-5 x 108 M-1) increased from approximately 2,400 to 12,100-17,300 per cell. Aggregation of Fc gamma RI on human mast cells, and only after IFN-gamma exposure, led to significant degranulation as evidenced by histamine release (24.5 +/- 4.4%): and up-regulation of mRNA expression for specific cytokines including TNF-alpha, GM-CSF, IL-3 and IL-13. These findings thus suggest another mechanism by which human mast cells may be recruited into the inflammatory processes associated with some immunologic and infectious diseases.     

Human neutrophils express the high-affinity receptor for immunoglobulin E (Fc epsilon RI): role in asthma.

Polymorphonuclear neutrophils (PMNs) are important effector cells in host defense and the inflammatory response to antigen. The involvement of PMNs in inflammation is mediated mainly by the Fc receptor family, including IgE receptors. Recently, PMNs were shown to express two IgE receptors (CD23/Fc epsilon RII and galectin-3). In allergic diseases, the dominant role of IgE has been mainly ascribed to its high-affinity receptor, Fc epsilon RI. We have examined the expression of Fc epsilon RI by PMNS: mRNA and cell surface expression of Fc epsilon RI alpha chain was identified on PMNs from asthmatic subjects. Furthermore, preincubation with human IgE Fc fragment blocks completely the binding of anti-Fc epsilon RI alpha chain (mAb15--1) to human PMNS: Conversely, preincubation of PMNs with mAb15--1 inhibits significantly the binding of IgE Fc fragment to PMNs, indicating that IgE bound to the cell surface of PMNs mainly via the Fc epsilon RI. Peripheral blood and bronchoalveolar lavage (BAL) PMNs from asthmatic subjects also express intracellular Fc epsilon RI alpha and beta chain immunoreactivity. Engagement of Fc epsilon RI induces the release of IL-8 by PMNS: Collectively, these observations provide new evidence that PMNs express the Fc epsilon RI and suggest that these cells may play a role in allergic inflammation through an IgE-dependent activation mechanism.     

Mapping of the high affinity Fc epsilon receptor binding site to the third constant region domain of IgE.

Identification of the precise region(s) on the IgE molecule that take part in the binding of IgE to its high affinity receptor (Fc epsilon RI) may lead to the design of IgE analogues able to block the allergic response. To localize the Fc epsilon RI-binding domain of mouse IgE, we attempted to confer on human IgE, which normally does not bind to the rodent receptor, the ability to bind to the rat Fc epsilon RI. Employing exon shuffling, we have expressed chimeric epsilon-heavy chain genes composed of a mouse (4-hydroxy-3-nitrophenyl)acetic acid (NP)-binding VH domain, and human C epsilon in which various domains were replaced by their murine counterparts. This has enabled us to test the Fc epsilon RI-binding of each mouse IgE domain while maintaining the overall conformation of the molecule. All of the chimeric IgE molecules which contain the murine C epsilon 3, bound equally to both the rodent and human receptor, as well as to monoclonal antibodies recognizing a site on IgE which is identical or very close to the Fc epsilon RI binding site. Deletion of the second constant region domain did not impair either the binding capacity of the mutated IgE or its ability to mediate mast cell degradation. These results assign the third epsilon domain of IgE as the principal region involved in the interaction with the Fc epsilon RI.     

Molecular cloning and expression of the mouse high affinity Fc receptor for IgG

Full length cDNA clones encoding the mouse Fc gamma RI were isolated by using redundant oligonucleotide probes based on previously determined amino acid sequence of protein bound to an IgG2a antibody column. Sequence analysis of cDNA clones indicates that mouse Fc gamma RI is a transmembrane glycoprotein that is composed of three disulfide bonded extracellular Ig binding domains unlike Fc gamma RII of man and mouse. These extracellular domains contain five potential sites of N-linked glycosylation; three sites in the first domain and one in each of the second and third domains. In addition a transmembrane region is present followed by a cytoplasmic tail of 84 amino acids. Analysis of the amino acid sequence of the first two extracellular domains of Fc gamma RI indicate that these are highly homologous to the extracellular domains of Fc gamma RII; the third domain is different and shows a lower level of homology to other FcR domains but is clearly related to the Ig super-family. Transfected cells expressing Fc gamma RI were shown to bind immune complexes of rabbit IgG; and monomeric IgG2a bound to transiently transfected cells with an affinity of approximately 5 x 10(7) M-1, i.e. the receptor was of high affinity and therefore was by definition Fc gamma RI. Northern analysis demonstrated that Fc gamma RI mRNA could be detected in the Fc gamma RI+ myeloid cell lines WEH1 3B and J774. Finally, Southern analysis indicated that Fc gamma RI is likely to be encoded by a single copy gene of approximately 9 kb.     

Artificial Anti-Tumor Opsonizing Proteins with Fibronectin Scaffolds Engineered for Specificity to Each of the Murine FcγR Types

We have engineered a panel of novel Fn3 scaffold-based proteins that bind with high specificity and affinity to each of the individual mouse Fcγ receptors (mFcγR). These binders were expressed as fusions to anti-tumor antigen single-chain antibodies and mouse serum albumin, creating opsonizing agents that invoke only a single mFcγR response rather than the broader activity of natural Fc isotypes, as well as all previously reported Fc mutants. This panel isolated the capability of each of the four mFcγRs to contribute to macrophage phagocytosis of opsonized tumor cells and in vivo tumor growth control with these monospecific opsonizing fusion proteins. All activating receptors (mFcγRI, mFcγRIII, and mFcγRIV) were capable of driving specific tumor cell phagocytosis to an equivalent extent, while mFcγRII, the inhibitory receptor, did not drive phagocytosis. Monospecific opsonizing fusion proteins that bound mFcγRI alone controlled tumor growth to an extent similar to the most active IgG2a murine isotype. As expected, binding to the inhibitory mFcγRII did not delay tumor growth, but unexpectedly, mFcγRIII also failed to control tumor growth. mFcγRIV exhibited detectable but lesser tumor-growth control leading to less overall survival compared to mFcγRI. Interestingly, in vivo macrophage depletion demonstrates their importance in tumor control with mFcγRIV engagement, but not with mFcγRI. This panel of monospecific mFcγR-binding proteins provides a toolkit for isolating the functional effects of each mFcγR in the context of an intact immune system.     

Gene mapping of the three subunits of the high affinity FcR for IgE to mouse chromosomes 1 and 19

The high affinity receptor for IgE (Fc epsilon RI) is a tetrameric structure consisting of a single IgE-binding alpha subunit, a single beta subunit, and two disulfide-linked gamma subunits. The alpha subunit of Fc epsilon RI and most Fc receptors are homologous members of the Ig superfamily. By contrast, the beta and gamma subunits from Fc epsilon RI are not homologous to the Ig superfamily. The gamma-chains do share a region of high homology with the zeta-chain of the TCR. No homology has been found to date for beta with any published sequence. Here, we report that a single copy gene encodes Fc epsilon RI beta and that the locus for Fc epsilon RI beta is found on mouse chromosome 19, genetically linked to the Ly-1 (Ly-12) locus and in a region that also contains Ly-10 and Ly-44 (CD20). Homology comparisons among these molecules reveal limited regions of homology between Fc epsilon RI beta and Ly-44 (CD20) as well as other striking similarities: both molecules have four putative transmembrane segments and a probably topology where both amino- and carboxytermini protrude into the cytoplasm. In addition, we show that a single gene for FC epsilon RI gamma is found at the distal end of mouse chromosome 1, clustered in a region where Fc epsilon RI alpha has also been linked to Fc gamma RII. At least one of the two forms of Fc gamma RII has recently been shown to contain gamma subunits identical to the gamma subunits of Fc epsilon RI. The close association of the genes for Fc epsilon RI alpha, FC gamma RII, and their shared gamma subunits raises interesting implications regarding coordinate regulation of gene expression.     

Fcγ receptors exhibit different phagocytosis potential in human neutrophils

In neutrophils, two receptors for IgG antibodies, namely FcγRIIA and FcγRIIIB are constitutively expressed, and a third one, FcγRI, can be upregulated by interferon-γ. Whether FcγRIIIB is capable of triggering phagocytosis by itself is still controversial. The main role of FcγRI has not been clearly established in these cells. To address this problem, neutrophils were treated with interferon-γ, and then phagocytosis mediated by each type of Fcγ receptor was evaluated by flow cytometry. FcγRIIA was the most efficient receptor for phagocytosis. FcγRIIIB could mediate phagocytosis but much less efficiently than FcγRIIA. Both FcγRIIA- and FcγRIIIB-mediated phagocytosis were blocked by inhibitors of Src family kinases, Syk, PI 3-K, and ERK. In contrast, interferon-γ-induced FcγRI was not able to mediate phagocytosis. Also, FcγRI did not activate ERK in the nucleus, but was however able to stimulate an efficient calcium rise. These data show that different neutrophil Fcγ receptors possess different phagocytosis capabilities: FcγRIIA and FcγRIIIB, but not FcγRI, promote phagocytosis.     

The effectiveness of different rat IgG subclasses as IgE-blocking antibodies in the rat basophil leukaemia cell model

The degranulation of mast cells in an allergic response is initiated by the aggregation of high-affinity IgE receptors (Fc epsilon RI) by IgE and antigen. Recently it has been shown that such degranulation can be inhibited by cross-linking Fc epsilon RI and low-affinity IgG receptors (Fc gamma RII) which are also expressed by mast cells. The ability of various monoclonal antibodies to block the degranulation of rat basophil leukaemia (RBL) cells sensitized with IgE antidinitrophenyl (DNP) antibodies has been investigated. Sensitized cells were challenged with immune complexes formed using varying concentrations of antigen, and of both high- and low-valency antigen. It is reported here that rat IgG1 antibodies, which are associated in the rat with a Th1-type response, act as highly effective blocking antibodies over a wide concentration range. Rat IgG2a antibodies, which are associated with a Th2-type response, were able only to inhibit degranulation when immune complexes were formed with very low concentrations of high-valency antigen (DNP32-HSA). Under these conditions, some inhibitory activity was seen with high-affinity murine IgA anti-DNP but not with low-affinity rat IgG2b anti-DNP antibody-containing immune complexes. In addition to this inhibitory activity, IgG2a antibodies were shown to be capable of inducing degranulation of cells via unoccupied Fc epsilon RI. These results demonstrate that blocking activity may arise via both inhibitory receptors and by masking of antigen.     

Fcγ receptors inhibit mouse and human basophil activation

Besides high-affinity IgE receptors (FcεRI), human basophils express activating (FcγRIIA) and inhibitory (FcγRIIB) low-affinity IgG receptors. IgG receptors (FcγR) were also found on mouse basophils, but not identified. We investigated in this study FcγR and the biological consequences of their engagement in basophils of the two species. We found the following: 1) that mouse basophils also express activating (FcγRIIIA) and inhibitory (FcγRIIB) low-affinity FcγR; 2) that activating FcγR can activate both human and mouse basophils, albeit with different efficacies; 3) that negative signals triggered by inhibitory FcγR are dominant over positive signals triggered by activating FcγR, thus preventing both human and mouse basophils from being activated by IgG immune complexes; 4) that the coengagement of FcεRI with inhibitory and activating FcγR results in a FcγRIIB-dependent inhibition of IgE-induced responses of both human and mouse basophils; 5) that FcγRIIB has a similar dominant inhibitory effect in basophils from virtually all normal donors; and 6) that IL-3 upregulates the expression of both activating and inhibitory FcγR on human basophils from normal donors, but further enhances FcγRIIB-dependent inhibition. FcγR therefore function as a regulatory module, made of two subunits with antagonistic properties, that prevents IgG-induced and controls IgE-induced basophil activation in both mice and humans.     

The human IgA-Fc alpha receptor interaction and its blockade by streptococcal IgA-binding proteins

IgA plays a key role in immune defence of the mucosal surfaces. IgA can trigger elimination mechanisms against pathogens through the interaction of its Fc region with Fc alpha Rs (receptors specific for the Fc region of IgA) present on neutrophils, macrophages, monocytes and eosinophils. The human Fc alpha R (CD89) shares homology with receptors specific for the Fc region of IgG (Fc gamma Rs) and IgE (Fc epsilon RIs), but is a more distantly related member of the receptor family. CD89 interacts with residues lying at the interface of the two domains of IgA Fc, a site quite distinct from the homologous regions at the top of IgG and IgE Fc recognized by Fc gamma R and Fc epsilon RI respectively. Certain pathogenic bacteria express surface proteins that bind to human IgA Fc. Experiments with domain-swap antibodies and mutant IgAs indicate that binding of three such proteins (Sir22 and Arp4 of Streptococcus pyogenes and beta protein of group B streptococci) depend on sites in the Fc interdomain region of IgA, the binding region also used by CD89. Further, we have found that the streptococcal proteins can inhibit interaction of IgA with CD89, and have thereby identified a mechanism by which a bacterial IgA-binding protein may modulate IgA effector function.