Recognition of IgG by Fc receptor and complement: effects of glycosidase digestion.

By extensive glycosidase digestion, most of carbohydrates were removed from IgG antibody against sheep erythrocytes without impairing hemagglutinating activity. The sugar-depleted IgG significantly lost the activities in antibody-dependent cell-mediated cytotoxicity, rosette formation and complement-dependent hemolysis. The results indicated the requirement of the carbohydrate moieties in recognition by Fc receptor and complement. Furthermore differential glycosidase digestion suggested that N-acetylglucosamine or mannose was the key sugar residue required for the maintenance of the activities.     

Human Fcgamma receptor IIb expressed in Escherichia coli reveals IgG binding capability.

Fcgamma receptors (FcgammaR) are expressed on immunologically active cells where they trigger B and T cell responses and are responsible for the clearance of immunocomplexes. They occur as type I transmembrane proteins and also in soluble forms (sFcR) comprising only the ecto domains of the receptors. State-of-the-art research has generated demand for highly pure and homogeneous sFcgammaR preparations: first, studies of the immunoregulative potential of the soluble FcgammaRs have been hampered by co-purified growth factors. Second, they are needed for crystallographic analyses to solve questions such as the exact location of the binding site for IgG on the receptor, and the graded affinities of the receptors for different IgG subclasses. This has been unsuccessful due to limitations in availability and homogeneity of sFcgammaR expressed in eukaryotic cells. In order to address these problems we expressed the extracellular part of the human FcgammaRIIb in E. coli. The protein was refolded, purified in a three-step procedure and characterized by SDS-PAGE, mass spectrometry as well as N-terminal sequencing. The unglycosylated FcgammaRIIb is active because it binds immobilized antibody as well as the IgG Fc-fragment in solution. Finally, the receptor was crystallized in orthorhombic, tetragonal and hexagonal crystal forms that diffracted X-rays to resolutions of 1.7 A, 2.7 A and 3.8 A respectively.     

Characterization and screening of IgG binding to the neonatal Fc receptor

The neonatal Fc receptor (FcRn) protects immunoglobulin G (IgG) from degradation and increases the serum half-life of IgG, thereby contributing to a higher concentration of IgG in the serum. Because altered FcRn binding may result in a reduced or prolonged half-life of IgG molecules, it is advisable to characterize Fc receptor binding of therapeutic antibody lead candidates prior to the start of pre-clinical and clinical studies.

In this study, we characterized the interactions between FcRn of different species (human, cynomolgus monkey, mouse and rat) and nine IgG molecules from different species and isotypes with common variable heavy (VH) and variable light chain (VL) domains. Binding was analyzed at acidic and neutral pH using surface plasmon resonance (SPR) and biolayer interferometry (BLI).

Furthermore, we transferred the well-accepted, but low throughput SPR-based method for FcRn binding characterization to the BLI-based Octet platform to enable a higher sample throughput allowing the characterization of FcRn binding already during early drug discovery phase. We showed that the BLI-based approach is fit-for-purpose and capable of discriminating between IgG molecules with significant differences in FcRn binding affinities.

Using this high-throughput approach we investigated FcRn binding of 36 IgG molecules that represented all VH/VL region combinations available in the fully human, recombinant antibody library Ylanthia®. Our results clearly showed normal FcRn binding profiles for all samples. Hence, the variations among the framework parts, complementarity-determining region (CDR) 1 and CDR2 of the fragment antigen binding (Fab) domain did not significantly change FcRn binding.     

Characterization and screening of IgG binding to the neonatal Fc receptor

The neonatal Fc receptor (FcRn) protects immunoglobulin G (IgG) from degradation and increases the serum half-life of IgG, thereby contributing to a higher concentration of IgG in the serum. Because altered FcRn binding may result in a reduced or prolonged half-life of IgG molecules, it is advisable to characterize Fc receptor binding of therapeutic antibody lead candidates prior to the start of pre-clinical and clinical studies. In this study, we characterized the interactions between FcRn of different species (human, cynomolgus monkey, mouse and rat) and nine IgG molecules from different species and isotypes with common variable heavy (VH) and variable light chain (VL) domains. Binding was analyzed at acidic and neutral pH using surface plasmon resonance (SPR) and biolayer interferometry (BLI). Furthermore, we transferred the well-accepted, but low throughput SPR-based method for FcRn binding characterization to the BLI-based Octet platform to enable a higher sample throughput allowing the characterization of FcRn binding already during early drug discovery phase. We showed that the BLI-based approach is fit-for-purpose and capable of discriminating between IgG molecules with significant differences in FcRn binding affinities. Using this high-throughput approach we investigated FcRn binding of 36 IgG molecules that represented all VH/VL region combinations available in the fully human, recombinant antibody library Ylanthia®. Our results clearly showed normal FcRn binding profiles for all samples. Hence, the variations among the framework parts, complementarity-determining region (CDR) 1 and CDR2 of the fragment antigen binding (Fab) domain did not significantly change FcRn binding.     

Synthesis and receptor binding of IgG1 peptides derived from the IgG Fc region

The IgG binding Fcgamma receptors (FcgammaRs) play a key role in defence against pathogens by linking humoral and cell-mediated immune responses. Impaired expression and/or function of FcgammaR may result in the development of pathological autoimmunity. Considering the functions of FcgammaRs, they are potential target molecules for drug design to aim at developing novel anti-inflammatory and immunomodulatory therapies. Previous data mostly obtained by X-ray analysis of ligand-receptor complexes indicate the profound role of the CH2 domain in binding to various FcgammaRs. Our aim was to localize linear segments, which are able to bind and also to modulate the function of the low affinity FcgammaRs, like FcgammaRIIb and FcgammaRIIIa. To this end a set of overlapping octapeptides was prepared corresponding to the 231-298 sequence of IgG1 CH2 domain and tested for binding to human recombinant soluble FcgammaRIIb. Based on these results, a second group of peptides was synthesized and their binding properties to recombinant soluble FcgammaRIIb, as well as to FcgammaRs expressed on the cell surface, was investigated. Here we report that peptide representing the Arg(255)-Ser(267) sequence of IgG1 is implicated in the binding to FcgammaRIIb. In addition we found that peptides corresponding to the Arg(255)-Ser(267), Lys(288)-Ser(298) or Pro(230)-Val(240) when presented in a multimeric form conjugated to branched chain polypeptide in uniformly oriented copies induced the release of TNFalpha, a pro-inflammatory cytokine from MonoMac monocyte cell line. These findings indicate that these conjugated peptides are able to cluster the activating FcgammaRs, and mediate FcgammaR dependent function. Peptide Arg(255)-Ser(267) can also be considered as a lead for further functional studies.     

pH dependence and stoichiometry of binding to the Fc region of IgG by the herpes simplex virus Fc receptor gE-gI

Herpes simplex virus type 1 encodes two glycoproteins, gE and gI, that form a heterodimer on the surface of virions and infected cells. The gE-gI heterodimer has been implicated in cell-to-cell spread of virus and is a receptor for the Fc fragment of IgG. Previous studies localized the gE-gI-binding site on human IgG to a region near the interface between the C(H)2 and C(H)3 domains of Fc, which also serves as the binding site for bacterial and mammalian Fc receptors. Although there are two potential gE-gI-binding sites per Fc homodimer, only one gE-gI heterodimer binds per IgG in gel filtration experiments. Here we report production of recombinant human Fc molecules that contain zero, one, or two potential gE-gI-binding sites and use them in analytical ultracentrifugation experiments to show that two gE-gI heterodimers can bind to each Fc. Further characterization of the gE-gI interaction with Fc reveals a sharp pH dependence of binding, with K(D) values of approximately 340 and approximately 930 nm for the first and second binding events, respectively, at the slightly basic pH of the cell surface (pH 7.4), but undetectable binding at pH 6.0. This strongly pH-dependent interaction suggests a physiological role for gE-gI dissociation from IgG within acidic intracellular compartments, consistent with a mechanism whereby herpes simplex virus promotes intracellular degradation of anti-viral antibodies.     

Effect of protease inhibitors on human monocyte IgG Fc receptor II. Evidence that serine esterase activity is essential for Fc gamma RII-mediated binding

We have shown previously that certain proteases can modulate the affinity of human Fc gamma RII for IgG. To study whether proteolytic events not only increase FcR affinity, but are essential for Fc gamma R functioning, we evaluated the effect of different protease inhibitors on binding mediated by two classes of human monocyte IgG FcR. These R, Fc gamma RI and Fc gamma RII, can be analyzed selectively in rosetting assays by employing E sensitized by either human IgG or mouse IgG1. Rosetting by both classes of R was inhibited profoundly by incubation of monocytes with different types of serine protease inhibitors such as diisopropylfluorophosphate, PMSF, or N alpha-tosyl-L-lysyl-chloromethylketone. The type II Fc gamma R was much more sensitive to inhibition than Fc gamma RI. We, therefore, studied these effects in more detail by using cell line K562, which expresses only Fc gamma RII. PMSF, diisopropylfluorophosphate, and N alpha-tosyl-L-lysyl-chloromethylketone were, again, inhibiting Fc gamma RII-mediated binding dose-dependently, whereas several inhibitors of metal, aspartic, or thiol proteases proved ineffective. Furthermore, Fc gamma RII-mediated rosetting on both cell types was profoundly inhibited by the addition of different small synthetic substrates of serine esterases. In an attempt to discriminate whether the proteolytic event is an intra- or extracellular process, macromolecular antiproteases such as soybean or ovomucoid trypsin inhibitor or alpha 1-antiprotease were tested. Fc gamma RII-mediated binding by K562 cells was not susceptible to macromolecular antiproteases, in contrast to monocytes. In the presence of drugs which interfere both with receptor recycling and intracellular traffic between endosomal compartments (e.g., primaquine or monensin), the effects of inhibitors were largely abrogated. This showed that endocytosis of inhibitors might be essential, indicating the proteolytic event to be intracellular. Our findings suggest that human monocyte Fc gamma RII-mediated functioning is dependent upon the action of one or more serine proteases.     

Isolation and characterization of IgG1 with asymmetrical Fc glycosylation

N-glycosylation of immunoglobulin G (IgG) at asparigine residue 297 plays a critical role in antibody stability and immune cell-mediated Fc effector function. Current understanding pertaining to Fc glycosylation is based on studies with IgGs that are either fully glycosylated [both heavy chain (HC) glycosylated] or aglycosylated (neither HC glycosylated). No study has been reported on the properties of hemi-glycosylated IgGs, antibodies with asymmetrical glycosylation in the Fc region such that one HC is glycosylated and the other is aglycosylated. We report here for the first time a detailed study of how hemi-glycosylation affects the stability and functional activities of an IgG1 antibody, mAb-X, in comparison to its fully glycosylated counterpart. Our results show that hemi-glycosylation does not impact Fab-mediated antigen binding, nor does it impact neonatal Fc receptor binding. Hemi-glycosylated mAb-X has slightly decreased thermal stability in the CH2 domain and a moderate decrease (～20%) in C1q binding. More importantly, the hemi-glycosylated form shows significantly decreased binding affinities toward all Fc gamma receptors (FcγRs) including the high-affinity FcγRI, and the low-affinity FcγRIIA, FcγRIIB, FcγRIIIA and FcγRIIIB. The decreased binding affinities to FcγRs result in a 3.5-fold decrease in antibody-dependent cell cytotoxicity (ADCC). As ADCC often plays an important role in therapeutic antibody efficacy, glycosylation status will not only affect the antibody quality but also may impact the biological function of the product.     

Effect of glycosylation inhibitors on binding properties of the Fc gamma receptors from guinea pig peritoneal macrophages.

Guinea pig peritoneal macrophages possess on their surfaces receptors for the Fc region of IgG immunoglobulins (Fc gamma R). The cells treated with the glycosylation inhibitors tunicamycin or monensin interacted with IgG with a higher affinity and showed a lower number of IgG-binding sites in comparison with control cells. This indicates that the interaction of IgG with the macrophage Fc gamma receptor depends on the degree of glycosylation of the cell surface glycoconjugates and that glycosylation of the macrophage Fc gamma receptor is important for the expression of the mature form of the receptor.     

The structure of the murine Fc receptor for IgG. Assignment of intrachain disulfide bonds, identification of N-linked glycosylation sites, and evidence for a fourth form of Fc receptor

The Fc receptor (Fc gamma R) of the murine macrophage cell line, J774, was purified by immunoaffinity chromatography then subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis and amino-terminal sequencing. FcR material judged to be pure by these criteria was digested with a number of enzymes to identify the cysteine residues engaged in disulfide bonds within the native structure. The results clearly establish that the mouse macrophage Fc gamma R contains two intrachain disulfide bonds, each of which connects adjacent cysteine residues within the two putative extracellular domains of the molecule. In addition, each disulfide-bonded domain was shown to contain two authentic sites of N-linked glycosylation. Extensive peptide sequencing resulted in the unexpected identification of peptide fragments from a fourth Fc gamma R whose sequences were highly homologous to sequences surrounding the two Cys residues in the amino-terminal domain of both alpha and beta 1 Fc gamma R. The fourth Fc gamma R contains a disulfide-bonded amino-terminal domain similar to beta 1 Fc gamma R.     

The structure of a human type III Fcgamma receptor in complex with Fc

Fcgamma receptors mediate antibody-dependent inflammatory responses and cytotoxicity as well as certain autoimmune dysfunctions. Here we report the crystal structure of a human Fc receptor (FcgammaRIIIB) in complex with an Fc fragment of human IgG1 determined from orthorhombic and hexagonal crystal forms at 3.0- and 3.5-A resolution, respectively. The refined structures from the two crystal forms are nearly identical with no significant discrepancies between the coordinates. Regions of the C-terminal domain of FcgammaRIII, including the BC, C'E, FG loops, and the C' beta-strand, bind asymmetrically to the lower hinge region, residues Leu(234)-Pro(238), of both Fc chains creating a 1:1 receptor-ligand stoichiometry. Minor conformational changes are observed in both the receptor and Fc upon complex formation. Hydrophobic residues, hydrogen bonds, and salt bridges are distributed throughout the receptor.Fc interface. Sequence comparisons of the receptor-ligand interface residues suggest a conserved binding mode common to all members of immunoglobulin-like Fc receptors. Structural comparison between FcgammaRIII.Fc and FcepsilonRI.Fc complexes highlights the differences in ligand recognition between the high and low affinity receptors. Although not in direct contact with the receptor, the carbohydrate attached to the conserved glycosylation residue Asn(297) on Fc may stabilize the conformation of the receptor-binding epitope on Fc. An antibody-FcgammaRIII model suggests two possible ligand-induced receptor aggregations.     

Affinity and kinetic analysis of Fcgamma receptor IIIa (CD16a) binding to IgG ligands

Binding of pathogen-bound immunoglobulin G (IgG) to cell surface Fc gamma receptors (FcgammaRs) triggers a wide variety of effector functions. The binding kinetics and affinities of IgG-FcgammaR interactions are hence important parameters for understanding FcgammaR-mediated immune functions. We have measured the kinetic rates and equilibrium dissociation constants of IgG binding to a soluble FcgammaRIIIa fused with Ig Fc (sCD16a) using the surface plasmon resonance technique. sCD16a interacted with monomeric human IgG and its subtypes IgG1 and IgG3 as well as rabbit IgG with on-rates of 6.5 x 10(3), 8.2 x 10(3), 1.1 x 10(4) and 1.8 x 10(4) m(-1) s(-1), off-rates of 4.7 x 10(-3), 5.7 x 10(-3), 5.9 x 10(-3), and 1.9 x 10(-2) s(-1), and equilibrium dissociation constants of 0.72, 0.71, 0.56, and 1.1 mum, respectively. The kinetics and affinities measured by surface plasmon resonance agreed with those obtained from real time flow cytometry and competition inhibition binding experiments using cell surface CD16a. These data add to our understanding of IgG-FcgammaR interactions.     

Highly parallel characterization of IgG Fc binding interactions

Because the variable ability of the antibody constant (Fc) domain to recruit innate immune effector cells and complement is a major factor in antibody activity in vivo, convenient means of assessing these binding interactions is of high relevance to the development of enhanced antibody therapeutics, and to understanding the protective or pathogenic antibody response to infection, vaccination, and self. Here, we describe a highly parallel microsphere assay to rapidly assess the ability of antibodies to bind to a suite of antibody receptors. Fc and glycan binding proteins such as FcγR and lectins were conjugated to coded microspheres and the ability of antibodies to interact with these receptors was quantified. We demonstrate qualitative and quantitative assessment of binding preferences and affinities across IgG subclasses, Fc domain point mutants, and antibodies with variant glycosylation. This method can serve as a rapid proxy for biophysical methods that require substantial sample quantities, high-end instrumentation, and serial analysis across multiple binding interactions, thereby offering a useful means to characterize monoclonal antibodies, clinical antibody samples, and antibody mimics, or alternatively, to investigate the binding preferences of candidate Fc receptors.     

Highly parallel characterization of IgG Fc binding interactions

Because the variable ability of the antibody constant (Fc) domain to recruit innate immune effector cells and complement is a major factor in antibody activity in vivo, convenient means of assessing these binding interactions is of high relevance to the development of enhanced antibody therapeutics, and to understanding the protective or pathogenic antibody response to infection, vaccination, and self. Here, we describe a highly parallel microsphere assay to rapidly assess the ability of antibodies to bind to a suite of antibody receptors. Fc and glycan binding proteins such as FcγR and lectins were conjugated to coded microspheres and the ability of antibodies to interact with these receptors was quantified. We demonstrate qualitative and quantitative assessment of binding preferences and affinities across IgG subclasses, Fc domain point mutants, and antibodies with variant glycosylation. This method can serve as a rapid proxy for biophysical methods that require substantial sample quantities, high-end instrumentation, and serial analysis across multiple binding interactions, thereby offering a useful means to characterize monoclonal antibodies, clinical antibody samples, and antibody mimics, or alternatively, to investigate the binding preferences of candidate Fc receptors.     

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.     

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

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

Concurrent and independent binding of Fcgamma receptors IIa and IIIb to surface-bound IgG

Fc receptor-antibody interactions are key mechanisms through which antibody effector functions are mediated. Neutrophils coexpress two low-affinity Fcgamma receptors, CD16b (FcgammaRIIIb) and CD32a (FcgammaRIIa), possessing overlapping ligand binding specificities but distinct membrane anchor and signaling capacities. Using K562 cell transfectants as a model, the kinetics of both separate and concurrent binding of CD16b and CD32a to surface-bound IgG ligands were studied. CD16b bound human IgG with 2-3 times higher affinity than did CD32a (A(c)K(a) = 4.1 and 1.6 x 10(-7) microm(4), respectively) and both FcgammaRs had similar reverse kinetic rates (k(r) = 0.5 and 0.4 s(-1), respectively). Because CD16b is expressed on neutrophils at a 4-5 times higher density than CD32a, our results suggest that CD16b plays the dominant role in binding of neutrophils to immobilized IgG. The question of possible cross-regulation of binding affinity between CD16b and CD32a was investigated using our multispecies concurrent binding model (Zhu and Williams, Biophys. J. 79:1850-1857, 2000). Because the model assumes independent binding (no cooperation among different species), the excellent agreement between the model predictions and the experimental data suggests that, when coexpressed on K562 cells, these two FcgammaRs do not interact in a manner that alters the kinetic rates of either molecule.     

The IgG Fc contains distinct Fc receptor (FcR) binding sites: the leukocyte receptors Fc gamma RI and Fc gamma RIIa bind to a region in the Fc distinct from that recognized by neonatal FcR and protein A

The CH2-CH3 interface of the IgG Fc domain contains the binding sites for a number of Fc receptors including Staphylococcal protein A and the neonatal Fc receptor (FcRn). It has recently been proposed that the CH2-CH3 interface also contains the principal binding site for an isoform of the low affinity IgG Fc receptor II (Fc gamma RIIb). The Fc gamma RI and Fc gamma RII binding sites have previously been mapped to the lower hinge and the adjacent surface of the CH2 domain although contributions of the CH2-CH3 interface to binding have been suggested. This study addresses the question whether the CH2-CH3 interface plays a role in the interaction of IgG with Fc gamma RI and Fc gamma RIIa. We demonstrate that recombinant soluble murine Fc gamma RI and human Fc gamma RIIa did not compete with protein A and FcRn for binding to IgG, and that the CH2-CH3 interface therefore appears not to be involved in Fc gamma RI and Fc gamma RIIa binding. The importance of the lower hinge was confirmed by introducing mutations in the proposed binding site (LL234,235AA) which abrogated binding of recombinant soluble Fc gamma RIIa to human IgG1. We conclude that the lower hinge and the adjacent region of the CH2 domain of IgG Fc is critical for the interaction between Fc gamma RIIa and human IgG, whereas contributions of the CH2-CH3 interface appear to be insignificant.     

Solid-phase synthesis and cyclization of a large branched peptide from IgG Fc with affinity for Fc gammaRI.

A solid phase approach has been used to synthesize a large branched disulphide peptide from IgG Fc, Ac-F-C*-A-K-V-N-N-K-D-L-P-A-P-I-E-K(Ac-E-L-L-G-G-P-S-V-F)-C*-I-NH2. This peptide combines the lower hinge region of IgG and a proximal beta-hairpin loop, both implicated in binding to Fc gammaRI. Solid phase Tl(tfa)3 cyclization of the linear branched peptide resulted in a poor yield of cyclic hinge-loop peptide (11%) most likely due to steric hindrance caused by the branch. However, if addition of the branch was preceded by solid phase Tl(tfa)3 cyclization of the loop, the yield was excellent at 75%. Cyclic hinge-loop peptide was active in displacing IgG2a from Fc gammaRI expressed on monocyte cell lines with an IC50 of 40 microM, whereas the linear form of this peptide was inactive. The Fc hinge-loop peptide demonstrates the potential for a non-mAb high affinity, immunomodulatory ligand for Fc gammaRI.     

Cynomolgus and pigtail macaque IgG subclasses: characterization of IGHG genes and computational analysis of IgG/Fc receptor binding affinity

Macaques are the most widely used experimental nonhuman primate (NHP) species. Rhesus (Macaca mulatta, Macmul), cynomolgus (Macaca fascicularis, Macfas), and pigtail (Macaca nemestrina, Macnem) macaques continue to be popular models for vaccine and infectious diseases research, especially HIV infection and AIDS, and for the development of antibody-based therapeutic strategies. Increased understanding of the immune system of these species is necessary for their optimal use as models of human infections and intervention. In the past few years, the antibody/Fc receptor system has been characterized in a stepwise manner in these species. We have continued this characterization by identifying the four IG heavy gamma (IGHG) genes of Macfas and Macnem in this study. Our results show that these genes share a high degree of similarity with those from other NHP species, while presenting consistent differences when compared to human IGHG genes. Furthermore, comparison of Macfas IGHG genes with those described in other studies suggests the existence of polymorphism. Using sequence- and structure-based computational tools, we performed in silico analysis on multiple polymorphic Macfas IgG and their interactions with human IgG Fc receptors (FcγR), thus predicting that Macfas IGHG polymorphisms influence IgG protein stability and/or binding affinity towards FcγR. The presence of macaque IGHG polymorphisms and macaque/human amino acid changes at locations potentially involved in antibody functional properties indicate the need for cautious design and data interpretation of studies in these models, possibly requiring the characterization of antibody/Fc receptor interactions at the individual level.