Stepwise cleavage of rabbit immunoglobin G by papain and isolation of four types of biologically active Fc fragments

Four types of Fc fragments of different sizes were isolated by papain treatment of rabbit immunoglobulin G under various conditions and by subsequent chromatographic procedures. 1. Brief digestion at neutral pH without reduction produced a molecule in which the Fab and Fc fragments were still linked by a pair of labile disulphide bridges, and the Fc fragment released by cleaving these bonds, called 1Fc fragment, contained a portion of the ;hinge' region including an interchain disulphide bridge. Both complement-binding and guinea-pig skin-binding activities were retained by this fragment, which had mol. wt. 48000. 2. Prolonged digestion at neutral pH of immunoglobulin G whose labile inter-heavy-chain disulphide bridges had been reduced removed the ;hinge' region, giving mFc fragments (mol. wt. 46000), which lacked the capacity to bind guinea-pig skin but retained the antigenic as well as the complement-binding activities of 1Fc fragment completely. 3. Digestion at pH5.0 yielded a smaller fragment, sFc (mol. wt. 40000), which was no longer able to bind complement. Though the antigenic structure was intact, sFc fragment was curiously unable to precipitate with antibodies to the N-terminal determinants. 4. Fragment stFc (mol. wt. 25000), representing the C-terminal portion of Fc fragment, was formed from all the larger fragments by digestion at pH4.5. Only the C-terminal antigenic determinants were retained by stFc fragment.     

The controlling effect of carbohydrate in human, rabbit and bovine immunoglobulin G on proteolysis by papain

About two-thirds of the hexose of human and rabbit immunoglobulin G (IgG) was located in the Fc fragment and one-third in the `hinge' region of the γ (heavy) polypeptide chain at the junction of the Fab and Fc fragments. In contrast, bovine IgG contained more hexose in the `hinge' region than in the Fc fragment. The initial cleavage of susceptible IgG molecules into Fab and Fc fragments by papain under the conditions given by Porter (1959) had reached completion after digestion for 2hr., though bovine IgG was digested somewhat more slowly than human or rabbit IgG. The release of `hinge' peptides from human and rabbit IgG had also reached completion by 2hr., but was slower from bovine IgG and continued for several hours longer. Since bovine IgG molecules contained on the average a greater amount of hexose in the `hinge' region, carbohydrate on this part of the γ-chain may influence not only the initial rate of enzymic hydrolysis into Fab and Fc fragments, but also, and to a greater extent, the rate of further limited hydrolysis of the N-terminal regions of the Fc fragment. The presence of carbohydrate in the `hinge' region does not appear to account for the resistance of some IgG molecules to papain digestion and of some Fc fragments to N-terminal degradation.     

The binding of lanthanides to non-immune rabbit immunoglobulin G and its fragments.

The binding of Gd(III) to rabbit IgG (immunoglobulin G) and the Fab (N-terminal half of heavy and light chain), (Bab')2 (N-terminal half of heavy and light chains joined by inter-chain disulphide bond), Fc (C-terminal half of heavy-chain dimer)and pFc' (C-terminal quarter of heavy-chain dimer) fragments was demonstrated by measurements of the enhancement of the solvent-water proton relaxation rates in the appropriate Gd(III) solutions. At pH 5.5 there are six specific Gd(III)-binding sites on the IgG. These six sites can be divided into two classes; two very 'tight' sites on the Fc fragment (Kd approx. 5 muM) and two weaker sites on each Fab region (Kd approx. 140 muM). Ca(II) does not apparently compete for these metal-binding sites. The metal-binding parameters for IgG can be explained as the sum of the metal binding to the isolated Fab and Fc fragments, suggesting that there is no apparent interaction between the Fab and Fc regions in the IgG molecule. The binding of Gd(III) to Fab and Fc fragments was also monitored by measuring changes in the electron-spin-resonance spectrum of Gd(III) in the presence of each fragment and also by monitoring the effects of Gd(III) on the protein fluorescence at 340 nm (excitation 295 nm). The fluorescence of Tb(III) solutions of 545 nm (excitation 295 nm) is enhanced slightly on addition of Fab or Fc.     

L445P mutation on heavy chain stabilizes IgG4 under acidic conditions

ABSTRACT

IgG₄, a common type of therapeutic antibody, is less stable during manufacturing processes compared with IgG₁. Aggregation and fragmentation are the two main challenges. Here, we report instability of the heavy chain (HC) C-terminal region under acidic conditions, which leads to cleavage and aggregation. Leu⁴⁴⁵, at the C-terminal region of the HC in IgG_4, plays a critical role in its acid-induced fragmentation and subsequent aggregation. We found that mutating HC C-terminal Leu⁴⁴⁵ to Pro (the corresponding residue in IgG₁) in IgG₄_CDR-X significantly reduces fragmentation and aggregation, while mutating Pro⁴⁴⁵ to Leu in IgG₁_CDR-X promotes fragmentation and aggregation. HC C-terminal Gly⁴⁴⁶ cleavage was observed in low pH citrate buffer and resulted in further fragmentation and aggregation, whereas, glycine buffer can completely inhibit the cleavage and aggregation. It is proposed that cleavages occur through acid-induced hydrolysis under acidic conditions and glycine stabilizes IgG₄ via two main mechanisms: 1) product feedback inhibition of the hydrolysis reaction, and 2) stabilization of protein conformation by direct interaction with the peptide backbone and charged side chains. Experiments using IgG₄ molecules IgG₄_CDR-Y and IgG₄_CDR-Z with the same CH domains as IgG₄_CDR-X, but different complementarity-determining regions (CDRs), indicate that the stability of the HC C-terminal region is also closely related to the sequence of the CDRs. The stability of IgG₄_CDR-X is significantly improved when binding to its target. Both observations suggest that there are potential interactions between Fab and CH2-CH3 domains, which could be the key factor affecting the stability of IgG antibodies.     

Solution structures of human myeloma IgG3 antibody reveal extended Fab and Fc regions relative to the other IgG subclasses

Human immunoglobulin G subclass 3 (IgG3) possesses a uniquely long hinge region that separates its Fab antigen-binding and Fc receptor-binding regions. Owing to this hinge length, the molecular structure of full-length IgG3 remains elusive, and the role of the two conserved Fc glycosylation sites are unknown. To address these issues, we subjected glycosylated and deglycosylated human myeloma IgG3 to multidisciplinary solution structure studies. Using analytical ultracentrifugation, the elongated structure of IgG3 was determined from the reduced sedimentation coefficients s⁰_20,w of 5.82 to 6.29 S for both glycosylated and deglycosylated IgG3. X-ray and neutron scattering showed that the Guinier R_G values were 6.95 nm for glycosylated IgG3 and were unchanged after deglycosylation, again indicating an elongated structure. The distance distribution function P(r) showed a maximum length of 25 to 28 nm and three distinct maxima. The molecular structure of IgG3 was determined using atomistic modeling based on molecular dynamics simulations of the IgG3 hinge and Monte Carlo simulations to identify physically realistic arrangements of the Fab and Fc regions. This resulted in libraries containing 135,135 and 73,905 glycosylated and deglycosylated IgG3 structures, respectively. Comparisons with the X-ray and neutron scattering curves gave 100 best-fit models for each form of IgG3 that accounted for the experimental scattering curves. These models revealed the first molecular structures for full-length IgG3. The structures exhibited relatively restricted Fab and Fc conformations joined by an extended semirigid hinge, which explains the potent effector functions of IgG3 relative to the other subclasses IgG1, IgG2, and IgG4.     

Intrachain disulphide bridges in immunoglobulin G heavy chains. The Fc fragment

The disulphide bridges of the Fc fragment (C-terminal half of the heavy chain) have been studied in several human immunoglobulins, containing heavy chains of different antigenic types (gamma1, gamma2, gamma3 and gamma4), and in heavy-chain-disease proteins. Two intrachain disulphide bridges were found to be present. The sequences appear to be identical in the Fc fragments of two types of chain studied (gamma1 and gamma3), and very similar to corresponding sequences of the Fc fragment in rabbit. These results suggest that the C-terminal half of the heavy chains is covalently folded (in a similar fashion to the light chains) with a C-terminal loop and an N-terminal loop. The similarity is emphasized by comparison of the sequence and location of the disulphide-bridged peptides of the C-terminal loop of heavy and light chains. The N-terminal loop, on the other hand, appears to be very different in Fc fragments and light chains. The C-terminal loop is the only one present in the F'c fragment.     

Energy transfer distance measurements in immunoglobulins. II. Localization of the hapten binding sites and the interheavy chain disulfide bond in rabbit antibody

The distance between the hapten combining site and the single interheavy chain disulfide bond in rabbit immunoglobulin G has been determined by measuring the efficiency of energy transfer between chromophores specifically attached at these sites on the molecule. The donor chromophore, DnsLys³, was non-covalently bound in the combining sites of high-affinity antiDns antibody molecules, in one case, and in the combining site of the pepsin Fab′ fragment of antiDns in another. The acceptor chromophore, fluorescein, was covalently attached by disulfide interchange of di-FlCys with sulfhydryls generated by selective reduction of the interheavy chain disulfide bond of whole antiDns antibody and of the (Fab′)₂ pepsin fragment. The presence of acceptor decreased the donor fluorescence lifetime by about 1.0 nanosecond in both cases, i.e. for the whole antibody, from 23.6 to 22.7 nanoseconds, and for the Fab′ fragment from 23.6 to 22.5 nanoseconds. An average separation distance of 81 Å was calculated from an average observed transfer efficiency of 3.7%. This value agrees closely with the over-all length of a Fab′ fragment of a human IgG myeloma protein (Poljak et al., 1972). These results strongly suggest that the antibody combining site is at, or very close to, the tip of the Fab fragment and that the inter-heavy chain disulfide bond is at or near the edge of the C_L?C_H1 domain.     

Analysis of Bacterial Immunoglobulin-Binding Proteins by X-Ray Crystallography

Protein crystallography offers a powerful means of analyzing the molecular mechanisms that underlie the action of bacterial immunoglobulin-binding proteins. Successful approaches used to date involve the isolation of individual IgG-binding domains from the immunoglobulin-binding protein under study and the crystallization of these on their own or in complex with Fc or Fab fragments. Two structures of complexes that have been determined to high resolution by protein crystallography are compared. A single IgG-binding domain from protein A (from Staphylococcus) binds to a human Fc fragment through formation of two α-helices, which bind in the cleft between the CH2 and the CH3 domains. Recognition is mediated by side chains on protein A which interact with conserved side chains on the surface of the antibody, ensuring binding to IgG molecules from different subclasses and species. A similar analysis of the complex of a single IgG-binding domain from protein G (from Streptococcus) with an Fab fragment from mouse IgG1 reveals that the same problem in molecular recognition is tackled in a different way. Protein G binds via an antiparallel alignment of β-strands from the IgG-binding domain and the CH1 domain in Fab: this main chain-main chain interaction is supported by a number of specific hydrogen bonds between the side chains in both proteins. By recognition of a high proportion of main-chain atoms, protein G minimizes the effects of IgG sequence variability in a way that is distinct from that adopted by protein A.     

Glycosylation in the Fc domain of IgG increases resistance to proteolytic cleavage by papain

IgG antibodies (Abs) and fragments of IgG Abs are becoming major biotherapeutics to treat an assortment of human diseases. Commonly prepared fragments of IgGs include Fc, Fab, and F(ab')2 fragments, all of which can be made using the sulfhydryl protease papain, although prolonged digestion times and/or excessive amounts of papain typically result in further cleavage of the Fc domain into smaller fragments. During our attempts to use papain to isolate Fc fragments from different IgG monoclonal Abs, it was observed that prior removal of Fc glycans resulted in a faster rate of papain-mediated degradation of the Fc domain. Subsequent time-course experiments comparing glycosylated and deglycosylated versions of IgG antibodies showed that the majority of molecules in a deglycosylated IgG sample were converted into Fab, Fc, and smaller Fc fragments in less than one hour, whereas the original glycosylated IgG required more than two hours to convert into a comparable amount of Fab and Fc fragments. Furthermore, whereas papain digestion converted almost all of a deglycosylated Fc fragment into smaller fragments of approximately 10 and approximately 12 kDa within 4 h, more than 40% of a glycosylated Fc fragment remained intact even after 24 h of digestion. These results indicate that the presence of CH(2) domain glycans in either IgGs or purified Fc fragments increases resistance to papain digestion. Increased sensitivity of non-glycosylated Fc domains to papain is consistent with the Fc domains lacking a defined structure, as exemplified by their inability to bind Fcgamma receptors, since misfolded proteins are often degraded by proteases because of increased accessibility of their proteolytic cleavage sites. Based on these observations it is possible to use papain sensitivity as a means of assessing proper Fc structure of IgG molecules.     

Strain differences in tolerance induction to human gamma-globulin subclasses: dependence on macrophages.

BALB/c and DBA/2 mice differ with respect to ease of tolerance induction with HGG, BALB/c mice being the resistant strain. When tested for susceptibility to tolerance induction with individual IgG subclasses, both strains were easily rendered unresponsive with IgG₁ and IgG₂ and less so with IgG₄. A strain difference appeared with IgG₃, where only BALB/c mice showed complete resistance to tolerance induction. Mixtures of the IgG subclasses Showed that IgG₁ and IgG₂ accounted for most of the tolerance to whole HGG seen in both strains, while addition of IgG₃ to the mixture made DBA/2 completely tolerant but reversed the trend toward tolerance in the BALB/c mice. By rosette assay it was found that BALB/c macrophages had receptors for IgG₃ (and to a lesser extent for IgG₄). These results are consistent with the hypothesis that resistance to tolerance induction with HGG is dependent on the presence of a receptor on the macrophage for a minor IgG subclass.     

The disulphide bridges of a mouse immunoglobulin G1 protein

[(35)S]Cystine-labelled immunoglobulin MOPC21 (IgG1) was prepared from myeloma cells in tissue culture. Carrier myeloma protein was added and the protein was digested with pepsin. The digest was fractionated on Sephadex G-50 into two fractions, further digested with trypsin and again fractionated on Sephadex. Disulphide-bridge peptides were purified by electrophoresis and chromatography and identified by radioautography. A peptide of 96 residues was isolated, which contains both the heavy-light interchain disulphide bridge and all the inter-heavy-chain disulphide bridges. Other peptides were isolated, accounting for all the intrachain disulphide bridges (which could be placed by homology with proteins of other species), except for the variable section of the light chain. Sequences describing this missing disulphide bridge were obtained from totally reduced and alkylated light chains. Peptides related to the interchain disulphide-bridge peptide were isolated from partially reduced and alkylated myeloma protein and from totally reduced heavy chain. The interchain disulphide-bridge peptide was placed at the C-terminal position of the F(ab')(2) fragment, prepared by digestion of the protein with pepsin at pH4.0. Sequences from the heavy-chain intrachain disulphide bridges of MOPC 21 immunoglobulin are compared with homologous sequences from mouse myeloma proteins of other subclasses and proteins of other species.     

Comparison of the structure of the immunoglobulins from horse serum

A study of the chemical structure of the horse immunoglobulins IgG and IgA(T) has shown that the amino acid contents of the peptide chains are very similar. These globulins differ most markedly in the products of papain digestion. IgG gives 3.5s products, whereas IgA(T) gives a 5s fraction and smaller components. This difference appears to be associated with the presence of an additional easily reducible disulphide bond in the Fd fragment of the heavy chain. There is two to three times as much carbohydrate in IgA(T) as in IgG. In both, this is in the heavy chain and in IgA(T) more than half is covalently bound to the Fd fragment. The differences in antigenic specificity between horse IgG and IgA(T) appear to be due to structural differences in the Fc fragment.     

Acid-induced aggregation propensity of nivolumab is dependent on the Fc

Nivolumab, an anti-programmed death (PD)1 IgG₄ antibody, has shown notable success as a cancer treatment. Here, we report that nivolumab was susceptible to aggregation during manufacturing, particularly in routine purification steps. Our experimental results showed that exposure to low pH caused aggregation of nivolumab, and the Fc was primarily responsible for an acid-induced unfolding phenomenon. To compare the intrinsic propensity of acid-induced aggregation for other IgGs subclasses, tocilizumab (IgG₁), panitumumab (IgG₂) and atezolizumab (aglyco-IgG₁) were also investigated. The accurate pH threshold of acid-induced aggregation for individual IgG Fc subclasses was identified and ranked as: IgG₁?1?2?4. This result was cross-validated by thermostability and conformation analysis. We also assessed the effect of several protein stabilizers on nivolumab, and found mannitol ameliorated the acid-induced aggregation of the molecule. Our results provide valuable insight into downstream manufacturing process development, especially for immune checkpoint modulating molecules with a human IgG₄ backbone.     

Structural and genetic analysis of four chicken 7S immunoglobulin allotypes

Four 7S immunoglobulin allotypic specificities in three inbred chicken lines were demonstrated in two immunoglobulin regions, probably associated with the heavy chains. Two specificities were associated with papain-produced Fab fragments, most likely the Fd fragment since they were not demonstrated on the 17S immunoglobulin. The other allotypes were detected only on intact 7S immunoglobulin and were undetectable on the Fab and Fc fragments; therefore, they probably were associated with a region of the heavy chain sensitive to papain digestion. Among F₂ hybrids, these specificities segregated in a manner statistically indistinguishable from that expected of three codominant alleles at an autosomal locus. This locus was not closely associated with any of five chicken blood group loci.     

The Solution Structures of Two Human IgG1 Antibodies Show Conformational Stability and Accommodate Their C1q and FcγR Ligands

The human IgG1 antibody subclass shows distinct properties compared with the IgG2, IgG3, and IgG4 subclasses and is the most exploited subclass in therapeutic antibodies. It is the most abundant subclass, has a half-life as long as that of IgG2 and IgG4, binds the FcγR receptor, and activates complement. There is limited structural information on full-length human IgG1 because of the challenges of crystallization. To rectify this, we have studied the solution structures of two human IgG1 6a and 19a monoclonal antibodies in different buffers at different temperatures. Analytical ultracentrifugation showed that both antibodies were predominantly monomeric, with sedimentation coefficients s_20,w⁰ of 6.3–6.4 S. Only a minor dimer peak was observed, and the amount was not dependent on buffer conditions. Solution scattering showed that the x-ray radius of gyration R_g increased with salt concentration, whereas the neutron R_g values remained unchanged with temperature. The x-ray and neutron distance distribution curves P(r) revealed two peaks, M1 and M2, whose positions were unchanged in different buffers to indicate conformational stability. Constrained atomistic scattering modeling revealed predominantly asymmetric solution structures for both antibodies with extended hinge structures. Both structures were similar to the only known crystal structure of full-length human IgG1. The Fab conformations in both structures were suitably positioned to permit the Fc region to bind readily to its FcγR and C1q ligands without steric clashes, unlike human IgG4. Our molecular models for human IgG1 explain its immune activities, and we discuss its stability and function for therapeutic applications.     

Structural studies of a human hybrid immunoglobulin

The structure of an hypothesized hybrid or “Lepore-type” IgG contained in the serum of donor 2904 was investigated. Previous immunological studies suggested that this serum contained IgG with aγ3-γ1 hybrid heavy chain consisting of aγ3 Fd portion and aγ1 Fc. Structural studies have now shown that the carboxyl terminal end of the 2904 hybrid IgG, including much of the Fc fragment, isγ1 in character. However, the fingerprints of the Fc tryptic peptides at both pH 3.6 and pH 6.4 included a peptide, possibly from the hinge region, in peptide maps of Fc from aγG3 Gm (5) myeloma protein, but absent from maps of Fc peptides fromγG1 proteins. Gel filtration of the CNBr fragments of Fc from 2904 suggested that the hinge region isγ3-like. Papain cleavage experiments indicated an elevated level of resistant IgG, which agrees with immunological findings of an increasedγG2 subclass level. Our data confirm previous reports that theγ chain C-terminal octadecapeptides fromγG3 proteins have a subclass specific residue of arginine and indicate that within this subclass there is an allotypic variation related to the Gm type of the protein.     

High-affinity binding of seminal plasma PSP94 to human immunoglobulin is through the Fab domain

Prostate secretory protein of 94 amino acids (PSP94) is one of the major proteins present in human seminal plasma. We had earlier reported that PSP94 has the ability to bind to human IgG. The aims of the present study were to further delineate the PSP94–IgG interaction and to understand whether this could have any significance in sperm function. Direct binding of IgG fragments to PSP94 showed maximal binding with F(ab′)₂ followed by Fab, while Fc displayed least binding in ELISA. Binding kinetics of PSP94–IgG interaction using surface plasmon resonance (SPR) revealed high-affinity binding of IgG to PSP94 with a dissociation constant (K_D) of 8.8 × 10⁻¹¹ M. PSP94–IgG interaction was found to be through the Fab domains of IgG. Real-time interaction kinetics revealed association constants for binding of IgG, Fab, and F(ab′)₂ towards PSP94 to be of the same order but with altered dissociation constants. IgG and its F(ab′)₂ fragment once complexed to PSP94 demonstrated negligible dissociation, while dissociation rate of Fab fragment was 6.6 × 10⁻⁴. In silico molecular modeling of PSP94–IgG complex identified N- and C-terminal β-strands of PSP94 to be the most plausible region involved in IgG interaction. Immunofluorescence studies revealed that IgG bound to human spermatozoa predominantly in the tail region, which could be prevented when IgG was preincubated with PSP94. This study reports for the first time that IgG forms a high-affinity complex with PSP94 through its F(ab′)₂ domain and reveals the ability of PSP94 to prevent binding of IgG to spermatozoa.     

Physiochemical characterization of proteolytic cleavage fragments of bovine colostral immunoglobulin G1 (IgG1).

Normal bovine colostral immunoglobulin G1 was subjected to enzymic digestion (pepsin, papain and trypsin) and the resulting fragments separated by a combination of molecularsieve and phosphocellulose chromatography.Fragments F(ab')2 derived from peptic digestion, fragment Fab from papain digestion and fragment Fab(t) from tryptic digestion showed complete antigenic identity with each other. Although fragment F(ab')2 (peptic digestion) had a sedimentation coefficient (S2o,w) of 5.3S, those for fragments Fab' (peptic digestion), Fab (papain digestion) and Fab(t) (tryptic digestion) were found to be 3.9S, 3.7S and 3.7S respectively. The mol.wts. calculated for the various fragments from the sedimentation equilibrium data were: F(ab')2, 104000 +/-200; Fab', 51900+/-340; Fab, 50900+/-230; Fab(t) 50900+/-300. Fragment Fc' (peptic digestion) had an S20,w of 3.2S and a mol. wt. of 42900+/-650; fragment Fc (papain digestion) had an SI0,w of 3.7S and a mol.wt. of 50800+/-300; fragment Fc(t) had an S20,w of 3.7S and a mol.wt. of 50800+/-300; fragment Fc(t) had an S20,w of 3.7S and a mol.wt. of 50800+/-450.     

Solution structure of deglycosylated human IgG1 shows the role of CH2 glycans in its conformation

The human immunoglobulin G (IgG) class is the most prevalent antibody in serum, with the IgG1 subclass being the most abundant. IgG1 is composed of two Fab regions connected to a Fc region through a 15-residue hinge peptide. Two glycan chains are conserved in the Fc region in IgG; however, their importance for the structure of intact IgG1 has remained unclear. Here, we subjected glycosylated and deglycosylated monoclonal human IgG1 (designated as A33) to a comparative multidisciplinary structural study of both forms. After deglycosylation using peptide:N-glycosidase F, analytical ultracentrifugation showed that IgG1 remained monomeric and the sedimentation coefficients s⁰_20,w of IgG1 decreased from 6.45 S by 0.16–0.27 S. This change was attributed to the reduction in mass after glycan removal. X-ray and neutron scattering revealed changes in the Guinier structural parameters after deglycosylation. Although the radius of gyration (R_G) was unchanged, the cross-sectional radius of gyration (R_XS-1) increased by 0.1 nm, and the commonly occurring distance peak M2 of the distance distribution curve P(r) increased by 0.4 nm. These changes revealed that the Fab-Fc separation in IgG1 was perturbed after deglycosylation. To explain these changes, atomistic scattering modeling based on Monte Carlo simulations resulted in 123,284 and 119,191 trial structures for glycosylated and deglycosylated IgG1 respectively. From these, 100 x-ray and neutron best-fit models were determined. For these, principal component analyses identified five groups of structural conformations that were different for glycosylated and deglycosylated IgG1. The Fc region in glycosylated IgG1 showed a restricted range of conformations relative to the Fab regions, whereas the Fc region in deglycosylated IgG1 showed a broader conformational spectrum. These more variable Fc conformations account for the loss of binding to the Fcγ receptor in deglycosylated IgG1.