Enzymatic Fragmentation of an Unusual Human IgG2 (Kva) Myeloma Protein

The Kva IgG2(k) myeloma protein showed a complete resistance to papain in the presence of cysteine at neutral pH, and a higher resistance to trypsin and alpha-chymotrypsin digestion than other IgG2 proteins. On the other hand, the Kva molecule was cleaved by pepsin at low pH to give the expected F(ab')2 fragment. When the cleavage conditions were altered, it was possible to obtain Fab, Fc, and Fc' fragments from this molecule as well. The Fab/c fragment and FacbFc' complex were also obtained, which have not previously been reported from human IgG2 molecules. Incubation at elevated temperatures (45-50 degrees C) and/or lower pH resulted mainly in enzymatic attack on the C terminal side of the hinge. It was necessary to destroy the hinge by reduction or to expose the Kva molecule at 70 degrees C or at lower pH (2.5) prior to digestion to facilitate enzyme digestion on the NH2 terminal side of the hinge. These results indicate that the hinge region of the Kva molecule has an unusually compact structure, which makes it extremely resistant to proteolysis.     

Kinetics of the Different Susceptibilities of the Four Human Immunoglobulin G Subclasses to Proteolysis by Human Lysosomal Elastase

Human lysosomal clastase cleaves human monoclonal IgG into components that closely resemble the fragments produced by papain digestion IgG1 produced Fab, Fe and Fab-Fc fragments; cleavage of IgG2 produced Fab-Fc, Fab and Fc fragments: IgG3 gave rise to almost pure Fab und Fch (Fc covalently Joined to the extended hinge region polypetide of IgG3). and from IgG4, F(ab)₂, Fab and Fc fragments were recovered. The relative susceptibilities of the four human IgG subclasses to proteolytic attack by elastase were studied kinetically and showed the following decrease order of susceptibility: IgG3 >IgG1 >IgG2 >IgG4. The Fab fragment from papain digestion of IgG1 and the corresponding fragment from clastase digestion showed indistinguishable molecular weights and immunochemical identity     

Phagocytosis of target particles bearing C3b-IgG covalent complexes by human monocytes and polymorphonuclear leucocytes.

Immunoglobulin G (IgG) provides an efficient acceptor site for nascent C3b, and complement activation on the surface of IgG-coated bacteria has been shown to generate significant numbers of C3b-IgG complexes. We have studied the relative efficiency of IgG alone, C3b-IgG complexes, and similar densities of IgG and C3b residues deposited independently, in mediating ingestion of sheep erythrocyte (E) targets by human phagocytes. Human 125I-C3b covalently bound to rabbit anti-Forssman IgG was generated as described elsewhere (Fries et al., 1985). E,EIgMC4b, or EIgMC4b3b (prepared with IgM antibody and purified complement components) were sensitized with radiolabelled anti-Forssman IgG or C3b-IgG heterodimers to generate targets bearing IgG alone, C3b-IgG covalent complexes, or C3b and IgG in equivalent numbers but not bound to each other. Phagocytosis by monocytes and polymorphonuclear leucocytes (PMN) of targets bearing C3b-IgG was markedly enhanced relative to those bearing IgG alone, especially at levels of less than 2000 opsonin residues/target cell. Uptake of C3b-IgG-bearing targets was also significantly more resistant to competitive inhibition by ambient monomeric IgG. Phagocytosis of EIgMC4b + C3b-IgG by monocytes was superior to the uptake of either EAC4b + IgG or EAC4b3b + IgG bearing equivalent amounts of C3b and IgG not in covalent complex (P less than 0.05, n = 10). Similar results were obtained with PMN. Thus, generation of C3b-IgG complexes in vivo may not only promote complement activation and enhance C3b deposition, but also produce a compound opsonic residue which is a more potent promoter of phagocytosis than an equal number of C3b and IgG residues randomly distributed relative to each other.     

Composition of immune deposits present in glomeruli of NZB/W F1 mice

This paper describes the results of experiments designed to investigate the composition of immune complexes present, in the form of immune deposits, in glomeruli of NZB/NZW F1 mice. Granular deposits of mouse IgG were present along the glomerular capillary walls of 6- to 12-month-old mice. Disappearance of mouse IgG from glomerular deposits, indicating a dissociation of immune complexes, was observed following incubation of kidney sections with an excess of mouse IgG, mouse Fc fragments, rat IgG, and rat Fc fragments, but not with human and rabbit Cohn fraction-II (FII), DNA, nucleohistone, and PBS. Antinuclear antibody activity in mouse sera or in glomerular eluates was removed by absorption with mouse IgG or mouse Fc fragments, rat IgG or rat Fc fragments, DNA, and nucleo-histone, but not by absorption with human or rabbit FII. These results suggest that the IgG antinuclear antibodies present in the sera and in glomerular deposits possess rheumatoid factor (RF) activity. In other experiments, kidney sections were incubated with various concentrations of pepsin, which digests the Fc portion of the IgG. After digestion, the sections were washed and stained for mouse IgG, IgG F(ab')2, and IgG Fc. At concentration of 10 micrograms/ml, pepsin completely removed IgG and IgG Fc, whereas faint IgG F(ab')2 deposits persisted in glomerular deposits. At the concentration of 1 microgram/ml, deposits of mouse IgG, F(ab')2, and Fc persisted, while F(ab')2 was observed bound to nuclei of glomerular cells. At the pepsin concentration of 0.1 microgram/ml or 0.01 microgram/ml, IgG F(ab')2 was bound to the nuclei of glomerular and tubular cells, indicating that the digestion of the Fc portion of IgG had released F(ab')2 with nuclear reactivity from glomerular deposits. The solubilization of mouse IgG from glomerular immune deposits with mouse IgG and the demonstration that pepsin digestion releases mouse F(ab')2 with nuclear reactivity are consistent with the interpretation that the immune deposits present in glomeruli of NZB/NZW F1 mice contain complexes formed by antinuclear IgG and IgG RF. These two antibodies probably cross-react and form multilayer aggregates which contribute to the formation of immune deposits.     

Differential binding characteristics of protein G and protein A for Fc fragments of papain-digested mouse IgG

It has been previously reported that staphylococcal protein A (SPA) bound only to the Fc region of mouse immunoglobulin G (IgG) and streptococcal protein G (SPG) bound to both Fab and Fc regions of mouse IgG and the binding sites for SPG and SPA on Fc were overlapped. In this study the binding characteristics of SPG and SPA for papain-digested mouse IgG were analysed. Papain digestion of mouse IgG purified from CAy-IFNg99C hybridoma (secreting IgG1 monoclonal antibody specific for human interferon gamma)-induced ascites resulted in Fab and two major Fc fragments referred to as the high molecular weight (HMW) and the low molecular weight (LMW) Fc fragments. SPG bound to Fab and the LMW Fc fragments of the papain-digested IgG. However SPG did not bind to the HMW Fc fragment. SPA showed practically no reactivity with the Fab and the LMW Fc fragments of the papain-digested mouse IgG but only to the HMW Fc fragment. SPG and SPA binding assays showed that papain digestion discriminated the SPG and SPA binding sites in the Fc fragment of mouse IgG. These results demonstrated a clear evidence for the presence of two independent SPG and SPA binding sites in the Fc fragment of mouse IgG.     

Interactions of monomeric IgG bearing covalently bound C3b with polymorphonuclear leucocytes.

The interactions of monomeric IgG, monomeric C3b, dimeric C3b, and C3b covalently bound to IgG (C3b-IgG) with neutrophils were examined. C3b-IgG heterodimers exhibited an increased affinity of binding to neutrophils, relative to C3b, both at half normal ionic strength (five-fold enhancement) and at normal ionic strength (six-fold enhancement). Binding of monomeric IgG to neutrophils was barely detectable and did not permit direct measurements of affinity in our assay conditions. The increased affinity of C3b-IgG for neutrophils was the result of divalent interactions with CR1, the C3b receptor, and the Fc gamma receptor of the cells, as could be demonstrated by competition studies using unlabelled IgG in the medium or monoclonal antibodies against the neutrophil Fc gamma receptor. This double receptor-ligand interaction allowed C3b-IgG to bind to the cells not only at normal ionic strength, but also in the presence of a 315-fold excess of IgG (near plasma concentration)--conditions that would preclude the binding of C3b or IgG alone. Furthermore, this interaction leads to the internalization of the C3b-IgG complex by the cells. C3b-IgG is internalized with kinetics similar to those found using dimeric C3b, with resting cells demonstrating a slow initial phase, which is accelerated by phorbol ester activation in both cases. Uptake of the homodimeric C3b was greater at 15 min than that of heterodimeric C3b-IgG, but both were significantly greater than that of monomer C3b, which showed no net internalization. The physiological implications of these findings are discussed.     

The activation of complement components by aggregates of antibodies and their fragments

The relative consumption of the complement components C1, C2, C3 and C4 from guinea pig serum on addition of rabbit antibody-antigen aggregates, papain digested aggregates, heat aggregated rabbit IgG and Fc has been measured. It has been found that antibody-antigen aggregates are much more efficient with respect to consumption of all four components than heat aggregated IgG which in turn is more efficient than heat aggregated Fc. In the latter two preparations the inefficiency is most marked with C2 and C3 consumption. The results suggest that splitting of C2 may depend on prior association with bound C4b which yields a bound C42 complex to the Fab section of the aggregated antibody.     

The covalent interaction of C3 with IgG immune complexes

Antigens (Ags) are converted into immune complexes (antigen-antibody complexes, IC) as soon as they encounter their specific antibodies (Abs). In fluids containing complement, the process of IC formation and fixation of complement components occur simultaneously. Hence, the formation of Ag-Ab-complement complexes is the normal way of eliminating Ags from a host. C3b-C3b-IgG covalent complexes are immediately formed on interaction of serum C3 with IgG-IC. These C3b-C3b dimers constitute the core for the assembly of C3/C5-convertase on the IC, which are subsequently converted into iC3b-iC3b-IgG by the complement regulators. These complexes are detected on SDS-PAGE by two bands of molecular composition, C3alpha65-C3alpha43 (band A) and C3alpha65-heavy chain of the Ab (band B), which correspond to C3b-C3b and C3b-IgG covalent interaction respectively, and that identify opsonized IC (C3b-IC). C3b can attach to Fab and Fc regions of the Ab molecule with similar efficiency. The presence of multiple C3b binding regions on IgG is considered an advantageous characteristic that facilitates the elimination of Ags in the form of C3b(n)-IC. Ab molecules on the IC recognize the Ag, and also serve as a very good acceptor for C3b binding. In this way, Ags, even if they have no acceptor sites for C3b, can be efficiently processed and removed. When C3 is activated in serum by IC or other activators, secondary C3b-IgG covalent complexes are generated, with bystander monomeric circulating IgG, and thus constitute, physiological products of complement activation. These complexes gain importance when IgG concentration is extremely high as in cases of infusion of intravenous IgG (IVIG) in several pathologies. The covalent attachment of activated complement C3 (C3b, iC3b, C3 d,g) to Ags or IC links innate and adaptative immunity by targeting Ags to different cells of the immune system (follicular dendritic cells, phagocytes, B cells). Hence C3b marks Ags definitively, from the earliest contact with the innate immune system until their complete elimination from the host.     

the heterogeneity of bovine IgG2—IV. Structural differences between IgG2a molecules of the A1 and A2 allotypes

The major product of digestion of bovine IgG2a(A1) with immobilized pepsin is F(ab')₂ while similar treatment of IgG2a(A2) yields Fab, Fc and other products. It is postulated that structural differences in the hinge region, including the absence of the most N-terminal disulfide bridge in IgG2a(A2) and a displacement of the primary pepsin cleavage site toward the Fd, can explain this effect. The immunodominant A1 allotope(s) appears to be located in the CH3 domain of IgG2a(A1) while the A2 allotopes are located elsewhere and are apparently affected by digestion. The allotypic bias of rabbit anti-IgG2a is also present in anti-IgG2a raised in goats. However, the A2 allotypic determinants of bovine IgG2a are recognized by goat precipitins although precipitins of this specificity are not detectable in rabbits immunized with IgG2a(A2). Rabbit anti-A2 antibodies are detectable using the ELISA in rabbits immunized with IgG2a(A2).     

The reaction of rheumatoid factor with bovine IgG fragments obtained by papain digestion and by reduction

1. The fragments produced from bovine IgG^* by papain digestion and by reduction were similar to those from human IgG.

2. The Fab^* and Fc^* fragments produced by papain digestion and the light chains produced by reduction of bovine IgG did not react with rheumatoid factor.

3. The heavy chains produced by reduction reacted with rheumatoid factor, but did not inhibit the reaction of whole bovine IgG with rheumatoid factor.

4. The difference between the reactions of human and bovine Fc fragments with rheumatoid factor is discussed. It is suggested that the major site in bovine IgG with which rheumatoid factor combines is on the heavy chain in the region of the junction of the Fab and Fc subunits.

     

Fragmentation of human IgG by a new protease isolated from the basidiomycete Armillaria mellea.

Digestion of human IgG by a new lysine-specific protease, isolated from the basidiomycete Armillaria mellea, produced Fc and Fab fragments similar to those produced by papain digestion of the same molecule. Digestion appeared to be restricted to a single cleavage point within the hinge region of the IgG molecule. Myeloma proteins of IgG1, IgG3 and IgG4 subclasses were found to be digested at an extremely rapid rate whereas IgG2 myeloma proteins appeared to be resistant to digestion by this enzyme.     

Conformation of the Hinge Region and Various Fragments of Human IgG3

A study of the circular dichroic (CD) spectra of various fragments of human IgG3, including the isolated hinge region, Fh, has shown that the hinge region has a high degree of an unusual secondary structure, unique within immunoglobulin material recorded to date. This structure appears to be rigid and aperiodic throughout the hinge region and is compatible with a repeated amino acid sequence. The conformation of the isolated Fh fragment is the same as that of the bound hinge region; also, there is no substantial conformational interaction between the hinge region and the Fab or Fc fragments of human Igtg3. a comparison of the CD spectra of Fc and pFc fragments isolated from an IgG1 and an IgG3 myeloma protein has shown that subclass differences of amino acid sequence do not substantially alter the conformation of these fragments.     

Binding of Fragments of Human IgG to Solid-phase C3b Measured by Enzyme-linked Immunosorbent Assay (ELISA)

The binding of human IgG and different fragment of IgG to C3b adsorbed in polystyrene tubes has been studied by the enzyme-linked immunosorbent Heat-denatured polyclonal IgG and F(ab')₂ and Fab fragments of IgG bound to solid-phase C3b Heat-denatured Fc fragments of IgG also had some reactivity with C3b, but at significantly higher concentrations than F(ab')₂ and Fab fragments. The binding of heat-denatured IgG could not be completely inhibited by the addition of heat-denatured F(ab')₂ fragments in tenfold excess The results suggest that the binding of heat-denatured IgG to solid-phase C3b is mediated through the Fab and Fc portions binding of denatured IgG to solid-phase C3b is mediated through the Fab and Fc portions of IgG molecules.     

Formation of covalently linked C3-C3 dimers on IgG immune aggregates

Upon activation of the complement system by IgG immune aggregates several components become tightly bound to the aggregates. The covalent interaction of C3 with immune complexes is essential for the solubilization and inhibition of immune precipitation of the complexes. It has recently been reported that on erythrocytes that have a fixed complement, activated C3 can become involved in the formation of C3b-C3b covalent dimers, which acts as high-affinity binding sites for C5 (Kinoshita, T., Takata, Y., Kozono, H., Takeda, J., Hong, K. and Inoue, K., J. Immunol. 1988 141: 3895). To characterize the molecular composition of immune aggregates that have fixed complement by the alternative pathway, we have investigated whether such C3b-C3b dimers are formed in IgG immune complexes. For this purpose immune aggregates bearing covalently bound C3 were analyzed by two-dimensional gel electrophoresis and the resolved bands transferred to polyvinylidene difluoride membranes and sequenced. When immune aggregates were incubated with serum for 15 min at 37 degrees C, the major high-molecular mass bands detected by gel electrophoresis corresponded to heavy chain-C3 alpha 65 and C3 alpha 65-C3 alpha 43 (derived from iC3b-iC3b-IgG) covalent complexes. If K76COONa, an inhibitor of factor I, was added to the serum, before incubation with the immune complexes, then the major C3 alpha fragment detected on the complexes corresponded to the C3 alpha' chain (105 kDa) and not C3 alpha 65. Hence C3b-C3b covalent dimers are readily formed on the immune aggregates incubated with normal human serum, and are degraded to iC3b-iC3b by factor I. The second C3b molecule was shown to be bound to the C3 alpha 43 region (C-terminal portion of the C3 alpha' chain) of the first C3b molecule, which was itself covalently bound to the heavy chain of IgG. Covalent complexes of heavy chain-(C3 alpha 65)2 molecular composition were also detected, but their precise bonding pattern has not been established.     

Characterization of subclass-related F(ab)2, Fab-c and Fch fragments obtainined by short papain digestion of human IgG myeloma proteins

When incubated with papain alone, all the IgGI proteins gave a good yield (6- 20%) of fragments (consisting of one Fc joined to one Fab through an unbroken heavy chain). Inclusion of cysteine during the digestion resulted in a mixture of F(ab)₂ and probably F(c)₂ fragments in (a dimer of Fc) in approx. weld. The IgG2 proteins gave mainly F(ab)₂ fragments in up to 12% yield during a short papain digestion in the presence of cysteine. The IgG3 proteins tested gave nearly pure Fch (Fc fragment plus the particular expanded hinge region) when digested without cysteine (yield of 4–25%) . If the papain proteolysis was performed together with cysteine, there was about 5% yield of a mixture of Mw 100,000 fragments The IgG₄ protein used in this study gave approximately 30%. yield of almost pure F(ab)₂ fragments when digested without teine F(ab)₂ fragments were also formed when the IgG4 protein was digested in the presence of cysteine (10% yield).     

Mouse IgG2b monoclonal antibody fragmentation. Preparation and purification of Fab, Fc and Fab/c fragments

Mouse IgG2b fragmentation has been poorly described in the literature because of the sensitivity of this subclass to proteases and the inability to produce F(ab')2 fragments. The fragments obtained include both Fc and Fab fragments and an intermediate of degradation, the Fab/c fragment, consisting of the Fc region and one Fab arm, which was first described by Parham (1983). Optimised pepsin digestion led to the formation of Fab/c in yields of up to 30% depending on the IgG2b antibodies susceptibility. DEAE-cellulose chromatography of the digested antibodies allowed, in all cases, separation of Fab fragments from Fc bearing fragments. Depending on the differences in pI between the fragments, Fab/c fragment purification was achieved either by CM-cellulose chromatography or by recycling HPLC gel filtration chromatography. Both procedures gave 97.5% purity Fab/c fragments. Fc fragments were purified by HPLC gel filtration chromatography. In cancer therapy the monovalent Fab/c fragments could be useful for drug targeting or for immunotherapy providing it retains a good affinity.     

The binding of rabbit IgG and its enzymatically derived fragments to homologous peritoneal macrophages.

Rabbit IgG and its Fab, Fc and pFc' fragments, prepared by papain or peptic digestion, were assayed for binding to homologous peritoneal macrophages. The binding affinity of IgG for the peritoneal macrophages (Ka = 5.9 +/- 1.6 x 10(5) L/M) was comparable to that recorded with alveolar macrophages (7.6 +/- 1.8 x 10(5) L/M, Arend & Mannik, 1973) but the number of receptor sites per peritoneal cell (4.6 +/- 2.1 x10(6)) was about four-fold greater than on the latter. Of the fragments, only Fc bound to macrophages with an affinity comparable to intact IgG; pFc' bound weakly and Fab was totally inactive. These data, taken with a recent study involving rabbit IgG and guinea-pig macrophages (Ovary, Saluk, Quijada & Lamm, 1976), indicate that the primary IgG binding site for macrophages is located in the C gamma 2 domain.     

A small domain (6.5 kDa) of bacterial protein G inhibits C3 covalent binding to the Fc region of IgG immune complexes

Attachment of the complement component C3 to antigen-antibody (Ag-Ab) complexes (immune complexes, IC) is the key molecular event responsible for the elimination of many Ag in the form of Ag-Ab-C3b. The CH1 domain and the Fc region of the Ab, which have previously been involved in the binding of C3b, are also the targets of several bacterial IgG-binding proteins, particularly proteins G and A. Here we describe the ability of a small recombinant protein G domain (B2; 6.5 kDa) to inhibit the covalent binding of C3b to the Fc portion of IgG without affecting the binding to the Fab part. Protein G (B2 domain) produced a remarkable inhibition of covalent binding of C3b to IC formed with rabbit IgG, but none with the F(ab ′ )₂ fragment, indicating that B2 interferes with the C3b binding to the Fc region. A weak inhibition was observed with IC formed with mouse IgG2b which preferentially binds B2 domain on the CH1 domain of the Fab. To confirm these data, recombinant single-chain Ab devoid of CH1 domains (scAb), and including the rabbit or human Fc portion (hinge-CH2-CH3), were produced and used to form IC. Protein G-B2 domain inhibited C3b binding to IC formed with scAb of either human or rabbit constant regions, supporting the view of a specific blockade of C3b binding to the Fc region. A similar inhibition of C3b binding was observed using protein A instead of protein G B2 domain and the same set of IC. On the CH1 domain, C3b and B2 bind on opposite faces, and therefore do not interfere with each other in their binding. However, B2 domain bound to the inter-CH2-CH3 region impedes the C3b binding to the Fc. This inhibition clarifies the specificity of C3b for the different regions of IgG and explains how bacterial IgG-binding proteins provide the bacteria with a mechanism of evasion from the opsonizing action of complement and contribute to the virulence. This could be a general mechanism of escape because protein G binds the majority of mammalian Ig.     

Affinity of immunoglobulin for heterologous tissue mast cells. A study with the fluorescent antibody method

A double layer immunofluorescence method was used to explore the affinity of immunoglobulins and immunoglobulin fragments for the mast cells of the mouse tongue. Human IgG but not IgA or IgM showed such an affinity as revealed by fluorescence of globulin attached to the mast cell surface and to the mast cell granules. This affinity was found also in isolated H(γ) chains but not in the light chains of IgG. After papain digestion, the Fab and Fc fragments obtained showed no affinity for mouse tongue mast cells though the 5S fragment obtained after pepsin digestion retained activity. The human immunoglobulin sub-class IgG₂ lacks the ability to bind to mouse tongue mast cells. In guinea-pig serum, γ₁- but not γ₂-globulin showed an affinity for mouse tongue mast cells. It was suggested that a specific attachment site for mouse tongue mast cell surface receptors was present on the γ chain of human IgG and that this site was in a position susceptible to attck by papain hydrolysis.     

The Fab/c fragment of IgG produced by cleavage at cyanocysteine residues

The intra- and inter-heavy chain disulfides of rabbit IgG were cleaved by mild reduction with either dithiothreitol or sulfite and cyanocysteines generated by treatment with either 2-nitro-5-thiocyanobenzoic acid or KCN, respectively. When cleavage occurs at a cyanocysteine residue in the hinge region of one heavy chain alone the Fab/c fragment is produced. Fab/c was also produced by papain digestion of IgG. Fab/c made by papain digestion was able to active complement in haemolytic assays; this activity was lost after cleavage of its accessible disulfide bonds. Fab/c made by cyanylysis of sulfite-reduced IgG was also active in these assays, but Fab/c made by cyanylysis of dithiothreitol-reduced IgG was not. Treatment of the latter fragment with cysteine and cystine resulted in partial reformation of cleaved disulfide bonds. Fab/c was also made from human IgG and from murine IgG2a and IgG2b.