Proteolysis of purified IgGs by human and bacterial enzymes in vitro and the detection of specific proteolytic fragments of endogenous IgG in rheumatoid synovial fluid

A comparative in vitro survey of physiologically relevant human and microbial proteinases defined a number of enzymes that induced specific hinge domain cleavage in human IgG1. Several of these proteinases have been associated with tumor growth, inflammation, and infection. A majority of the identified proteinases converted IgG to F(ab')(2), and a consistent feature of their action was a transient accumulation of a single-cleaved intermediate (scIgG). The scIgG resulted from the relatively rapid cleavage of the first hinge domain heavy chain, followed by a slower cleavage of the second chain to separate the Fc domain from F(ab')(2). Major sites of enzymatic cleavage were identified or confirmed from the mass of the F(ab')(2) or Fab fragments and/or the amino-terminal amino acid sequence of the Fc for each enzyme including human matrix metalloproteinases (MMPs) 3 and 12, human cathepsin G, human neutrophil elastase (Fab), staphylococcal glutamyl endopeptidase I and streptococcal immunoglobulin-degrading enzyme (IdeS). The cleavage sites in IgG1 by MMP-3, cathepsin G and IdeS were used to guide the synthesis of peptide analogs containing the corresponding carboxy-termini to be used as immunogens in rabbits. Rabbit antibodies were successfully generated that showed selective binding to different human F(ab')(2)s and other hinge-cleavage fragments, but not to intact IgG. In Western blotting studies of synovial fluids from individuals with rheumatoid arthritis, the rabbit antibodies yielded patterns consistent with the presence of endogenous IgG fragments including F(ab')(2) and the single-cleaved IgG intermediate. The detection in synovial fluid of IgG fragments similar to those observed in the in vitro biochemical studies suggests that proteolysis of IgG may contribute to localized immune dysfunction in inflammatory environments.     

Characterization of neutralizing anti-pre-S1 and anti-pre-S2 (HBV) monoclonal antibodies and their fragments.

Single-chain Fv fragments (scFv) were generated from two murine monoclonal antibodies directed to the neutralizing epitopes of the pre-S1 and pre-S2 region of hepatitis B virus, respectively, using different assembly cloning strategies. The scFv fragments were solubly expressed in E. coli. Dissociation constants were in the nanomolar range for all forms (whole IgG antibodies, Fab fragment and scFv fragments). The epitopes of both antibodies were mapped using solid phase peptide synthesis on continuous cellulose membranes and turned out to be linear determinants. The minimal epitope for the anti-pre-S2 antibody 1F6 was identified to be DPRVRGLYF (amino acid 133-141 of the pre-S region). For the anti-pre-S1 antibody MA 18/7 the minimal epitope proved to be the hexamer LDPAFR (amino acid 30-35 of the pre-S region). Complete substitutional analyses as well as truncation experiments revealed key residues for these antibody-antigen interactions. On the basis of those results we used computer-assisted modeling techniques to suggest models for both antibody-peptide interactions providing insight into the structural basis of these molecular recognitions.     

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.     

Cleavage of the Four Human IgG Subclasses with Cathepsin G

Cathepsin G, the chymotrypsin-like serine proteinase from human polymorphonuclear leucocytes, cleaves human IgG. The relative susceptibilities of the four IgG subclasses to the action of this enzyme were studied kinetically and showed the following decreasing order of susceptibility: IgG3≫ IgG4>IgG1>IgG2. IgG1 and IgG2 produced primarily F(ab')s and traces of Fc-related fragments. IgG4 gave rise to both Fab and F(ab')₂ as major products, and small amounts of an Fc-related fragment were detected. The cleavage of IgG3 produced various fragments, depending on the experimental conditions: The primary fragments were Fab and Fch (Fc covalently joined to the extended hinge-region polypeptide of IgG3) and an intermediate Fab-Fch species. Both Fab and Fch were further degraded by cathepsin G. Fch was gradually split, giving rise to three subfragments that were finally degraded to dialysable peptides. The enzyme further cleaved the Fab fragment in the heavy-chain portion and released a polypeptide probably representing the V_H domain.     

Unique features of monoclonal IgG2b in the cleavage reaction with pepsin

Preparations of IgG2b purified from several mouse hybridoma clones were highly susceptible, compared to other subclasses, to peptic digestion under conditions usually used to prepare F (ab')2 fragments. Analyses of the digestion products revealed that no F (ab')2 was produced and that the main product was a Fab-like fragment. Demonstration of the hinge disulfides in the Fc portion clearly indicated that in IgG2b the primary peptic cleavage occurs on the NH2-terminal side of the inter-heavy chain disulfide bridge. The resulting Fab failed to bind with antigen, suggesting the importance of the CH1-hinge region in maintaining the native conformation of the antigen-binding site.     

Interaction of the hinge region of human immunoglobulin G with a murine lymphocyte membrane receptor. Relevance to the problem of antiglobulin induction in rheumatoid arthritis.

Evidence is presented which indicates the presence on murine lymphocytes of a membrane receptor for determinants on the hinge region of human IgG. These determinants are exposed following pepsin scission of IgG molecule, i.e. on the F(ab')2 fragment. The evidence for a hinge receptor derives, in vivo, from splenic localization of F(ab')2 in germinal centres and, in vitro, from immunofluorescent binding studies. The sequential immunofluorescent pattern for the uptake of human F(ab)2 fragments into murine spleen germinal centres was identical with that previously observed for heat-aggregated human IgG, but F(ab')2 fragments appeared to be retained in the germinal centres for a shorter time than aggregated IgG. Experiments with nude mice and T cell-deprived mice showed that the localization of F(ab')2 fragments does not require T cells. Competition experiments suggest that the receptor for F(ab')2 may bear little relation to the receptor for aggregated IgG. The relevance of such a lymphocyte membrane receptor to the immunopathology of rheumatoid arthritis is discussed in the light of previous findings that a proportion of the serum IgG of patients with rheumatoid arthritis has a structural anomaly compared with control IgG, characterized exposure of new determinants at the hinge region.     

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     

Specific cleavage sites on human IgG subclasses by cruzipain, the major cysteine proteinase from Trypanosoma cruzi

Cruzipain, the major cysteine proteinase of Trypanosoma cruzi, might have other biological roles than its metabolic functions. In this report, we have explored the interaction of cruzipain with molecules of the immune system. The enzyme was used to digest all human IgG subclasses at different pH values and lengths of time. At pH 7.3, all subclasses were readily split at the hinge region. Immunoblot and amino acid sequence analysis showed fragments of IgG1 and IgG3 to be compatible with Fab and Fc, whereas IgG2 and IgG4 rendered Fab2 and Fc. In all cases the fragments produced might impair the binding capacities and the effector functions of specific IgG. At these cleavage sites cruzipain displays cathepsin L and/or cathepsin B activities and shows a clear preference for Pro at the P'2 position and polar residues at P1. Despite the activity of cruzipain within the hinge, the enzyme also cleaved all heavy chains between the CH2 and CH3 domains; producing Fc'-like-fragments of 14 kDa. These fragments are potential candidates to block or saturate Fc receptors on immunocompetent cells. At mild acidic pH cruzipain produced further degradation of the Fc of all subclasses, the Fd of IgG4 and partially the Fd of IgG1, with the consistent loss of any antibody activity. The L chains apparently were not affected. Thus, cruzipain should be able to modulate, depending on the subclass selected and the pH of the environment, the production and the length of different biologically active/inactive IgG fragments.     

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.     

Transformation of Trypomastigote Forms of Trypanosoma cruzi into Activators of Alternative Complement Pathway by Immune IgG Fragments

In this report we examined the capacity of immune IgG fragments to prepare trypomastigote bloodstream forms (TBF) of Trypanosoma cruzi for lysis. F(ab')₂, fragments were capable of presensitizingTBF For complement (C) lysis, thus excluding the participation of Fc domains in the C activation process. An intact hinge region of the IgG molecule was not involved either, since the corresponding Fab' were almost as active as the original molecules in preparing TBF for lysis. Fab also retained such activity even after further reduction and alkylation. These findings indicate that neither the portions of heavy chains that make up the hinge region nor the intrachain disulphide bonds are involved in the process. The IgG fragments promoted lysis through the activation of the alternative C pathway (ACP). These results suggest that the immune IgG transforms TBF into ACP activators by blocking the capacity of some parasite cell surface components that are known inhibitors of C activation.     

Binding of human IgA1 and IgA1 fragments to jacalin

Interaction of jacalin, an N-terminal galactose specific lectin, with human IgA1 and IgA1 fragments was investigated. IgA1 and all galactose containing fragments bound to jacalin-Sepharose, including Fab fragments containing only the galNac linked to serine-224 and Fc fragments containing four gal-galNac sequences. These data indicate that both the galNac and gal-galNac sequences can interact with jacalin. Jacalin precipitated IgA1 and the fragments F(abc)2, F(ab')2 and Fc in agar gel and from solutions. It also precipitated Fab' fragments in agar gel. Jacalin did not precipitate Fab fragments significantly. This suggests that, except for the single binding site on the Fab fragments containing the galNac linked to serine-224, jacalin itself also has a limited number of sites to interact with N-terminal galactose residues. ELISA studies revealed that intact IgA1 had a lower jacalin binding capacity than F(abc)2 fragments which lack CH3 domains, than F(ab')2 which lack the CH2 and CH3 domains, and than Fc fragments containing four gal-galNac sequences. This led to the conclusion that part of the galNac or gal-galNac sequences in intact IgA1 molecules are inaccessible to interaction with jacalin. Cleaving the C-terminal domains off may have induced a reorientation of the hinge region structure, including the orientation of the carbohydrate units.     

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.     

Influences of amino acid sequences in FR1 region on binding activity of the scFv and Fab of an antibody to human gastric cancer cells

Murine anti-gastric cancer mAb 3H11 has promising clinical applications. In this work, engineering of 3H11 scFv and Fab was conducted to increase its usefulness. 3H11 scFv and Fab were constructed by PCR amplification of the V-domains with degenerate primers for FR1. The bacterially expressed 3H11 Ab fragments showed no antigen binding activity. Then the N-terminal sequences of V regions were mutated to the 3H11 original sequence. The expressed scFv and Fab in bacterial culture supernatant showed binding activity to gastric cancer cells. Comparing the expression of unmutated and mutated 3H11 Fab, we found that the sequence changes of the V region N terminus introduced by PCR may seriously affect antigen binding but not the expression of antibody. Correction of either VL or VH N-terminal sequences can partially restore the antigen binding activity (61% for VL and 73% for VH).     

Activation of complement by human serum IgA, secretory IgA and IgA1 fragments

Activation of the complement (C) system by human IgA was studied. Both subclasses of IgA, IgA1 and IgA2, and secretory IgA were shown to activate C, as determined by deposition of C3 on glutaraldehyde-activated microwells coated with IgA. The activation of the C system occurred in the presence of MgEGTA and not in D-deficient serum. In addition to C3, deposition of properdin (P) but not of C4 was detected. These results indicate that C activation, as determined by measuring deposition of C3 and P, occurred by the alternative pathway (AP). The data further show that the major part of the hinge region, which is deleted in IgA2 as compared with IgA1 and which forms the major structural difference between the two subclasses, is not involved in C activation. Reduction and alkylation destroyed the ability of IgA to activate C, as has also been demonstrated for IgG. In order to define the C activating region of the IgA molecule, several fragments of IgA1 were tested. The four-chain molecules F(ab')2 and F(abc)2 were shown to activate the AP. No activation was observed with the two-chain fragments Fab and Fc. The Fc fragment of IgA also did not activate the CP, as does the Fc fragment of IgG. This indicates that activation of the AP of C by IgA is dependent on the presence of the F(ab')2 fragment. In conclusion: human IgA does activate C by the AP. This activation requires an intact F(ab')2 fragment.     

Autoantibodies to calcium channels in type 1 diabetes mediate autonomic dysfunction by different mechanisms in colon and bladder and are neutralized by antiidiotypic antibodies

Autoantibodies (Abs) directed against L-type voltage-gated calcium channels (VGCCs) have been shown to contribute to autonomic dysfunction of the gastrointestinal tract and bladder in patients with Type 1 diabetes mellitus (T1D). We used a passive transfer model to determine whether the functional activity of the Ab requires crosslinking of channels in colon and bladder and can be neutralized by intravenous immunoglobulin (IVIg). Mice were injected with mono- and divalent F(ab) fragments of patient IgG with anti-VGCC activity and tested for gut and bladder function using a colonic migrating motor complex (MMC) assay and bladder-filling cystometry. The ability of IVIg to neutralize anti-VGCC IgG-mediated autonomic dysfunction was investigated by injection of mice with an equimolar concentration of IVIg prior to T1D IgG injection, or by injection with T1D IgG passed over a sepharose 4B column coupled with F(ab')(2) from IVIg. Passive transfer of T1D IgG and its F(ab')(2) or F(ab) fragments reduced the amplitude of spontaneous colonic motility. In contrast, intact IgG and F(ab')(2,) but not F(ab), produced the urodynamics features of an overactive bladder. T1D IgG-mediated colonic and bladder dysfunction was neutralized in vivo by prior injection of animals with equimolar IVIg. Moreover, anti-VGCC activity was depleted by preabsorption of patient IgG on a IVIg F(ab')(2) column. The activity of anti-VGCC IgG is mediated by the antigen-binding site consistent with a true functional Ab. The pathogenic effect on the bladder requires crosslinking of the channel, whereas monovalent binding of Ab is sufficient for disruption of colon motility. The anti-VGCC Abs are neutralized by antiidiotypic antibodies present in IVIg that may prevent the emergence of these Abs in healthy individuals.     

Streptococcal protein G has affinity for both Fab- and Fc-fragments of human IgG

We have analyzed the binding of IgG and fragments of IgG [Fc, F(ab')2, and Fab] to group C and G streptococci and to protein G, the IgG binding cell wall protein of these bacteria. A direct correlation (r = 0.87, P less than 0.0001) was observed when the binding of radiolabelled, polyclonal IgG F(ab')2- and Fc-fragments to 23 group C and G streptococcal strains was compared. One strain (G-148) was treated with increasing amounts of pepsin, trypsin or papain and the Fab-binding structure was found to be much more sensitive to the enzymes as compared to the Fc-binding. A 35 K fragment of protein G was coupled to Sepharose, and both radiolabelled IgG F(ab')2- and Fc-fragments bound to the Sepharose beads. Binding of IgG fragments was inhibited by intact IgG or by the homologous IgG fragment, whereas Fc-fragments did not inhibit Fab binding or vice versa. Two radiolabelled protein G-fragments (28 and 35 K) showed different binding to polyclonal IgG, IgG F(ab')2-, IgG Fab- and IgG Fc-fragments. Thus, in a dot binding assay the 35 K fragment bound all IgG fragments tested, whereas the 28 K protein G fragment bound only intact IgG and IgG Fc-fragments. These results indicate two independent and separate binding sites for Fab- and Fc-fragments on protein G. Different binding sites on protein G were also indicated by Western blot analysis of four different protein G-fragments (28, 35, 42 and 65 K). In these experiments the 28 K fragment showed affinity only for Fc-fragments, while the higher mol. wt protein G preparations bound both IgG Fab- and Fc-fragments.     

Binding of Human IgA Myeloma Proteins to Protein a. Evidence for Different Binding Mechanisms

The binding of fifteen IgA myeloma proteins to protein A was studied using affinity chromatography on protein A-Sepharose CL-4B. The percentage to which the proteins bound was variable from 1% to 11% with the exception of IgA(GED) with a binding capacity of 22%, and IgA(KLO) with a binding capacity of 84%. The binding of the proteins IgA(GED) and IgA(KLO) was studied further. IgA(GED) was a monomer, IgA(KLO) a polymer. The characteristics of the binding of these proteins were different. The protein A-reactive fraction of IgA(KLO), but not of IgA(GED) remained fully reactive on repeated protein A chromatography. Furthermore, the binding of IgA(GED) could be reduced to about 3% by either a decrease in pH to 4.5 or an increase in NaCl concentration to 2.OM, whereas the binding of IgA(KLO) was similarly reduced by a decrease in pH but its binding only reduced to half of the original value on a similar increase of NaCl concentration. In addition, F(ab')2 fragments of IgA(KLO), but not of IgA(GED), bind to protein A-Sepharose CL-4B, whereas IgA1 protease-produced Fab fragments of neither of the proteins did so, nor did pepsin-produced Fab' fragments. This suggests that the binding of F(ab')2 fragments of IgA(KLO) needs an intact hinge region.     

Conformational changes in the antibody constant domains upon hapten-binding

Bacterial proteins A and G (SpA and SpG) are immunoglobulin receptors that can be used as probes for monitoring change in the conformation of heavy chain constant (C(H)) domains. Interaction of anti-(4-hydroxy-3-nitrophenyl)acetyl (NP) antibody (Ab) with SpA and SpG were measured by isothermal titration calorimetry and surface plasmon resonance in order to address the question of whether hapten-binding induces a conformational change in the C(H) domain. The interactions of IgG2a or its enzymatic fragments with SpA were measured in the presence or absence of the hapten. Although binding of Fab and F(ab')2 fragments were not observed to free SpA, they did bind to immobilized SpA. In addition, the association constant (K(a)) for interaction of IgG2a with immobilized SpA was approximately 20-fold higher than that with free SpA. This was explained in terms of high avidity resulting from multivalent interaction between IgG2a and immobilized SpA on the chip. Interestingly, the hapten-binding weakened the interaction between the F(ab')2 fragment and SpA. Furthermore, approximately half of the IgG2a was incapable of binding to immobilized SpA in the presence of hapten. These results were explained using a model which assumed the formation of two kinds of SpA/IgG complexes; one through sites on F(ab')2 arms and the other through sites on the Fc region. The former type dissociated as a result of hapten-binding, as did the F(ab')2 fragment and suggested that a conformational change had occurred around the Fab arms, while the latter type did not dissociate because of the higher avidity of the Fc region. However, using a mutant SpA with a lower K(a) value for the interaction with IgG2a, it was shown that hapten-binding induced long range conformational changes in the Fc region of IgG2a. Similar evidence of conformational change upon hapten-binding was also obtained using SpG as a probe.     

Mitogenic Properties of Fab and F(ab'')2 Fragments of Rabbit Anti-Human β2-Microglobulin for Human Lymphocytes

Bivalent F(ab')2 fragments and monovalent Fab fragments of rabbit anti-human beta2-microglobulin (anti-beta2m) stimulated DNA synthesis in human lymphocytes. Mitogenicity of anti-beta2m antibodies can therefore be ascribed to the antigen-binding site and not to the Fc portion of the molecule. The mitogenic response to F(ab')2, and sometimes Fab, fragments of anti-beta2m IgG was comparable to that obtained with original IgG antibodies when tested at the same protein concentration. Since Fab monomers of anti-beta2m can cause lymphocyte activation, 'cross-linking' of hypothetical beta2-microblobulin-containing lymphocyte receptors does not seem necessary for activation. F(ab')2, as well as Fab, fragments of anti-beta2m blocked the cytotoxic effect of anti-beta2m IgG, showing that the fragments did indeed react with beta2-microblobulin on the cell surface. F(ab')2 dimers, but not Fab monomers, of anti-beta2m were capable of inhibiting the cytotoxic effect of an anti-HLA-A2 antiserum. The mitogenic activity of both anti-beta2m IgG and Fab monomers of such antibodies disappeared after absorption with highly purified beta2-microblobulin. The mitogenic effect of anti-beta2m IgG was inhibited to a minor extent by exposure of cells to high concentrations of pooled multispecific anti-HLA antibodies. This effect was probably nonspecific.     

Binding of normal human IgG to myelin sheaths, glia and neurons.

The binding of normal human serum, purified IgG and IgG fragments to central nervous tissue was studied by the anti-globulin consumption (AGCT) and immunofluorescence (IF) techniques. In the AGCT, F(ab')2 fragments failed to react, whereas IgG and Fc fragments did so. In IF experiments, the binding was localized to myelin sheaths, glia and neurons; Fab monomers at a protein concentration of 1-3 mg/ml dod not react with the tissue, but purified Fc fragments at 0-0625 mg/ml did. The binding is neither tissue- nor species-specific. Lipid and protein extraction procedures indicated that the factor responsible for binding to myelin was basic protein. It was concluded that the binding of normal IgG to central nervous tissue is medicated by the Fc part of the molecule.