The role of the C9b domain in the binding of C9 molecules to EAC1-8 defined by monoclonal antibodies to C9

Three mAb to human C9, X195, X197, and P40 were used to analyze the roles of the C9a and C9b domains in the reaction of the C9 molecule with sensitized sheep E bearing C1 to C8 (EAC1-8). X195 bound to NH2-terminal (C9a) fragments, and X197 bound to COOH-terminal (C9b) fragments obtained by cleavage of C9 with alpha-thrombin or trypsin. P40 recognized the epitope on the C9b fragment obtained by alpha-thrombin cleavage but did not react with the NH2-terminal or COOH-terminal fragment obtained by trypsin cleavage. In this respect, P40 differed from mAb to C9 reported previously. P40 almost completely inhibited the hemolytic activity of C9. X195 and X197 also inhibited C9 activity, but less effectively than P40. C9 molecules bound to P40 could not bind to EAC1-8 cells. C9 bound to X197 could not bind rapidly to EAC1-8, but prolonged incubation of the C9-X197 complex with EAC1-8 caused considerable lysis of the cells. C9 molecules bound to X195 could bind rapidly to EAC1-8, but their lytic activity was partially inhibited by the bound antibody. From these results, it is concluded that the C9b but not C9a domain contributes to the binding of C9 to EAC1-8 and that the epitope recognized by P40 or a closely adjacent site may be the binding site of C9 molecule to EAC1-8.     

Functional evidence for three distinct and independently inhibitable adhesion activities mediated by the human integrin VLA-4. Correlation with distinct alpha 4 epitopes.

The human integrin VLA (very late activation antigens)-4 (CD49d/CD29), the leukocyte receptor for both the CS-1 region of plasma fibronectin (Fn) and the vascular cell surface adhesion molecule-1 (VCAM-1), also mediates homotypic aggregation upon triggering with specific anti-VLA-4 monoclonal antibody (mAb). Epitope mapping of this integrin on the human B-cell line Ramos, performed with a wide panel of anti-VLA-4 mAb by both cross-competitive cell binding and protease sensitivity assays, revealed the existence of three topographically distinct epitopes on the alpha 4 chain, referred to as epitopes A-C. By testing this panel of anti-VLA-4 mAb for inhibition of cell binding to both a 38-kDa Fn fragment containing CS-1 and to VCAM-1, as well as for induction and inhibition of VLA-4 mediated homotypic cell adhesion, we have found overlapping but different functional properties associated with each epitope. Anti-alpha 4 mAb recognizing epitope B inhibited cell attachment to both Fn and VCAM-1, whereas mAb against epitope A did not block VCAM-1 binding and only partially inhibited binding to Fn. In contrast, mAb directed to epitope C did not affect cell adhesion to either of the two VLA-4 ligands. All mAb directed to site A, as well as a subgroup of mAb recognizing epitope B (called B2), were able to induce cell aggregation, but this effect was not exerted by mAb specific to site C and by a subgroup against epitope B (called B1). Moreover, although anti-epitope C and anti-epitope B1 mAb did not trigger aggregation, those mAb blocked aggregation induced by anti-epitope A or B2 mAb. In addition, anti-epitope A mAb blocked B2-induced aggregation, and conversely, anti-epitope B2 mAb blocked A-induced aggregation. Further evidence for multiple VLA-4 functions is that anti-Fn and anti-VCAM-1 antibodies inhibited binding to Fn or to VCAM-1, respectively, but did not affect VLA-4-mediated aggregation. In summary, we have demonstrated that there are at least three different VLA-4-mediated adhesion functions, we have defined three distinct VLA-4 epitopes, and we have correlated these epitopes with the different functions of VLA-4.     

The low C5 convertase activity of the C4A6 allotype of human complement component C4.

We have compared the C5-convertase-forming ability of different C4 allotypes, including the C4A6 allotype, which has low haemolytic activity and which has previously been shown to be defective in C5-convertase formation. Recent studies suggest that C4 plays two roles in the formation of the C5 convertase from the C3 convertase. Firstly, C4b acts as the binding site for C3 which, upon cleavage by C2, forms a covalent linkage with the C4b. Secondly, C4b with covalently attached C3b serves to form a high-affinity binding site for C5. Purified allotypes C4A3, C4B1 and C4A6 were used to compare these two activities of C4. Covalently linked C4b-C3b complexes were formed on sheep erythrocytes with similar efficiency by using C4A3 and C4B1, indicating that the two isotypes behave similarly as acceptors for covalent attachment of C3b. C4A6 showed normal efficiency in this function. However, cells bearing C4b-C3b complexes made from C4A6 contained only a small number of high-affinity binding sites for C5. Therefore a lack of binding of C5 to the C4b C3b complexes is the reason for the inefficient formation of C5 convertase by C4A6. The small number of high-affinity binding sites created, when C4A6 was used, were tested for inhibition by anti-C3 and anti-C4. Anti-C4 did not inhibit C5 binding, whereas anti-C3 did. This suggests that the sites created when C4A6 is used to make C3 convertase may be C3b-C3b dimers, and hence the low haemolytic activity of C4A6 results from the creation of low numbers of alternative-pathway C5-convertase sites.     

Inhibition of binding of activated compliment component C4b with its target]

The inhibition of covalent binding of the nascent C4b fragment of the human complement component to its natural target, immunoglobulin G, was studied. To this end, an immunoenzyme system was developed. In this ELISA method, the complement was activated on the sorbed IgG molecules and the resulting nascent C4b fragment acylated IgG or interacted with a competitive inhibitor added to the system. The inhibition constants for binding of the nascent C4b to its target were determined for immunoglobulins G1, G2, G3, G4, M, and A1, as well as for ferritin, yeast mannan, capsid polysaccharides of the Neisseria meningitidis A, B, and C serotypes, diphtheria anatoxin, epinephrine, and salicylic acid. On the basis of the experimental data, the immunoglobulin role at the activation stage of the complement regulation cascade, the relationship between the antigen immunogenicity and its ability to interact with C4b, and the direct effect of a number of therapeutic agents on the complement system were discussed. Lectins of various specificities were shown to inhibit the enzymic activation of C4 by the first complement component and the subsequent C4b sorption to its target, which allowed us to suggest that some oligosaccharide fragments of the C1s and C4 molecules are spatially close to the C1s active site and to the thioester bond of C4.     

Probing the C4-binding site on C1s with monoclonal antibodies. Evidence for a C4/C4b-binding site on the gamma-domain

The catalytic site for C4 of C1s has been presumed to consist of a C4-binding domain and a proteolytic domain. A mAb to C1s, M81, blocked C4 activation and C4 binding to C1s. M81 recognized the H chain of C1s. Using M81 as a probe, we tried to define C4-binding site on C1s. Plasmin digestion of C1s generated four products of Mr 58,000 (P1), 48,000 (P2), 37,000 (P3), and 27,000 (P4). These products, except for P2, all possessed a 26,000-Da H chain fragment (26k-HF) connected to variable-sized L chain pieces. 26k-HF alone had an ability to interact with M81. Amino-terminal amino acid analysis of 26k-HF mapped the epitope for M81 to domain IV and/or V of gamma-domain of C1s. The gamma-domain therefore contains the C4-binding site. The confirm and further elucidate the role of the C4-binding site for C4, we used a substrate-blotting technique in which labeled C4 was incubated with nitrocellulose membrane-fixed C1s and its fragments. C4 was successfully blotted onto C1s and P1, but not P2-P4; i.e., further degradation of the L chain led to the loss of C4-binding. During the incubation, most of the added C4 was converted to C4b. The binding was augmented, if the proteolytic activity of C1s and P1 was blocked, so that the added C4 remained intact. Although C4b also bound to C1s and P1, its binding was less effective and abolished by the addition of cold C4. Based on these results, the gamma-domain and the L chain constitute the catalytic site of C1s to activate C4 to C4b. Moreover, the generated C4b, although it still has weak affinity for C1s, can be replaced by newly coming C4.     

Characteristics of monoclonal antibody binding with the C domain of human angiotensin converting enzyme

Binding of a panel of eight monoclonal antibodies (mAbs) with the C domain of angiotensin converting enzyme (ACE) to human testicular ACE (tACE) (corresponding to the C domain of the somatic enzyme) was studied and the inhibition of the enzyme by the mAb 4E3 was found. The dissociation constants of complexes of two mAbs, IB8 and 2H9, with tACE were 2.3 +/- 0.4 and 2.5 +/- 0.4 nM, respectively, for recombinant tACE and 1.6 +/- 0.3 nM for spermatozoid tACE. Competition parameters of mAb binding with tACE were obtained and analyzed. As a result, the eight mAbs were divided into three groups, whose binding epitopes did not overlap: (1) 1E10, 2B11, 2H9, 3F11, and 4E3; (2) 1B8 and 3F10; and (3) IB3. A diagram demonstrating mAb competitive binding with tACE was proposed. Comparative analysis of mAb binding to human and chimpanzee ACE was carried out, which resulted in revealing of two amino acid residues, Lys677 and Pro730, responsible for binding of three antibodies, 1E10, 1B8, and 3F10. It was found by mutation of Asp616 located close to Lys677 that the mAb binding epitope 1E10 contains Asp616 and Lys677, whereas mAbs 1B8 and 3F10 contain Pro730.     

The inhibition of covalent binding of the nascent complement component C4b to its target

The inhibition of covalent binding of the nascent C4b fragment of the human complement component to its natural target, immunoglobulin G, was studied. To this end, an immunoenzyme system was developed. In this ELISA method, the complement was activated on the sorbed IgG molecules and the resulting nascent C4b fragment acylated IgG or interacted with a competitive inhibitor added to the system. The inhibition constants for binding of the nascent C4b to its target were determined for immunoglobulins G1, G2, G3, G4, M, and A1, as well as for ferritin, yeast mannan, capsid polysaccharides of theNeisseria meningitidis A, B, and C serotypes, diphtheria anatoxin, epinephrine, and salicylic acid. On the basis of the experimental data, the immunoglobulin role at the activation stage of the complement regulation cascade, the relationship between the antigen immunogenicity and its ability to interact with C4b, and the direct effect of a number of therapeutic agents on the complement system were discussed. Lectins of various specificities were shown to inhibit the enzymic activation of C4 by the first complement component and the subsequent C4b sorption by its target, which allowed us to suggest that some oligosaccharide fragments of the C1s and C4 molecules are spatially close to the C1s active site and to the thioester bond of C4.     

Segment spanning residues 727-768 of the complement C3 sequence contains a neoantigenic site and accommodates the binding of CR1, factor H, and factor B.

CR1, CR2, DAF, MCP, factor H, C4bp, factor B, and C3 are members of a family of structurally related molecules, the majority of which belong to the complement system. Several of these molecules also share functional features such as cofactor and decay/dissociation activity and compete with one another in binding to C3b. Since factor H appears to bind to multiple sites in C3, we investigated the relationship between the factor H- and CR1-binding sites in C3b. Factor H binding to C3b is inhibited by either the C3c or C3d fragments, and addition of both fragments together augments this inhibition. One monoclonal anti-C3c antibody, anti-C3-9, which recognizes a neoantigenic epitope expressed upon cleavage to C3 to C3b, inhibited both factor H and CR1 binding to EC3b cells. This monoclonal antibody (MoAb) also inhibited factor B binding to EC3b. Two observations further supported our hypothesis that these molecules bind to proximal sites in C3b. First, a synthetic peptide spanning this region of C3b (C3(727-768)) inhibited factor H binding. Second, antibodies raised against this peptide inhibited binding to CR1, factor H, and factor B to C3b. These data show that H binds to at least two sites in C3b: the site in the C3c fragment is within the identified CR1-binding domain while the site in the C3d fragment surrounds the CR2-binding site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mapping of conformational mAb epitopes to the C domain of human angiotensin I-converting enzyme

Angiotensin I-converting enzyme (ACE, CD143) has two homologous domains, each having a functional active site. Fine epitope mapping of 8 mAbs to the C-terminal domain of human ACE was carried out using plate precipitation assays, mAbs' cross-reactivity with ACE from different species, site-directed mutagenesis, and antigen- and cell-based ELISAs. Almost all epitopes contained potential glycosylation sites. Therefore, these mAbs could be used to distinguish different glycoforms of ACE expressed in different tissues or cell lines. mAbs 1B8 and 3F10 were especially sensitive to the composition of the N-glycan attached to Asn 731; mAbs 2H9 and 3F11 detected the glycosylation status of the glycan attached to Asn 685 and perhaps Asn1162; and mAb 1E10 and 4E3 recognized the glycan on Asn 666. The epitope of mAb 1E10 is located at the N-terminal end of the C domain, close to the unique 36 amino acid residues of testicular ACE (tACE). Moreover, it binds preferentially to tACE on the surface of human spermatozoa and thus may find application as an immunocontraceptive drug. mAb 4E3 was the best mAb for quantification of ACE-expressing somatic cells by flow cytometry. In contrast to the other mAbs, binding of mAb 2B11 was not markedly influenced by ACE glycosylation or by the cell culture conditions or cell types, making this mAb a suitable reference antibody. Epitope mapping of these C-domain mAbs, particularly those that compete with N-domain mAbs, enabled us to propose a model of the two-domain somatic ACE that might explain the interdomain cooperativity. Our findings demonstrated that mAbs directed to conformational epitopes on the C-terminal domain of human ACE are very useful for the detection of testicular and somatic ACE, quantification using flow cytometry and ELISA assays, and for the study of different aspects of ACE biology.     

Antigenic specificities of human monoclonal and polyclonal IgM rheumatoid factors. The C gamma 2-C gamma 3 interface region contains the major determinants

The binding site specificity of 12 monoclonal and 11 polyclonal IgM rheumatoid factors (RF) isolated from human plasma or serum has been studied. All IgM RF bound best to sites on IgG and intact Fc. The monoclonal IgM RF did not bind at all to fragments lacking the C gamma 2 or C gamma 3 domains. In contrast, low level binding to the pFc' fragment, composed of the C gamma 3 domain, was seen with seven IgM RF, mainly from patients with rheumatoid arthritis (RA). IgG1 binding appeared to be a requisite specificity of all human IgM RF. IgM RF binding to IgG3 subclass was common among the monoclonal IgM RF. Most RA polyclonal IgM RF but only 2 of the monoclonal IgM RF possessed the IgG1, 2 and 4 binding pattern. Monoclonal IgM RF which bound best to histidine-modified IgG also bound well to IgG3. The 7-kDa fragment D of staphylococcal protein A inhibited the IgG binding of most monoclonal and to a lesser degree polyclonal IgM RF. Thus, the results indicate that the C gamma 2-C gamma 3 interface region of IgG contains the predominant determinants for monoclonal and polyclonal IgM RF. For some monoclonal IgM RF the binding site, even though at the interface of the C gamma 2 and C gamma 3 domains, is not the staphylococcal protein A site. Furthermore, polyclonal IgM RF possess specificities not encountered among the monoclonal IgM RF. These specificities may have special     

C1q and C4b bind simultaneously to CR1 and additively support erythrocyte adhesion.

Previously, we showed that soluble C1q bound specifically to CR1 on transfected cells. If the CR1-C1q interaction were to participate in immune complex clearance, then this interaction should support E adhesion. Using a tip plate adhesion assay, we found that immobilized C1q mediated adhesion of human E. E binding to C1q was specifically inhibited by polyclonal anti-CR1 Fab fragments. Intact C1 was not efficient as an adherence ligand until it was treated with EDTA or the C1 inhibitor to remove the C1r2C1s2 complex from C1, leaving C1q. Titration of C1q alone, C4b alone, and C1q + C4b indicated that the two complement ligands were additive in their ability to support CR1-mediated adhesion of E. Analysis of binding to immobilized CR1 using a BIAcore instrument documented that C1q, C4b, and C3b binding were independent events. Additionally, C1q-dependent binding of immune complexes and heat-aggregated IgG to E was documented. These experiments confirm that the immune adherence receptor in humans, CR1, is the single receptor for all of the opsonic ligands of complement, provide evidence for a single C1q binding site on LHR-D of CR1, and suggest that C1q may participate in immune clearance.     

Conformational and sequential epitopes on the human granulocyte-colony stimulating factor molecule (hG-CSF) and their role in binding to human placenta receptors.

Monoclonal antibodies (mAbs) named 8C2 and 6E3, directed against the recombinant human granulocyte colony-stimulating factor (hG-CSF), were used as probes to study the cytokine orientation on its binding to receptors from human placenta. Competition enzyme linked immunoabsorbent assays (ELISA) revealed that mAb 8C2 would be directed to a linear epitope, whereas mAb 6E3 would delimit a more assembled epitope. Gel-filtration high performance liquid chromatography (HPLC) of the immune complexes formed by incubating [(125)I]hG-CSF with each mAb showed that epitope 8C2, but not 6E3, was altered after cytokine iodination. In addition, mAb 6E3 completely inhibited [(125)I]hG-CSF binding to human placental microsomes. Although [(125)I]mAb 6E3 was unable to bind to preformed hG-CSF-receptor complexes, [(125)I]mAb 8C2 did recognize hG-CSF previously bound to receptors, suggesting that epitope 8C2 would remain accessible in the hG-CSF-receptor complex. To identify the cytokine region defined by mAbs, hG-CSF was digested with different proteolytic enzymes: Arg-C, Glu-C, trypsin and alpha chymotrypsin. Immunoreactivity of the resulting peptides was examined by Western blot and their sequences were established by Edman degradation. Results showed that mAb 6E3 would be directed to a conformation-dependent epitope located close to the hG-CSF binding domain and included into the sequence 1-122/123, whereas mAb 8C2 recognized the region 41-58, which represents a linear epitope left exposed after cytokine binding to receptors from human placenta.     

Immunogenic regions of the GA733-2 tumour-associated antigen recognised by autoantibodies of patients with colorectal carcinoma

The tumour-associated antigen (TAA) GA733-2 is overexpressed by >90% of human colorectal carcinomas (CRC). The antigen has previously been shown to be recognised by B and T cells. The aim of the present study was to define B cell epitopes of GA733-2. Fifteen percent of CRC patients with no previous immunotherapy have recently been shown to elicit an anti-GA733-2 IgG antibody response. Sera of these patients ( n=136) were analysed by enzyme-linked immunosorbent assay (ELISA) for immunoglobulin G (IgG) antibodies against 23 partly overlapping synthetic peptides (18 amino acids: aa) derived from the extracellular domain of GA733-2. An 18-aa long sequence at the N-terminal region of the antigen (peptide 2) was found to be an immunodominant B cell epitope. Fifty percent of the patients had antibodies against peptide 2, while 8% to 9% had antibodies against peptides 1, 4, 7, 8 or 20. In healthy donors ( n=30) antibodies against peptides 2 and 8 were also detected in 13% and 3% of cases respectively, while no antibodies were found against the other peptides and the complete protein. Thirteen percent of CRC patients ( n=30) with no IgG antibodies against the GA733-2 antigen elicited antibodies against peptide 2. The specificity of peptide-reactive sera was verified by inhibition ELISA. The binding of sera to GA733-2 was significantly inhibited by peptides to which CRC sera bound, but not by control peptides. Binding to peptide 2 of sera showing both peptide 2 and GA733-2 reactivity was specifically inhibited by the complete GA733-2 antigen, while binding of peptide 2-reactive sera showing no GA733-2 reactivity was not inhibited. CRC sera interfered with the binding of monoclonal antibody (mAb) 17-1A and mAb C215 that recognise distinct epitopes of GA733-2. No significant correlation was found between the presence of anti-peptide antibodies in CRC patients and clinical stage or overall survival. The results provide additional evidence for immune recognition of CRC by the host.     

Carbohydrates contribute to the interactions between cockroach allergen Bla g 2 and a monoclonal antibody

The crystal structure of a murine mAb, 4C3, that binds to the C-terminal lobe of the cockroach allergen Bla g 2 has been solved at 1.8 ? resolution. Binding of 4C3 involves different types of molecular interactions with its epitope compared with those with the mAb 7C11, which binds to the N-terminal lobe of Bla g 2. We found that the 4C3 surface epitope on Bla g 2 includes a carbohydrate moiety attached to Asn(268) and that a large number of Ag-Ab contacts are mediated by water molecules and ions, most likely zinc. Ab binding experiments conducted with an enzymatically deglycosylated Bla g 2 and a N268Q mutant showed that the carbohydrate contributes, without being essential, to the Bla g 2-4C3 mAb interaction. Inhibition of IgE Ab binding by the mAb 4C3 shows a correlation of the structurally defined epitope with reactivity with human IgE. Site-directed mutagenesis of the 4C3 mAb epitope confirmed that the amino acids Lys(251), Glu(233), and Ile(199) are important for the recognition of Bla g 2 by the 4C3 mAb. The results show the relevance of x-ray crystallographic studies of allergen-Ab complexes to identify conformational epitopes that define the antigenic surface of Bla g 2.     

Localization of the receptor binding site of IFN-alpha 2b

The receptor binding site of IFN-alpha is not precisely known. To further characterize this site, mAb against IFN-alpha 2b were selected that block the binding of radiolabeled IFN-alpha 2b to its cell surface receptor. These antibodies also neutralized the anti-viral and anti-proliferative properties of IFN-alpha 2b. A subset of these antibodies (group 1) do not recognize IFN-alpha 2a, either in solid-phase immunoassays or functional assays, whereas a second subset (group 2), with no cross-reactivity with group 1, recognizes both IFN-alpha subtypes. Because IFN-alpha 2b and IFN-alpha 2a differ by only alpha Arg23-Lys23 substitution, group 1 antibodies must recognize an epitope within the receptor binding region of IFN-alpha 2b that includes Arg23. Group 2 antibodies recognize a separate and distinct epitope within the binding site that does not include Arg23.     

Complement C2 receptor inhibitor trispanning and the beta-chain of C4 share a binding site for complement C2

Complement C2 receptor inhibitor trispanning (CRIT) of the Schistosoma parasite binds human C2 via the C2a segment. The receptor in vivo functions as C2 decoy receptor by directly competing with C4b for binding to C2. As a result, CRIT is able to limit the extent of classical pathway (CP) C3 convertase formation. We report that the CRIT-extracellular domain 1 (ed1) peptide inhibits CP-mediated complement activation with an ICH(50) of approximately 0.1 microM, the C-terminal 11 aa of CRIT-ed1, named H17, even more effectively. The beta-chain region F222-Y232 of C4 shares 55% identity and 73% similarity with H17. Peptides based on this region also inhibit CP in a dose-dependent manner. As further evidence of C2 binding we showed CRIT-ed1 peptides and homologous C4 beta-chain peptides to inhibit complement in C2 hemolytic assays. We have predicted C4 beta-c F222-Y232 as a C2 binding site which we have termed the CRIT-ed1 domain, and the sequence [F/H]EVKX(4/5)P as a consensus C2-binding sequence. Anti-CRIT-ed1 cross-reacts with the C4 beta-chain and F222EVKITPGKPY232 appears to be the key epitope recognized by this Ab. Furthermore, anti-CRIT-ed1 was found to inhibit CP activation in a total hemolytic assay. We believe that Schistosoma CRIT-ed1, as well as C4 beta-chain peptides based on the CRIT-ed1 domain, function as interface peptides. These peptides, based on C2-binding sequences in CRIT, or C4, competitively inhibit the binding of C2 to C4b and thus limit the activation of C. The C4 peptides, unlike CRIT-ed1, did not inhibit the cleavage of C2 by C1s.     

Rheumatoid factors may bear the internal image of the Fc gamma-binding protein of herpes simplex virus type 1

Affinity-purified rheumatoid factors (RF) from 20 patients with rheumatoid arthritis were tested for their reactivity with the mAb II-481 against glycoprotein E (gE), the Fc gamma-binding protein of HSV-1, as well as with a panel of mAb against human Fc gamma R. All RF bound to mAb II-481 in preference to mAb IV.3 (anti-human Fc gamma RII) or MOPC 141 (control mAb) which belong to the same IgG2b subclass. Five RF showed strong reactivity with II-481. No significant reactivity was observed between RF and mAb against human Fc gamma R. Non-RF human IgM did not react with any of the mAb. Clear-cut binding to II-481 was also seen with monoclonal IgM-RF derived from MRL/1 mice (mRF-2). The reaction between RF and II-481 was completely inhibited by human IgG. It was also inhibited by BHK cell extract infected with HSV-1, and with purified gE. II-481 inhibited the binding of human IgG Fc to the infected cell extract, confirming that II-481 recognizes the Fc-binding site on gE. II-481 did not react directly with human IgG or Fc of IgG. mAb to human IgG2 showed stronger binding to II-481 than to MOPC 141, suggesting II-481 has conformational similarity to human IgG H chain. These results suggest that at least some RF bear the "internal image" of HSV-1 Fc gamma-binding protein and support the hypothesis that some RF may be generated as anti-idiotype antibodies against antiviral antibodies.     

Control of C1 activation by nascent C3b and C4b: a mechanism of feedback inhibition

We have demonstrated that immune complexes turn over C1, i.e., limiting quantities of immune complexes activate an excess of C1. This was readily apparent in a system of purified C1 and C1-inhibitor (C1-In) but not in normal human serum (NHS). The following results indicate that C3 and C4 are the serum factors responsible for the inhibition of C1 turnover by immune complexes. 1) In a purified protein system composed of C1 and C1-In at pH 7.5, ionic strength 0.14 M, doses of immune complexes that activated all the C1 in 60 min at 37 degrees C yielded no detectable C1 activation when C2, C3, and C4 were also present. All proteins were at their physiologic concentrations. Activation was quantified by SDS-PAGE analysis and hemolytic titration 2) In order to inactivate C3 and C4, NHS was treated with 50 mM methylamine (MeAm) for 15 min at 37 degrees C, after which the MeAm was removed by dialysis. The activities of C1, C2, and C1-In were unaffected by this treatment. Doses of immune complexes that consumed no C1 in NHS, consumed all the C1 in MeAm-treated NHS (MeAm-NHS). 3) Reconstitution of MeAm-NHS with physiologic concentrations of C3 and C4 rendered the serum again resistant to excessive C1 consumption by immune complexes. Immune complexes used in these studies included EA-IgG, EA-IgM, tetanus-human anti-tetanus, and aggregated human IgG. There appeared to be specificity to the inhibition reaction since C4 by itself could inhibit C1 consumption by EA-IgM, whereas the presence of C3 was also required to control EA-IgG. Finally, N-acetyl-L-tyrosine was added to NHS at a final concentration of 30 mM. This nucleophile did not interact with native C3 or C4, nor did it directly activate C1. However, upon the addition of low doses of immune complexes, acetyl tyrosine did yield uncontrolled C1 activation, presumably by binding nascent C3b and C4b and thereby blocking their attachment to the immune complexes. We conclude that in NHS there is a mechanism of feedback inhibition by which nascent C3b and C4b inhibit C1 turnover by immune complexes. This mechanism of control might be physiologically important in that it prevents excessive complement activation by low concentrations of immune complexes.     

An immobile subset of plasma membrane CD11b/CD18 (Mac-1) is involved in phagocytosis of targets recognized by multiple receptors

CD11b/CD18 is a heterodimeric leukocyte surface receptor which functions in both C3bi-ligand binding and homotypic and heterotypic cell adherence. We have examined the effect of several anti-CD11b/18 mAb on phagocytosis of IgG (EIgG) or complement (EC4b) opsonized erythrocytes by polymorphonuclear leukocytes (PMN) and monocytes. F(ab')2 of two mAb (IB4, an anti-beta-chain mAb and Mo-1 an anti-alpha-chain mAb), inhibited both phagocytosis of EIgG and phorbol ester-stimulated phagocytosis of EC4b by PMN and monocytes. These F(ab')2 inhibited the binding of EIgG to monocytes, but they had no effect on binding of EIgG to PMN, or EC4b to either phagocyte. In addition, IB4 inhibited phorbol-ester stimulated phagocytosis of sheep E opsonized with C component 3bi (EC3bi) without inhibiting rosetting of these same targets. These data separate the anti-phagocytic effect of these mAb from effects on phagocyte-target adherence. When PMN were adherent to an anti-CD11b/CD18 F(ab')2-coated surface, EC3bi binding was abolished, but phagocytosis of EIgG or EC4b was unaffected. Subsequent addition of fluid- phase IB4 or Mo-1 F(ab')2 inhibited phagocytosis of EIgG or EC4b by the adherent cells. This suggested that the CD11b/CD18 involved in C3bi rosetting were mobile in the membrane, whereas those involved in phagocytosis of EIgG or EC4b were not. Cytochalasin treatment of PMN during adherence to F(ab')2-coated plates decreased both apical expression of CD11b/18 and subsequent ingestion of EIgG by 70%, suggesting that microfilaments are important in maintaining immobile CD11b/18 on the apical PMN surface. We conclude that there are functionally distinct populations of CD11b/CD18 on monocytes and PMN: one involved in C3bi rosetting and another involved in the process of phagocytosis mediated via several different receptors. CD11b/18 is not required for optimal target binding in all cases, but is always required for ingestion. As with several other integrins, the CD11b/18 molecules involved in phagocytosis have a functional association with the cell cytoskeleton.     

Synthesis and functional characterization of a recombinant monoclonal antibody directed against the alpha-chain of the human interleukin-2 receptor.

We have determined the sequence of the light and heavy chains of mAb 3G-10 (IgG1), a monoclonal antibody competing with interleukin 2 (IL2) for binding to the human IL2 receptor Tac protein. The antibody-encoding genes were chimerized by introducing splice donor and part of the intron sequences into the cDNA and subsequently linking it to the constant parts of the human IgG1 gene. The chimeric mAb was produced in mouse myeloma cells and purified. Murine and chimeric mAbs showed similar properties with respect to inhibition of T-cell proliferation. In contrast to its murine counterpart, the chimeric mAb exhibited Ab-dependent cellular cytotoxicity and, when combined with an Ab recognizing a different epitope on the IL2 receptor Tac protein, was able to activate human complement. The chimerized mAb might therefore have improved therapeutic efficacy.