Reaction mechanisms of beta1H globulin

Identification of intermolecular bonds between human factor B and Cobra Venom Factor important for C3 convertase stability

Cobra venom factor (CVF) is the complement-activating protein in cobra venom. CVF is a structural and functional analog of complement component C3. CVF, like C3b, forms a convertase with factor B. This bimolecular complex CVF, Bb is an enzyme that cleaves C3 and C5. However, CVF, Bb exhibits significantly different functional properties from C3b,Bb. Whereas both, CVF, Bb and C3b, Bb exhibit spontaneous decay-dissociation into the respective subunits, thereby eliminating the enzymatic activity, the CVF, Bb convertase is physico-chemically far more stable, decaying with a half-life that is more than two orders of magnitude slower than that of C3b,Bb. In addition, CVF, Bb is completely resistant to inactivation by Factors H and I. These two properties of CVF, Bb allow continuous activation of C3 and C5, and complement depletion in serum. In order to understand the structural basis for the physico-chemical stability of CVF,Bb, we have created recombinant hybrid proteins of CVF and human C3, based on structural differences between CVF and human C3b in the C-terminal C345C domain. Here we describe three human C3/CVF hybrid proteins which differ in only one, two, or five amino acid residues from earlier described hybrid proteins. In all three cases, the hybrid proteins containing CVF residues form more stable convertases, and exhibit stronger complement-depletion activity than hybrid proteins with human C3 residues. Three bonds between CVF residues and Factor Bb residues could be identified by crystallographic modeling that contribute to the greater stability of the convertases.

Complement depletion with humanised cobra venom factor: Efficacy in preclinical models of vascular diseases

The complement system is an intrinsic part of the immune system and has important functions in both innate and adaptive immunity. On the other hand, inadvertent or misdirected complement activation is also involved in the pathogenesis of many diseases, contributing solely or significantly to tissue injury and disease development. Multiple approaches to develop pharmacological agents to inhibit complement are currently being pursued. We have developed a conceptually different approach of not inhibiting but depleting complement, based on the complement-depleting activities of cobra venom factor (CVF), a non-toxic cobra venom component with structural and functional homology to complement component C3. We developed a humanised version of CVF by creating human complement component C3 derivatives with complement-depleting activities of CVF (humanised CVF) as a promising therapeutic agent for diseases with complement pathogenesis. Here we review the beneficial therapeutic effect of humanised CVF in several murine models of vascular diseases such as reperfusion injury.

Hybrid proteins of Cobra Venom Factor and cobra C3: tools to identify functionally important regions in Cobra Venom Factor

Cobra Venom Factor (CVF) is the complement-activating protein in cobra venom. CVF is structurally and functionally highly homologous to complement component C3. CVF, like C3b, the activated form of C3, forms a bimolecular complex with Factor B in serum, called C3/C5 convertase, an enzyme which activates complement components C3 and C5. Despite the high degree of homology, the two C3/C5 convertases exhibit significant functional differences. The most important difference is that the convertase formed with CVF (CVF,Bb) is physico-chemically far more stable than the convertase formed with C3b (C3b,Bb). In addition, the CVF,Bb convertase and CVF are completely resistant to inactivation by the complement regulatory proteins Factor H and Factor I. Furthermore, the CVF,Bb enzyme shows efficient C5-cleaving activity in fluid phase. In contrast, the C3b,Bb enzyme is essentially devoid of fluid-phase C5-cleaving activity. By taking advantage of the high degree of sequence identity at both the amino acid (85%) and DNA levels (93%) between CVF and cobra C3, we created hybrid proteins of CVF and cobra C3 where sections, or only a few amino acids, of the CVF sequence were replaced with the homologous amino acid sequence of cobra C3. In a first set of experiments, we created five hybrid proteins, termed H1 through H5, where the cobra C3 substitutions collectively spanned the entire length of the CVF protein. We also created three additional hybrid proteins where only four or five amino acid residues in CVF were exchanged with the corresponding amino acid residues from cobra C3. Collectively, these hybrid proteins, representing loss-of-function mutants of CVF, allowed the identification of regions and individual amino acid residues important for the CVF-specific functions. The results include the observation that the CVF β-chain is crucially important for forming a stable convertase, whereas the CVF α-chain appears to harbor no CVF-specific functions. Furthermore, the CVF γ-chain is additionally important for the fluid-phase C5-cleaving activity of CVF,Bb. Interestingly, the structural changes in the individual hybrid proteins differentially affected the molecular functions of the CVF,Bb enzyme such as convertase formation, C3 cleavage, and C5 cleavage.

Molecular cloning and characterization of a complement-depleting factor from king cobra, Ophiophagus hannah

Cobra venom factor (CVF) is an anti-complement factor existing in cobra venom. CVF proteins have been purified from the venoms of Naja haje, Naja siamensis, Naja atra, Naja kaouthia, Naja naja, Naja melanoleuca and Austrelaps superbus, but only three full-length cDNA sequences of CVF are available. In the present work, a cobra venom factor termed OVF was purified from the crude venom of Ophiophagus hannah by successive gel filtration, ion-exchange and heparin affinity chromatography steps. The purified OVF was homogenous on the SDS-PAGE gel with an apparent molecular weight of 140 kDa under non-reducing conditions. Under reducing conditions, OVF was divided into three bands with apparent molecular weight of 72 kDa (α chain), 45 kDa (β chain) and 32 kDa (γ chain), respectively. OVF consumed complement components with anti-complement activity of 154 units per mg. By using Reverse transcription-PCR and 5'-RACE assay, the open reading frame of OVF was obtained. MALDI-TOF and protein sequencing assays confirmed the cloned cDNA coding for OVF protein. The cDNA sequence of OVF is conservative when aligned with that of other CVFs. Phylogenetic analysis revealed OVF is closer to CVF from N. kaouthia than to AVF-1 and AVF-2 from A. superbus. Our results demonstrated that OVF has its unique features as following: 1) The N-terminal amino acid sequence of OVF γ chain is different from that of other known CVFs, suggesting that the OVF γ chain might be further processed; 2) Unlike N. kaouthia CVF and A. superbus AVF-1, which have potential N-linked glycosylation sites located in both α and β chain, OVF only has N-linked glycosylation site in its α chain as revealed by Schiff's reagent staining and protein sequence analysis; 3) In addition to the 27 well conserved cysteine residues in all known CVFs, OVF have an additional cysteine residue in its γ chain. Understanding the importance of above mentioned specific characteristics might provide useful information on structure-function relationship between CVF and complement system.

Cobra venom factor: Structure, function, and humanization for therapeutic complement depletion

Cobra venom factor (CVF) is the complement-activating protein in cobra venom. This manuscript reviews the structure and function of CVF, how it interacts with the complement system, the structural and functional homology to complement component C3, and the use of CVF as an experimental tool to decomplement laboratory animals to study the functions of complement in host defense and immune response as well as in the pathogenesis of diseases. This manuscript also reviews the recent progress in using the homology between CVF and C3 to study C3 structure and function, and to develop human C3 derivatives with the complement-depleting function of CVF. These human C3 derivatives represent humanized CVF, and are a conceptually different concept for pharmacological intervention of the complement system, therapeutic complement depletion. The use of humanized CVF for therapeutic complement depletion in several pre-clinical models of human diseases is also reviewed.

Polyanion-induced self-association of complement factor H

Factor H is the primary soluble regulator of activation of the alternative pathway of complement. It prevents activation of complement on host cells and tissues upon association with C3b and surface polyanions such as sialic acids, heparin, and other glycosaminoglycans. Here we show that interaction with polyanions causes self-association forming tetramers of the 155,000 Da glycosylated protein. Monomeric human factor H is an extended flexible protein that exhibits an apparent size of 330,000 Da, relative to globular standards, during gel filtration chromatography in the absence of polyanions. In the presence of dextran sulfate (5000 Da) or heparin an intermediate species of apparent m.w. 700,000 and a limit species of m.w. 1,400,000 were observed by gel filtration. Sedimentation equilibrium analysis by analytical ultracentrifugation indicated a monomer Mr of 163,000 in the absence of polyanions and a Mr of 607,000, corresponding to a tetramer, in the presence of less than a 2-fold molar excess of dextran sulfate. Increasing concentrations of dextran sulfate increased binding of factor H to zymosan-C3b 4.5-fold. This result was accompanied by an increase in both the decay accelerating and cofactor activity of factor H on these cells. An expressed fragment encompassing the C-terminal polyanion binding site (complement control protein domains 18-20) also exhibited polyanion-induced self-association, suggesting that the C-terminal ends of factor H mediate self-association. The results suggest that recognition of polyanionic markers on host cells and tissues by factor H, and the resulting regulation of complement activation, may involve formation of dimers and tetramers of factor H.

Functional characterization of human C3/cobra venom factor hybrid proteins for therapeutic complement depletion

Cobra venom factor (CVF) is a structural and functional analog of complement C3 isolated from cobra venom. Both CVF and C3b can bind factor B and subsequently form the bimolecular C3/C5 convertases CVF,Bb or C3b,Bb, respectively. The two homologous enzymes exhibit several differences of which the difference in physico-chemical stability is most important, allowing continuous activation of C3 and C5 by CVF,Bb, leading to serum complement depletion. Here we describe the detailed functional properties of two hybrid proteins in which the 113 or 315 C-terminal residues of C3 were replaced with corresponding CVF sequences. Both hybrid proteins formed stable convertases that exhibited C3-cleaving activity, although at different rates. Neither convertase cleaved C5. Both convertases showed partial resistance to inactivation by factors H and I, allowing them to deplete complement in human serum. These data demonstrate that functionally important structural differences between CVF and C3 are located in the very C-terminal region of both homologous proteins, and that small substitutions in human C3 with homologous CVF sequence result in C3 derivatives with CVF-like functions. Such hybrid proteins are important tools to study the structure/function relationships in both C3 and CVF, and these "humanized CVF" proteins may become reagents for therapeutic complement depletion.

Levels of urinary complement factor H in patients with IgA nephropathy are closely associated with disease activity

Factor H plays a key inhibitory role in control of the activation of alternative pathway of complement system. The aim of the study was to investigate the predictive value of factor H as a biomarker of renal injury in IgA nephropathy (IgAN). Urine factor H concentration from 202 patients was measured and compared with that of 60 healthy volunteers. Forty-eight patients fulfilled Haas-I or II (group 1), 60 fulfilled Haas-III (group 2) and 94 fulfilled Haas-IV or V (group 3). Co-deposition of factor H and C3b in kidneys were investigated using confocal microscope. The levels of urinary factor H, when expressed as a ratio of urinary creatinine, were significantly higher in groups 3 than group 1 and 2, also significantly higher in group 2 than group 1. In addition, the levels of urinary factor H were significantly higher in those with factor H deposition in the kidney than those without deposition. The levels of urinary factor H may be a useful biomarker to evaluate kidney injury in IgAN.

Translational mini-review series on complement factor H: renal diseases associated with complement factor H: novel insights from humans and animals

Factor H is the major regulatory protein of the alternative pathway of complement activation. Abnormalities in factor H have been associated with renal disease, namely glomerulonephritis with C3 deposition including membranoproliferative glomerulonephritis (MPGN) and the atypical haemolytic uraemic syndrome (aHUS). Furthermore, a common factor H polymorphism has been identified as a risk factor for the development of age-related macular degeneration. These associations suggest that alternative pathway dysregulation is a common feature in the pathogenesis of these conditions. However, with respect to factor H-associated renal disease, it is now clear that distinct molecular defects in the protein underlie the pathogenesis of glomerulonephritis and HUS. In this paper we review the associations between human factor H dysfunction and renal disease and explore how observations in both spontaneous and engineered animal models of factor H dysfunction have contributed to our understanding of the pathogenesis of factor H-related renal disease.

Role of complement in defense of the middle ear revealed by restoring the virulence of nontypeable Haemophilus influenzae siaB mutants

Nontypeable (NT) Haemophilus influenzae is an important cause of otitis media in children. We have shown previously that NT H. influenzae mutants defective in their ability to sialylate lipopolysaccharide (LPS), called siaB mutants, show attenuated virulence in a chinchilla model of experimental otitis media (EOM). We show that complement is a key arm of host innate immunity against NT H. influenzae-induced EOM. Depleting complement in chinchillas by use of cobra venom factor (CoVF) rendered two otherwise avirulent siaB mutants fully virulent and able to cause EOM with severity similar to that of wild-type strains. Clearance of infection caused by siaB mutants in CoVF-treated animals coincided with reappearance of C3. Wild-type strains were more resistant to direct complement-mediated killing than their siaB mutants. The serum-resistant strain bound less C3 and C4 than the serum-sensitive strain. Neither NT H. influenzae strain tested bound factor H (alternative complement pathway regulator). Selective activation of the alternative pathway resulted in more C3 binding to siaB mutants. LPS sialylation had a more profound impact on the amount of alternative-pathway-mediated C3 binding ( approximately 5-fold decrease in fluorescence) when LPS was the main C3 target, as occurred on the more serum-resistant strain. In contrast, only an approximately 1.5-fold decrease in fluorescence intensity of C3 binding was seen with the serum-sensitive strain, where surface proteins predominantly bound C3. Differences in binding sites for C3 and C4 may account for variations in serum resistance between NT H. influenzae strains, which in turn may impact their virulence. These data demonstrate a central role for complement in innate immune defenses against NT H. influenzae infections and specifically EOM.

Structure and function of recombinant cobra venom factor

Cobra venom factor (CVF) is the complement-activating protein from cobra venom. It is a structural and functional analog of complement component C3. CVF functionally resembles C3b, the activated form of C3. Like C3b, CVF binds factor B, which is subsequently cleaved by factor D to form the bimolecular complex CVF,Bb. CVF,Bb is a C3/C5 convertase that cleaves both complement components C3 and C5. CVF is a three-chain protein that structurally resembles the C3b degradation product C3c, which is unable to form a C3/C5 convertase. Both C3 and CVF are synthesized as single-chain prepro-proteins. This study reports the recombinant expression of pro-CVF in two insect cell expression systems (baculovirus-infected Sf9 Spodoptera frugiperda cells and stably transfected S2 Drosophila melanogaster cells). In both expression systems pro-CVF is synthesized initially as a single-chain pro-CVF molecule that is subsequently proteolytically processed into a two-chain form of pro-CVF that structurally resembles C3. The C3-like form of pro-CVF can be further proteolytically processed into another two-chain form of pro-CVF that structurally resembles C3b. Unexpectedly, all three forms of pro-CVF exhibit functional activity of mature, natural CVF. Recombinant pro-CVF supports the activation of factor B in the presence of factor D and Mg2+ and depletes serum complement activity like natural CVF. The bimolecular convertase pro-CVF,Bb exhibits both C3 cleaving and C5 cleaving activity. The activity of pro-CVF and the resulting C3/C5 convertase is indistinguishable from CVF and the CVF,Bb convertase. The ability to produce active forms of pro-CVF recombinantly ensures the continued availability of an important research reagent for complement depletion because cobra venom as the source for natural CVF will be increasingly difficult to obtain as the Indian cobra is on the list of endangered species. Experimental systems to express pro-CVF recombinantly will also be invaluable for studies to delineate the structure and function relationship of CVF and its differences from C3 as well as to generate human C3 derivatives with CVF-like function for therapeutic complement depletion ("humanized CVF").

Functional role of the noncatalytic subunit of complement C5 convertase

The C5 convertase is a serine protease that consists of two subunits: a catalytic subunit which is bound in a Mg2+-dependent complex to a noncatalytic subunit. To understand the functional role of the noncatalytic subunit, we have determined the C5-cleaving properties of the cobra venom factor-dependent C5 convertase (CVF, Bb) made with CVF purified from the venom of Naja naja (CVFn) and Naja haje (CVFh) and compared them to those for two C3b-dependent C5 convertases (ZymC3b,Bb and C3b,Bb). A comparison of the kinetic parameters indicated that although the four C5 convertases (CVFn,Bb, ZymC3b,Bb, CVFh,Bb, and C3b,Bb) had similar catalytic rate constants (kcat = 0.004-0.012 s-1) they differed 700-fold in their affinity for the substrate as indicated by the Km values (CVFn,Bb = 0.036 microM, ZymC3b,Bb = 1.24 microM, CVFh,Bb = 14.0 microM, and C3b,Bb = 24 microM). Analysis of binding interactions between C5 and the noncatalytic subunits (CVFh or C3b, or CVFn) using the BIAcore, revealed dissociation binding constants (Kd) that were similar to the Km values of the respective enzymes. The kinetic and binding data demonstrate that the binding site for C5 resides in the noncatalytic subunit of the enzyme, the affinity for the substrate is solely determined by the noncatalytic subunit and the catalytic efficiency of the enzyme appears not to be influenced by the nature of this subunit.

The selective cytotoxicity of cobra venom factor immunoconjugate on cultured human nasopharyngeal carcinoma cell line

The selective cytotoxicity of a CVF immunoconjugate on human nasopharyngeal carcinoma cell line was reported. Cobra venom factor (CVF), a C3b-like glycoprotein, was linked to BAC5, a murine monoclonal antibody directed against a human nasopharyngeal carcinoma-associated membrane antigen, by a disulfide bond. The high affinity to cultured human nasopharyngeal cells (CNE2) and the complement activating potency retained in CVF immunoconjugate. Although the equimolar concentration of BAC5 or CVF alone was harmless to CNE2 cells, the CVF immunoconjugate in the presence of fresh human serum exhibited selective cytotoxicity on CNE2 cells in a concentration- (IC50 3.07 x 10(-7) mol/L) and time-dependent manner. No cytotoxicity occurred on either CNE1 (another human nasopharyngeal carcinoma cell line) or MGC-803 (human gastric carcinoma cell line) cells. Furthermore, direct lytic factor (DLF, cardiotoxin) separated from cobra venom, augmented CVF immunoconjugate-induced cytotoxicity significantly. These results indicate that the CVF immunoconjugate has complement-mediated selective cytotoxicity on CNE2 cells, which can be potentiated by DLF.

Complement factor I deficiency in a family with recurrent infections

Factor I deficiency causes a permanent, uncontrolled activation of the alternative pathway resulting in an increased turnover of C3 and consumption of factor B, factor H and properdin. Factor I deficiency is clinically associated with recurrent bacterial infections already in early infancy, mainly affecting the upper and lower respiratory tract, or presenting as meningitis or septicemia. We here report on a Brazilian family (n = 9) with known consanguinity, where in 3/7 children, suffering from chronic otitis, meningitis, and respiratory infections, a complete factor I deficiency was recognized. One of the patients died after fulminant sepsis. Hemolytic activity of the alternative pathway was not detectable in the patients' sera due to decreased plasma concentrations of C3, factor B and properdin. As a consequence of factor I deficiency, C3b could not be metabolized with the result that no C3-derived split products (C3dg/C3d) were detectable in the patients' sera. In vitro reconstitution with purified factor I restored the regulatory function in the patients' sera with the subsequent cleavage of C3b to C3c and C3dg. Factor H levels were decreased in all patients' sera and found to be tightly complexed with C3b resulting in a modified electrophoretic mobility. Upon factor I reconstitution, factor H was released from C3b regaining its beta 1 electrophoretic mobility. Complement-mediated biological functions like opsonization of bacteria, chemotactic activity and phagocytosis in these patients were impaired. The parents (cousins, 2nd degree) and 3/4 siblings had significantly reduced factor I plasma levels without further alteration in their complement profile. 3 of these obviously heterozygously deficient family members suffered from recurrent bacterial infections of different frequency and severity.

Additive cytotoxicity of different monoclonal antibody-cobra venom factor conjugates for human neuroblastoma cells

Insufficient numbers of antigen molecules and heterogeneity of antigen expression on tumor cells are major factors limiting the immunotherapeutic potential of the few clinically useful monoclonal antibodies capable of mediating complement cytotoxicity and antibody-dependent cellular cytotoxicity. To overcome this limitation, we converted two non-cytotoxic monoclonal anti-neuroblastoma antibodies, designated 3E7 (IgG2b) and 8H9 (IgG1), and the non-cytotoxic F(ab')2 fragment of the cytotoxic monoclonal anti-GD2 antibody 3F8 (IgG3) into cytotoxic antibody conjugates by covalent attachment of cobra venom factor (CVF), a structural and functional homologue of the activated third component of complement. Competitive binding experiments confirmed the different specificities of the three antibodies. In the presence of human complement, all three antibody-CVF conjugates mediated selective complement-dependent lysis of human neuroblastoma cells. Consistent with the kinetics of the alternative pathway of complement, approximately seven hours incubation were required to reach maximum cytotoxicity of up to 25% for the 3E7-CVF conjugate, up to 60% for the 8H9-CVF conjugate, and up to 95% for the 3F8 F(ab')2-CVF conjugate. The different extent of maximal cytotoxic activity of the three conjugates was reflected by corresponding differences in the extent of binding of both unconjugated antibodies and the respective conjugates. Any combination of the three antibody-CVF conjugates caused an additive effect in complement-mediated lysis. Using a cocktail of all three conjugates, the extent of complement-mediated killing could be increased up to 100%. These data demonstrate that by coupling of CVF the relative large number of non-cytotoxic monoclonal anti-tumor antibodies of interesting specificity can be used to design cocktails of cytotoxic conjugates and, thereby, to overcome the problem of insufficient and heterogeneous antigen expression on tumor cells for immunotherapy.

Human factor H and C4b-binding protein serve as factor I-cofactors both encompassing inactivation of C3b and C4b

Human factor H in the complement (C) system has been characterized as a decay-accelerator for the alternative C pathway C3 convertase and a cofactor for factor I-mediated inactivation of C3b. The current concept is that it does not serve as a C4b-inactivating cofactor. In the present study, we demonstrated that in fluid-phase, factor H and Factor I can cleave methylamine-treated C4(C4ma), a C4b analogue, to C4d, regardless of its isotype. The buffer pH and ionic strength were critical factors for the C4ma cleavage, which proceeded at around pH 6.0 and low conductivity around 3.0 mS. Similar results were obtained with fluid-phase C4b. Cell-bound C4b, however, did not undergo factor I-mediated inactivation by factor H. Hence, all of the human cofactors reported to date can mediate factor I-mediated cleavage of both C3b and C4b at least in the fluid-phase.

Functional properties of the allotypes of mouse complement regulatory protein, factor H: difference of compatibility of each allotype with human factor I

Three allotypes of mouse factor H, H.1, H.2, and H.3 were purified from the sera of mice with different factor H allotypes, and their functional properties were investigated. The three allotypes all bound to heparin, DNA, Con A, and methylamine-treated mouse C3 (C3(MA)mo) with similar affinities for each protein immobilized, showed identical mobilities on SDS-PAGE, and were reacted well with rabbit polyclonal antibody against H.1 and H.2. Factor I-cofactor activity of these factor H allotypes was measured using highly purified material of mouse, guinea-pig, and human origin. In a homologous system, these allotypes expressed indistinguishable mouse factor I (Imo)-cofactor activity for the cleavage of C3(MA)mo. Imo-cofactor activity was again indistinguishable in these allotypes when methylamine-treated human C3 (C3(MA)hu) or methylamine-treated guinea-pig C3 (C3(MA)gp) was substituted for the C3(MA)mo substrate. The cofactor activity of these factor H allotypes, however, was augmented 4-5 times if C3(MA)hu) was used instead of C3(MA)mo, and was barely detected if C3(MA)gp was employed. In contrast, differences in the potency of the cofactor activity for the three allotypes were revealed if human factor 1 (Ihu) was substituted for Imo: the order of the efficiency for the cleavage of C3(MA)hu was H.2 > H.1 = H.3. These results, taken together with the finding that the homologous combinations of mouse and human factors H and I expressed greater activity for the cleavage of C3(MA)hu than did the heterologous combinations of factor H and factor I, suggest that mouse factor H allotypes discriminate species of protease factor I but not those of substrate (C3(MA), and H.2 possesses the best compatibility for Ihu in C3(MA)hu inactivation.

A new biological activity of the complement factor H: identification of the precursor of the major macrophage-chemotactic factor in delayed hypersensitivity reaction sites of guinea pigs

The guinea pig complement factor H(FH) and the plasma precursor(PMCFS-1) of the major monocyte-chemotactic factor(MCFS-1) found in the skin site of delayed hypersensitivity reaction(DHR) induced in the guinea pigs were compared in the antigenicity and the function. Both anti-FH-IgG and anti-MCFS-1-IgG formed a single precipitation line against FH, PMCFS-1, MCFS-1 and guinea pig plasma, and these lines fused one another without any spur formation. The inhibition activity of FH for C3bBb was absorbed by anti-MCFS-1-F(ab')2 in a dose-dependent manner. PMCFS-1 inhibited C3bBb activity dose-dependently as FH. These results show that FH is identical to PMCFS-1 and imply that FH, converted to MCFS-1 plays as a monocyte-chemotactic factor in the site of DHR.

Structure of the major oligosaccharide of cobra venom factor

Cobra venom factor (CVF), the complement-activating glycoprotein in cobra venom, contains three or possibly four N-linked oligosaccharide chains per molecule and is devoid of O-linked saccharides. Analysis by lectin-affinity staining revealed the presence of complex-type oligosaccharides containing non-reducing terminal alpha-galactosyl residues and fucose residues linked to the proximal N-acetylglucosamine. Sialic acid residues could not be detected. For their structural analysis, the oligosaccharides were released by hydrazinolysis and fractionated on Bio-Gel P-4. Approximately 80% of the eluted oligosaccharides have a size equivalent of 17 +/- 2 glucose units. The major oligosaccharide representing about 45% of the total carbohydrate present in CVF was purified to homogeneity by MicroPak AX-5 HPLC and its structure was analyzed by sequential exoglycosidase digestion. The positions of the glycosidic linkages of the sugar residues were established by methylation analysis of CVF-derived glycopeptides. The data of these analyses indicated that the major oligosaccharide has a symmetrical fucosylated biantennary complex-type structure terminating with unusual alpha-galactosyl residues.

Regulatory system of guinea-pig complement C3b: tests for compatibility of guinea-pig factors H and I with human factors

Two proteins that are involved in cleavage of methylamine-treated C3 of guinea-pig origin (C3(MA)gp) have been isolated from guinea-pig serum. One of them functioned as a cofactor of human factor I (Ihu) for cleavage of C3(MA)gp and its molecular size was 150 kDa. The other was functionally pure and able to cleave C3(MA)gp together with human factor H (Hhu). They appear to be analogous to human factors H and I in the guinea-pig and will be referred to as Hgp and Igp. Methylamine-treated human C3 [C3(MA)hu] was not a compatible substrate for Hgp or Igp: little cleavage of C3(MA)hu was observed if human factor H (Hhu) or I was substituted with the guinea-pig counterpart. C3(MA)gp, on the other hand, served as a substrate, though less efficiently, for Hhu and Ihu. Human C4b-binding protein (C4bp) and membrane cofactor protein (MCP) as well as Hhu could participate in cleavage of C3(MA)gp by Igp or Ihu. In these assays, C3(MA)gp was degraded again less efficiently than C3(MA)hu. Interestingly, human C3b/C4b receptor (CR1) mediated factor I-dependent cleavage of C3(MA)hu and C3(MA)gp to a similar extent regardless the sources of factor I. These results suggest that factor I-dependent C3b regulatory system is species-specific except in the case of CR1, which may function as a cofactor irrespective of species.

In vivo anti-complementary activities of the cobra venom factors from Naja naja and Naja haje

The kinetics of complement (C) depletion and recovery of C levels upon injection of BALB/c mice with cobra venom factors (CVF), from N. naja (C3- and C5-depleting) and N. haje (selectively C3-depleting) were studied. The animals received i.p. or i.v. injections of either of the two preparations. CH50 and hemolytic C3 and C5 levels were followed as parameters of residual complement activity. N. naja CVF turned out to be as efficient in depleting total complement activity as N. haje CVF. Decreased CH50 values could largely be ascribed to C3 depletion. Complement consumption after N. naja CVF, however, lasted longer than after N. haje CVF administration. Estimated functional half-lives of N. naja and N. haje CVF were 11.5 and 4.5 h, respectively. Inhibition ELISAs showed that, after in vivo administration of either of the two CVF preparations, antigenic C3 and C5 kept circulating for days.

Functional assay of C5-activating and nonactivating cobra venom factor preparations in the mouse system

This paper deals with a new, functional assay of cobra venom factor (CVF) preparations with or without C5-activating property. Existing methods lack sensitivity and use diluted human complement as target of inactivation. An adapted assay using diluted mouse serum as complement source was hampered by underestimation of C3 depletion by bystander lysis and an overvaluation of C5 consumption resulting from C3 inactivation in the reagent used. These disadvantages prompted us to develop the new assay which is based on the incubation of CVF preparations with undiluted mouse serum. After incubation, residual total C activity, as well as functional C3 and C5 are estimated by titration. The procedure permits the assessment of CVF activities with minimal interference from undesired processes. The conditions in the new assay approach the in vivo situation in mice by the use of undiluted serum from the same animal species.

Complement killing of human neuroblastoma cells: a cytotoxic monoclonal antibody and its F(ab')2-cobra venom factor conjugate are equally cytotoxic

Only a few monoclonal antibodies mediate complement lysis of tumor cells, but for several antibodies it has been demonstrated that a complement-activating function can be introduced by covalent coupling of cobra venom factor (CVF), a non-toxic glycoprotein which is a structural and functional homologue of human complement component C3. In this study we compared the efficacy of complement killing of human neuroblastoma cells by the complement-activating monoclonal antibody 3F8 directed against the GD2 ganglioside antigen with that of its F(ab')2-CVF conjugate. At equal numbers bound per cell the 3F8 antibody and the 3F8 F(ab')2-CVF conjugate were found to be equally cytotoxic in the presence of complement from several species including human. Maximal killing reached up to 98%. The kinetics of killing and the bivalent metal requirement confirmed that the cytotoxic activity of the 3F8 antibody is mediated via the classical pathway and that of the 3F8 F(ab')2-CVF conjugate via the alternative pathway. To achieve a comparable degree of killing, an approximately eight-fold higher concentration of the 3F8 F(ab')2-CVF conjugate was required which appears to be a consequence of the approximately eight-fold lower binding activity of the 3F8 F(ab')2-CVF conjugate compared to the intact 3F8 antibody. Our data suggest that the coupling of CVF to non-cytotoxic antibodies allows the generation of conjugates with a cytotoxic activity similar to that of inherently cytotoxic antibodies.

Factor H

While the mouse and human H proteins are structurally and functionally similar, they differ in their genetics. Whereas there is no evidence in humans for more than one gene; in mice the H locus is complex. Based on cDNA sequence and hybridization analysis of genomic cosmid clones, there are at least three distinct genes, all highly related to one another. The consensus repeating unit that comprises this molecule has obviously been duplicated numerous times, since it is present in many other molecules. Thus, it is not surprising to discover that there are several genes related to H in the mouse. A similar case has been described for two other members of this family. In humans, CR1 cDNA hybridizes to two distinct genomic clusters in the CR1 locus (Wong et al. 1989), and in mice, mCRY hybridizes to two regions in the genome, one on chromosome 1 and another on chromosome 8 (Aegerter-Shaw et al. 1987). It will be of interest to see if any other members of this family display as complex a genetic locus as murine H.

The oligosaccharide chains of cobra venom factor are required for complement activation

To examine the function of the carbohydrate chains of cobra venom factor (CVF), the molecule was enzymatically deglycosylated under non-denaturing conditions with N-glycanase (peptide-N4-(N-acetyl-beta-glucosaminyl) asparagine amidase). The deglycosylation of CVF chains seems to proceed independently of each other, leading to partially deglycosylated intermediates. Complete deglycosylation of CVF was found to abolish the activity of CVF. The deglycosylated molecule is unable to activate the alternative pathway of complement. Deglycosylated CVF no longer consumes the serum complement activity, it does not induce C3 activation in serum, nor does it induce complement-mediated hemolysis. These results indicate that the carbohydrate moieties of CVF are essential for its role in complement activation.

Two different mechanisms of serum resistance in Escherichia coli

Fifty-three serum-resistant strains of E. coli which were all able to grow in at least 50% normal human serum (NHS) were tested in respect to binding and consumption of C3b, factor H, C5, and C6 after incubation in pooled NHS. The results of immunofluorescence tests, hemolytic assays, and binding studies using radiolabeled components were comparable. The different binding patterns allowed us to divide the strains into three different groups. The main features of group I were the attachment of C3, C5, and C6 to the bacterial cells as well as consumption of C3 and C5, whereas factor H did not bind at all or only in small amounts. In addition, released MAC was detectable in the supernatant of reaction mixtures containing bacteria of a group I strain and NHS. In group II factor H was easily bound to the bacteria, but no C3, C5, and C6 binding or C5 consumption was detectable. In addition, strains of group III bound C3 and factor H and some strains also bound and consumed C5. Because of the inhomogeneity of group III, this investigation was restricted to a comparison of groups I and II. From the results presented in this study we conclude that group I bacteria activate the whole complement cascade, whereas with bacteria of group II, complement activation is interrupted at the C3 level. These findings therefore indicate a second, alternative mechanism of serum resistance in E. coli.

Antibody conjugates with cobra venom factor. Synthesis and biochemical characterization

Immunoconjugates are semi-synthetic hybrid proteins which bear great promise to become a new generation of anti-tumor agents. While many immunoconjugates have been shown to be selectively cytotoxic in in vitro model systems, dramatic in vivo anti-tumor effects have not been reported. To improve the activity of immunoconjugates, careful structure-function analyses have to be performed. We report here such an analysis for immunoconjugates consisting of a monoclonal anti-tumor antibody (MoAb) and cobra venom factor (CVF), the complement-activating glycoprotein from cobra venom, synthesized with the heterobifunctional crosslinking reagent N-succinimidyl-3-(2-pyridyldithio)propionate (SPDP). It is shown that a reaction mixture after protein coupling contains free MoAb and CVF as well as hybrid proteins of different compositions (dimers (MoAb-CVF), trimers (MoAb2-CVF, MoAb-CVF2), tetramers (MoAb-CVF3, MoAb2-CVF2, MoAb3-CVF), and some higher oligomers). While free MoAb and CVF can be removed by size exclusion chromatography, separation of different oligomeric hybrid proteins is not possible by this method. From the biochemical characterization of the hybrid proteins, which included the determination of sedimentation coefficients, recording of circular dichroism spectra with subsequent determination of secondary structure, and ultrastructural analysis by transmission electron microscopy, it was concluded that the two proteins do not undergo major structural changes upon coupling, and that the coupling of the two proteins is random with no preferential relative orientation. The functional inactivation of CVF was substantial (approximately 70%) due to both derivatization with SPDP and subsequent conjugation to the MoAb, with conjugation being relatively more inactivating than derivatization. In contrast, the binding activity of the antibody was far less susceptible to inactivation. In conclusion, our data indicate that immunoconjugate synthesis with heterobifunctional crosslinking reagents results in a mixture of heterogeneous hybrid proteins and causes substantial functional inactivation. For successful in vivo anti-tumor activity of future immunoconjugates with CVF and other protein ligands better methods for immunoconjugate synthesis will have to be developed.

Localization of the complement-component-C3b-binding site and the cofactor activity for factor I in the 38kDa tryptic fragment of factor H

Trypsin treatment of human factor H (H160) [enzyme/substrate ratio 1:100 (w/w), 30 min, 37 degrees C] generated a 38 kDa (H38) and a 142 kDa (H142) fragment linked by disulphide bonds (H38/142). The fragments were purified by reduction with 2-mercapto-ethanol, gel filtration on a Sephadex G-200 column and affinity chromatography with monoclonal anti-(factor H) antibody coupled to Sepharose 4B. This monoclonal antibody bound to a site in the 38 kDa fragment. To localize the C3b binding site in factor H we used two enzyme-linked immunosorbent assays (e.l.i.s.a.). For the first test, e.l.i.s.a. plates were coated with C3b; H160, H38/142, H38 and H142 were added, and their binding was monitored by goat anti-(factor H) and peroxidase-labelled rabbit anti-goat antibodies. Only intact factor H bound to the C3b-coated plates. For the second test, e.l.i.s.a. plates were coated with comparable amounts of factor H or its fragments, and C3b was offered at several dilutions. In contrast with the results from the first assay, C3b bound to intact factor H, H38/142 and H38 but not to H142, thus characterizing H38 as the fragment carrying the C3b-binding site. To identify the fragment responsible for the cofactor activity of factor H (cleavage of fluid-phase C3b by factor I), 125I-C3b was incubated with either H38 or H142 and factor I. H142 had no cofactor activity, whereas H38 had the same cofactor function as intact H. To further investigate the relationship between the C3b-binding site and the site of factor H essential for its cofactor activity, we made use of monoclonal antibodies directed against the H38. Those antibodies inhibiting the binding of C3b to H160 also inhibited the cofactor function, whereas those without effect on the C3b binding also did not interfere with the cofactor activity. This suggests that the C3b-binding site and the site essential for the cofactor activity of factor H are both localized in the 38 kDa tryptic fragment of factor H in close proximity or are identical.

Cobra venom factor: improved method for purification and biochemical characterization

A method to purify cobra venom factor (CVF) from cobra venom by sequential column chromatography is described which yields a product virtually free of phospholipase A2, a common contaminant of CVF preparations. The separation of phospholipase A2 from CVF was achieved by chromatography on Cibacron blue-agarose, a resin that tightly binds cobra venom phospholipase A2. A rapid and simple hemolytic assay for the qualitative and quantitative determination of CVF based on its ability to induce bystander lysis of erythrocytes has been devised. CVF was isolated from the venom of the Naja naja kaouthia subspecies and some of its biochemical properties and physicochemical parameters were delineated.

Isolation of two molecular populations of human complement factor H by hydrophobic affinity chromatography

Human complement factor H was prepared in highly purified form from fresh serum by euglobulin precipitation, DEAE-Sephacel chromatography and Sephacryl S-300 gel filtration. This preparation allowed the recovery of 37% of the initial factor H. Sodium dodecyl sulphate/polyacrylamide-gel electrophoresis revealed that factor H was homogeneous both in reduced and non-reduced media and exhibited a molecular mass of 150 kDa. Charge-shift experiments clearly showed the presence of hydrophobic sites in the factor H molecule. Charge shifts were observed with two detergent systems (Triton/sodium deoxycholate and Triton/cetyltrimethylammonium bromide). Factor H was able to bind to phenyl-Sepharose. This property allowed us to study two populations of factor H. These two populations exhibited the same physicochemical parameters, but revealed differences in their ability to aggregate in low- and iso-ionic-strength media. The molecular basis and biological significance of this heterogeneity are discussed.

Complement receptor expression of primates and non-primates detected by the rosette formation technique

The expression of complement receptors were studied on erythrocytes and platelets from 14 non-human primates and 3 non-primate species by rosette formation. It was found that the reactivity of erythrocytes with the cell bound complement is deeply dependent on which species are used as the complement source. The erythrocytes from Prosimian do not react with any kind of complement, while their platelets react with many kinds of complement. New World monkey erythrocytes do not react with indicator cells binding complements from guinea pig or man, while some of them react with indicators binding complements from non-human primate species. Contrarily Old World monkey erythrocytes react with complements from guinea pig, man and non-human primate. Hominoidea erythrocytes reacted with all the complements tested. Rabbit expresses C3 receptors on their erythrocytes for rabbit C3 and on their platelets for rabbit, guinea pig or mouse C3. Guinea pig expresses receptors on their erythrocytes for guinea pig and mouse C3, and on their platelets for guinea pig, mouse, rabbit and human C3. It becomes clear that not all of erythrocytes from primate and platelets from non-primate always express complement receptors as has been stated in the text books.

Regulation of the binding of C3-coated particles to human lymphocytes by human complement component H

Human complement component H was found to modify greatly the binding of C3-coated particles to lymphocytes. We used an experimental model in which lymphocytes were mixed successively with various amounts of H and C3b-coated erythrocytes. At least three mechanisms were postulated to interpret the phenomenon: (i) release of endogenous I by lymphocytes triggered by H through specific binding sites, (ii) cleavage of iC3b by I, promoted by complement receptor type one, and (iii) inhibition of immune adherence by H. Such qualitative and quantitative changes in C3-coated particle recognition by the binding sites might mediate important functions of lymphocytes.

Quantitation of in vitro opsonic activity of human antibody induced by a vaccine consisting of the type III-specific polysaccharide of group B streptococcus

Human antibody, induced by a vaccine consisting of undegraded and highly purified extracellular type III-specific polysaccharide of group B streptococcus, was shown to increase the rate of phagocyte-mediated killing of bacteria of the homologous type. The bactericidal effect was mediated by type III-specific antibody and was complement dependent. An assay which permitted quantitation of "opsonic activity" was developed. In this assay, loss of CFUs occurred at a constant rate, and the rate constant was used as a measure of opsonic activity of antisera. A linear relationship between type III-specific antibody concentration (40 to 500 ng/ml) and the rate constant of killing was observed. When sets of immune sera were tested, some sera reacted anomalously, mediating significantly higher or lower rates than expected on the basis of their antibody content. Since type III-specific antibody in immune sera was found almost exclusively in the immunoglobulin G class, we hypothesize that differences in immunoglobulin G subclass distribution of specific antibody may have been the source of this variation.

Circular dichroism studies of human factor H. A regulatory component of the complement system

Factor H of the human complement system exhibits an unusual circular dichroism spectrum. The CD spectrum of Factor H exhibits a positive extreme at 230 nm and a negative extreme at 190 nm. No apparent alpha-helical or beta-sheet conformations were present in the native protein structure. However, when the disulfide bridges are reduced, followed either by reoxidation or alkylation, the structure of Factor H is modified so that it now exhibits conventional protein secondary structure as determined from its CD spectra in the far ultraviolet region. Factor H also fails to mediate its regulatory function of inhibiting the alternative pathway convertase once the disulfides have been ruptured and conformational rearrangement has occurred. CD studies indicate that minor conformational changes take place when Factor H and C3b associate in free solution.

Purification and structural studies on the complement-system control protein beta 1H (Factor H)

An efficient procedure for the isolation of the complement-system control protein beta 1H (Factor H) from human plasma was developed. The chemical composition and physical characteristics of the protein were studied, and a sequence of 17 amino acid residues at the N-terminus was determined. Factor H is a single-polypeptide-chain glycoprotein of mol.wt. 155 000 containing 9.3% carbohydrate. Factor H is cleaved by plasma proteinases to a two-chain form. This cleavage can be mimicked by trypsin, and the two-chain form retains fully the C3b-inactivator cofactor activity of Factor H. The proteolytic fragments of Factor H are compared with those of other proteins (C4b-binding protein and erythrocyte C3b-receptor) that act as cofactors for C3b-inactivator.

The binding of human complement proteins C5, factor B, beta 1H and properdin to complement fragment C3b on zymosan

The covalent binding of complement fragment C3b to zymosan by the action of the alternative-pathway C3 convertase and the reversible binding of several complement proteins (component C5, factor B, beta 1H and properdin) to C3b on zymosan have been investigated. When C3b is deposited on zymosan after activation by a surface-bound C3 convertase, the C3b molecules are deposited in foci around the C3 convertase site, with an average of 30 C3b molecules per site. The association constants of C5, factor B, beta 1H, and properdin for C3b bound to zymosan have been determined. The association constants ranged from 6.5 x 10(-5) M-1 for factor B to 2.9 x 10(7) M-1 for properdin. An approximate stoichiometry of 1 : 1 for C5, factor B, and properdin binding to C3b has been observed. Curvilinear Scatchard plots were observed for beta 1H binding to C3b, with the maximal extrapolated ratio of beta 1H to C3b of 0.32. Physiological amounts of properdin increase by 7-fold the affinity constant for factor B binding to C3b with no alteration in the stoichiometry. Similarly, physiological amounts of factor B increase the affinity constant of properdin to C3b about 4-fold with only a small measured difference in stoichiometry. Competition binding studies and protein modification suggest that C5, factor B, beta 1H, and properdin each bind to a distinct region on C3b.

Complement receptor is an inhibitor of the complement cascade

A glycoprotein from the membrane of human erythrocytes has been identified as a receptor for C3b (CR1). It promotes the dissociation of the alternative pathway C3 convertase C3b,Bb and the cleavage of C3b by C3b/C4b inactivator. We find that CR1 also inactivates the C3 and C5 convertases of the classical pathway. CR1 inhibits the consumption of C3 by C3 convertase EAC142 and enhances the decay of C4b,2a sites. On a weight basis, CR1 is approximately 5-10 times more active than C4 binding protein, a serum inhibitor of C4b,2a. The binding of 125I-CR1 to EAC14 cells is inhibited by C2. Therefore, it is likely that CR1 and C2 compete for a site on C4b. CR1 inhibited C5 convertase even more effectively, but had no effect on the assembly of the late complement components. At high concentrations, CR1 alone has no irreversible effects on cell-bound C4b. In the fluid phase, CR1 can function as a cofactor for the cleavage of the alpha' chain of C4b by C3b/C4b inactivator. A well-known function of CR1 is to promote adherence of microbes or immune complexes bearing C3b and C4b to cells. This interaction could result in a microenvironment damaging to the plasma membrane of the responding cell because the extrinsic C3b and C4b fragments can serve as additional sites of assembly of enzymes of the cascade. We therefore wish to propose that CR1 on the surface of cells supplies an increased local concentration of a strong inhibitor of the amplifying enzymes of the complement system and provides cells with a mechanism for circumventing damage when they bind C3b- and C4b-bearing substrates.