The C3 convertase of the alternative pathway of human complement. Enzymic properties of the bimolecular proteinase

C3 activation is inhibited by analogs of compstatin but not by serine protease inhibitors or peptidyl alpha-ketoheterocycles

C3 convertase is a key enzyme in the complement cascade and is an attractive therapeutic target for drug design. Recent studies have demonstrated that this enzyme is inhibited by compstatin (Morikis, D. , Assa-Munt, N., Sahu, A., Lambris, J.D., 1998. Solution structure of Compstatin, a potent complement inhibitor. Protein Sci. (7) 619-627; Sahu, A., Kay, B.K., Lambris, J.D., 1996. Inhibition of human complement by a C3-binding peptide isolated from a phage-displayed random peptide library. J. Immunol. (157) 884-891), a 13 amino acid cyclic peptide that binds to C3. Since the enzyme exhibits some homology to serine proteases, substrate-based design could be another avenue for drug design. In this study, we confirm the activity of compstatin using different sources of enzyme and different assay systems. We also tested the activity of substituted compstatin analogs and compared the selectivity and toxicity of these compounds to peptidyl alpha-ketoheterocyclic compounds. Our work confirms the activity of compstatin in both alternative and classical complement pathways, describes 11 new active analogs of this cyclic peptide, and provides evidence for key segments of the peptide for activity. Compstatin and related active analogs showed little or no inhibition of clotting or key enzymes in the clotting cascade nor did they appear to have significant cytotoxicity. The characteristics of compstatin suggest that this peptide and its analogs could be attractive candidates for further clinical development. By contrast, known serine protease inhibitors, including peptidyl alpha-ketoheterocycles, did not inhibit C3 convertase illustrating the atypical nature of this enzyme.

Activation of the alternative pathway of human complement by autologous cells expressing transmembrane recombinant properdin

Properdin (P) is a serum glycoprotein that stabilizes the labile C3 convertase (C3bBb) of the alternative pathway of the complement system (AP). Thanks to its oligomeric nature, P specifically upregulates AP on surfaces without activating AP in the fluid-phase. We investigated whether human cells, displaying P at their membrane, could activate autologous AP. The cDNAs encoding human P and the transmembrane domain of human platelet derived growth factor receptor were fused together and expressed in human embryo kidney cells (HEK-293). Selected cells displayed P at their surface as shown by FACS. In contact with human serum at 37 degrees C, they triggered AP-mediated C3 deposition. SDS-PAGE analysis showed C3 covalently bound to various membrane proteins, but not to P itself. However, displayed P affinity could bind to serum or purified C3i at 4 degrees C. C3 binding was restricted to the cells displaying P, was inhibited by an anti-P mAb, and did not require serum P. Bound C3 allowed further C5, C7 and C9 deposition as well as cell lysis after blocking CD59 function. In contrast, wild-type cells, cells displaying factor D or truncated P (deleted from its 6th thrombospondin-like repeat) did not activate AP. We hypothesize that displayed P activates AP by stabilizing bystander C3b and/or by capturing serum C3iBb convertase. Finally, we suggest that P could be used for retargeting autologous complement to AP-resistant pathogens and tumor cells.

Inhibition of complement alternative pathway function with anti-properdin monoclonal antibodies

Complement activation products appear to contribute to the pathology of several acute and chronic inflammatory conditions. The relative contributions of the classical and alternative complement pathways to these pathologies have, in large part, been undefined. Considerable progress has been made recently in identifying inhibitors of complement activation and demonstrating that such molecules can attenuate inflammation in various models of disease. However, most of these complement inhibitors affect aspects of both the classical and alternative pathways. In an effort to better define the role of the alternative complement pathway in complement-mediated inflammatory conditions, we have developed monoclonal antibodies that specifically inhibit alternative pathway function. These blocking antibodies bind human properdin with high avidity and prevent its interaction with the alternative pathway C3 convertase. This results in a cessation of alternative pathway function in several in vitro assay systems. When tested in a model of cardiopulmonary bypass, in which human blood passes through tubing, a selected antiproperdin antibody caused nearly complete inhibition of the C3a and C5b-9 formation that was seen in untreated blood. Moreover, the anti-properdin agent resulted in a dramatic reduction of neutrophil and platelet activation in the bypass model. Surprisingly, the monoclonal antibody also caused a significant inhibition of C5b-9 generation when classical pathway activators, such as heparin-protamine or immune complexes, were added to human blood. These latter data suggest that the alternative pathway contributes significantly to the formation of complement activation products in blood when the classical pathway is initially triggered.

New structural motifs on the chymotrypsin fold and their potential roles in complement factor B

Factor B and C2 are two central enzymes for complement activation. They are multidomain serine proteases and require cofactor binding for full expression of proteolytic activities. We present a 2.1 A crystal structure of the serine protease domain of factor B. It shows a number of structural motifs novel to the chymotrypsin fold, which by sequence homology are probably present in C2 as well. These motifs distribute characteristically on the protein surface. Six loops surround the active site, four of which shape substrate-binding pockets. Three loops next to the oxyanion hole, which typically mediate zymogen activation, are much shorter or absent. Three insertions including the linker to the preceding domain bulge from the side opposite to the active site. The catalytic triad and non-specific substrate-binding site display active conformations, but the oxyanion hole displays a zymogen-like conformation. The bottom of the S1 pocket has a negative charge at residue 226 instead of the typical 189 position. These unique structural features may play different roles in domain-domain interaction, cofactor binding and substrate binding.

Mutational analysis of the primary substrate specificity pocket of complement factor B. Asp(226) is a major structural determinant for p(1)-Arg binding

Factor B is a serine protease, which despite its trypsin-like specificity has Asn instead of the typical Asp at the bottom of the S(1) pocket (position 189, chymotrypsinogen numbering). Asp residues are present at positions 187 and 226 and either one could conceivably provide the negative charge for binding the P(1)-Arg of the substrate. Determination of the crystal structure of the factor B serine protease domain has revealed that the side chain of Asp(226) is within the S(1) pocket, whereas Asp(187) is located outside the pocket. To investigate the possible role of these atypical structural features in substrate binding and catalysis, we constructed a panel of mutants of these residues. Replacement of Asp(187) caused moderate (50-60%) decrease in hemolytic activity, compared with wild type factor B, whereas replacement of Asn(189) resulted in more profound reductions (71-95%). Substitutions at these two positions did not significantly affect assembly of the alternative pathway C3 convertase. In contrast, elimination of the negative charge from Asp(226) completely abrogated hemolytic activity and also affected formation of the C3 convertase. Kinetic analyses of the hydrolysis of a P(1)-Arg containing thioester by selected mutants confirmed that residue Asp(226) is a primary structural determinant for P(1)-Arg binding and catalysis.

Inhibition of complement by covalent attachment of rosmarinic acid to activated C3b

Rosmarinic acid has been reported to inhibit complement activation in vivo as well as in vitro. Previous studies suggested that the inhibitory effect was due to inhibition of C3/C5 convertases, but inhibition of C3b attachment would yield the same results. Recent work in our laboratory demonstrated that compounds with polyhydroxylated phenyl rings are highly reactive with the thioester bond in nascent C3b. These compounds block complement activation by preventing attachment of C3b to the activating surface. Because rosmarinic acid contains two 3,4-dihydroxyphenyl groups, the current study was undertaken to re-examine the mechanism of inhibition by analyzing the effect of rosmarinic acid on C3b attachment. In assays using purified complement proteins, rosmarinic acid inhibited covalent attachment of C3b to cells with an 1C50 = 34 microM. Inhibition of C5 convertase activity required 1500 microM rosmarinic acid, and no significant inhibition of the C3 convertase enzyme, which produces C3b from C3, was observed at 10,000 microM. In hemolytic assays using human serum, rosmarinic acid was shown to inhibit activation of both the classical (IC50 = 180 microM) and the alternative (IC50 = 160 microM) pathways of complement. Rosmarinic acid concentrations up to 10,000 microM did not cause direct inactivation of C3. Radioiodination of rosmarinic acid was used to demonstrate covalent activation-dependent incorporation of rosmarinic acid specifically into the thioester-containing alpha'-chain of nascent C3b. These findings indicate that inhibition of complement activation by rosmarinic acid is due to the reaction of rosmarinic acid with the activated thioester of metastable C3b, resulting in covalent attachment of the inhibitor to the protein.

C5 convertase of the alternative pathway of complement. Kinetic analysis of the free and surface-bound forms of the enzyme

Although proteolytic activation of the complement protein C5 initiates important defensive and occasionally pathological inflammatory reactions, the enzymatic properties of the enzymes responsible for this cleavage have never been examined. We have studied the kinetic parameters of the C5 convertase of the alternative pathway of complement, either bound to a zymosan surface or in its monomeric soluble form. C5 convertase enzymatic activity was measured as a function of C5 concentration by quantitating production of C5b,6 under physiological conditions of temperature, pH, and ionic strength. The C5 convertases appeared to follow Michaelis-Menten kinetics and exhibited similar catalytic rate constants (kcat). However, the surface-bound enzyme, ZymC3b,Bb had a Km (1.4 microM) that was 17 times lower than that of the soluble monomeric form of the enzyme, C3b,Bb (Km = 24 microM). The kcat for the cell-bound enzyme, ZymC3b,Bb was 0.0048 s-1 and that for soluble C3b,Bb was 0.0110 s-1. Both forms of the enzyme had a low turnover number at Vmax (0.23 to 0.68 C5/min/enzyme). Substituting Mg2+ for Ni2+ did not alter the kinetic parameters but lowered the half-life of the enzyme by 5-7-fold. The kinetic data presented demonstrate that the fluid phase C5 convertase, C3b,Bb, can cleave C5 without the aid of a second C3b molecule. The results also show that the greater enzymatic activity previously observed for the surface-bound C5 convertases is not due to higher catalytic efficiency but is solely due to higher affinity for the substrate C5. In blood, C5 concentrations are 3-4-fold below the Km determined for the surface-bound C5 convertase suggesting a direct correlation between the local C5 concentration and production of the anaphylatoxin C5a and the cytolytic C5b-9 complex.

Beneficial effects of systemic immunoglobulin in experimental membranous nephropathy

To test the hypothesis that systemic administration of immunoglobulin might reduce glomerular injury in membranous nephropathy through mechanisms involving inhibition of complement activation, we studied the passive Heymann nephritis (PHN) model of membranous nephropathy in rats. The daily administration of immunoglobulin goat IgG (600 mg/kg i.p.) reduced proteinuria by 52%. Quantitative immunohistochemical analysis showed that the glomerular deposition of C3c, an indicator of ongoing complement attack, and of C5b-9 was significantly decreased in the immunoglobulin treated group, while deposition of anti-Fx1A was not affected. Electron microscopic analysis demonstrated that the extent of subepithelial immune complexes did not appreciably differ between treated and control animals. Systemic complement levels were not altered by immunoglobulin treatment. These data suggest that the reduction in proteinuria that resulted from systemic immunoglobulin administration was mediated by modifying the effect of complement induced glomerular injury. This interpretation was further supported by in vitro data that documented a significant reduction in C5b-9 induced glomerular epithelial cell lysis in the presence of both goat and rat IgG. These results indicate that systemic administration of immunoglobulin can substantially reduce ongoing complement activation in the glomerulus in PHN rats and that this effect is associated with a significant reduction in glomerular injury.

Investigation of mechanism-based inhibitors of complement targeting the activated thioester of human C3

An intramolecular thioester bond in complement protein C3 is vital for covalent attachment of C3b (the proteolytically activated form of C3) to biological surfaces and for activation of the complement system. Proteolytic removal of C3a from C3 activates the thioester in the C3b fragment. Activated C3b primarily forms ester bonds with hydroxyl groups of carbohydrates on complement activating surfaces, but it has also been shown to react with the hydroxyl group of tyrosine and with specific Ser and Thr residues on IgG and on complement protein C4b. To examine the reactivity of the thioester, several families of hydroxylated compounds were examined. Reactivity of a series of substituted phenols varied over two orders of magnitude and demonstrated a linear correlation between reactivity and the Hammett substituent constants. Hydroxylated drugs including members of the L-DOPA/epinephrine family and hydroxamic acids also were examined. Compounds were identified that were 20,000 times more reactive than carbohydrates. These compounds were found to inhibit both the classical and alternative pathways of complement activation. Although the specificity of the thioester for its natural biological targets appears to be determined by many structural features, the data presented here demonstrate that increasing the nucleophilic character of the target hydroxyl group can increase the potency of a synthetic inhibitor many orders of magnitude.

Linear systems analysis of activating processes of complement system as a defense mechanism

The complement system is an important element of the host defense mechanism, although its kinetics and characteristics as a system are still unclear. We have investigated its temporal changes and system properties from the view point of system engineering. The temporal changes of sequential activating processes of the system were expressed by 26 non-linear differential equations using reported values of rate constants and serum concentration for each component. The intermediate products in the activating processes increased parabolically while the membrane attack component as the final product, increased linearly. The little change in inactive precursors afforded validity for system linearization. Linear systems analysis revealed that the system which was insensitive to the changes in rate constants was unstable. The system became stable when the feed-back input from the final product was set to operate on the first step of the activating processes. Seven uncontrollable variables were insensitive to changes in rate constants or system optimization that minimized the changes in concentrations of components in the complement system. The singular values of the complement system were reduced and the impulse responses of the system were improved when the system was optimized. When stronger minimization was imposed on the changes of concentration of the components in the complement system, the singular values were reduced more, the magnitude of the impulse responses was depressed further and the responses terminated earlier than those when the elements in the weighting matrix of concentration of the components were set to be unity. By this potent minimization, the influences of changes in rate constants on the singular values were diminished. The present theoretical analysis is presented to evaluate the ability of defense mechanism of complement system.

Specificity of the thioester-containing reactive site of human C3 and its significance to complement activation

The specificity of the thioester-containing site in three plasma proteins is regulated by elements of their protein structures other than the thioester bond itself. Human C4A and alpha 2-macroglobulin preferentially form amide linkages while human C3 primarily forms ester linkages with hydroxyl groups. We have examined the thioester in C3 and found evidence of strong preferences for certain carbohydrates, indications of selectivity for specific positions on those carbohydrates and a preference for terminal sugars in polysaccharides. A testable set of rules are derived from these findings which predict preferred attachment sites on polysaccharides. A computer model of the effect of different reactivities on activation of the alternative pathway of complement suggested that organisms might greatly alter their susceptibility to complement with small changes in carbohydrate structure. While a random selection of 20 biological particles showed no correlation between activation and C3b attachment efficiency, subsets of related organisms differing primarily in their surface polysaccharide exhibited stronger correlations. The strongest correlation occurred in a series of the yeasts (Cryptococcus neoformans) possessing capsular polysaccharides with one, two, three or four branching xylose sugars per repeating unit. These organisms exhibited capture efficiencies for metastable C3b from 12% (one-xylose strain) to 41% (four-xylose strain).

Immune lysis of Trypanosoma congolense: generation of a soluble covalent complex of variant surface glycoprotein and bovine complement component C3b

Organisms of Trypanosoma congolense variant antigenic type TC13 (VAT TC13) were incubated, at 37 degrees C for 60 min, with fresh bovine serum in the presence of antibody specific for the variant surface glycoprotein (VSG). Upon immune lysis, soluble VSG (54 kDa) and a larger complex (about 225 kDa), containing VSG, was detected in the supernatant fluid of the mixture. Neither soluble VSG nor the VSG complex were detected when fresh bovine serum was incubated with organisms of T. congolense in the absence of specific antibody. Within a narrow range of low antibody concentration, the release of soluble VSG and the formation of the VSG complex were correlated with the amount of specific antibody added to the mixture. The VSG complex could be precipitated with rabbit antibodies specific for VSG of VAT TC13 or antibodies specific for bovine complement C3. The VSG complex was detected by Western blot with rabbit anti-VSG of VAT TC13 as well as rabbit antibovine C3. The complex was found to consist of VSG covalently bound to bovine complement component C3b. Potential pathophysiological implications are discussed.

Glomerular C3c localization indicates ongoing immune deposit formation and complement activation in experimental glomerulonephritis

In antibody-mediated glomerular disease, deposits of C3 (C3b) are common and are degraded by factor I to C3c and C3d. However, the kinetics of C3b degradation in glomerulonephritis have not been defined. To do this, we studied three models of complement-dependent glomerulonephritis with established C3 deposits (passive Heymann nephritis, cationized immunoglobulin G membranous nephropathy, and concanavalin A-anticoncanavalin A glomerulonephritis). C3b deposition was halted by administration of cobra venom factor, and the disappearance of C3c and C3d from glomeruli was measured with specific antibodies and quantitative fluorescence densitometry. Results showed that C3c deposits were reduced by over 85% within 24 hours in all three models. C3c clearance was unaffected by site or mechanism of deposit formation. C3d deposits persisted despite lack of ongoing complement activation. In passive Heymann nephritis when disease activity was monitored by urinary C5b-9 excretion, C3c was cleared in parallel with return of urine C5b-9 excretion to normal values. We conclude that glomerular deposits of C3c are cleared within 24 hours of cessation of complement activation. Positive staining for C3 utilizing antibody specific for the C3c portion documents recent complement activation usually reflecting new immune deposit formation.

Activation of the alternative pathway of complement by monoclonal lambda light chains in membranoproliferative glomerulonephritis

Immunopathological evidence suggests that activation of the alternative pathway of complement (AP) is involved in membranoproliferative glomerulonephritis (MPGN) and in immunoglobulin A nephropathy. In this report we describe an AP dysfunction-associated factor that was isolated from the serum and urine of a patient with hypocomplementemic MPGN. Extensive glomerular deposits of C3, properdin, and of the terminal complement components were observed in the kidney of the patient. In her serum the AP hemolytic activity was virtually absent. When mixed with fresh normal serum, the patient's serum induced a 96% C3 conversion during a 30-min incubation at +37 degrees C. This activity was found to be due to a circulating factor that by immunochemical characterization proved to be a 46-kD monoclonal immunoglobulin lambda light (L) chain dimer (lambda L). Purified lambda L, but not control lambda or kappa L chains from patients with L chain disease, activated the AP in a dose- and ionic strength-dependent manner. Functionally, lambda L was differentiated from C3 nephritic factor (an autoantibody against the AP C3 convertase, C3bBb) by its inability to bind to and stabilize the C3bBb enzyme. Instead, lambda L was observed to interact directly with the AP control factor H. Thus, lambda L represents a novel type of immunoglobulin-related AP-activating factor with the capacity to initiate alternative complement pathway activation in the fluid phase.

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.

A mechanism of activation of the alternative complement pathway by the classical pathway: protection of C3b from inactivation by covalent attachment to C4b

In this work we studied the role of the classical pathway complement component C4b in the activation of the alternative pathway. It was found that nascent C3b attaches with high efficiency to C4b and that C3b in C4bC3b complexes is protected from inactivation by factors H and I. Activation of C3 by factors B and D in the presence of Mg2+ ions and excess C4b led to 35% incorporation of nascent C3b into C4bC3b complexes in the fluid phase. In comparison, when human IgG was tested as an acceptor under similar conditions, only 12% of generated C3b was incorporated into IgGC3b complexes. The half-life time of dissociation of C3b from purified C4bC3b complexes was approximately 2.3 h at 37 degrees C. C4b in these complexes protected C3b from inactivation as effectively as any known alternative pathway activator. Thus, C3b bound to C4b was tenfold more stable than free C3b or C3b bound to a nonactivating surface. In comparison, the protection provided by attachment to human IgG was only 67% of that of C4b. The results provide an explanation for observations of alternative pathway recruitment following classical pathway activation and for the stability of the classical pathway C5 convertase on surfaces which do not provide protection for C3b from factors H and I.

Structures of the asparagine-linked oligosaccharides of guinea-pig factor B of the alternative complement pathway

This paper describes the structures of the asparagine-linked oligosaccharides of two forms of guinea-pig Factor B of the alternative complement pathway with different Mr values. Oligosaccharides were quantitatively liberated from both glycoproteins by hydrazinolysis, fractionated by paper electrophoresis and Bio-Gel P-4 column chromatography, and their structures determined by sequential exoglycosidase digestions in conjunction with methylation analysis. Both glycoproteins were shown to have the same biantennary complex-type oligosaccharides but it is suggested that they contain different numbers of oligosaccharide chains.

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.

Proteolytic activity of the different fragments of factor B on the third component of complement (C3). Involvement of the N-terminal domain of Bb in magnesium binding

Kinetic experiments measuring the proteolytic activity of Bb and 33Kd fragment (the C-terminal domain of factor B) on C3 were performed in several conditions, in order to assess the role of factor B domains in the catalytic activity and magnesium binding. The experiments were carried out in fluid phase with 125I-C3 or C3(H2O) as substrates and in the presence of nonradioactive C3b as cofactor. The results indicate: (a) The C-terminal domain, 33Kd, possesses proteolytic activity on C3, which is Mg2(+)-independent, whereas proteolysis by Bb is enhanced in 5 mM Mg2+. (b) C3b behaves as cofactor of 33Kd proteolytic activity on C3 and factor H is able to inhibit this activity. (d) Kinetics of C3 proteolysis by 33Kd shows a lag phase which is also displayed by Bb in the absence but not in the presence of Mg2+. Taken together these data are consistent with the involvement of the N-terminal domain of Bb in Mg2+ binding, which results in an enhancement of the proteolytic activity on C3 of the adjacent C-terminal domain. A C3 convertase model accounting for these results is presented.

Separation of active and inactive forms of the third component of human complement, C3, by fast protein liquid chromatography (FPLC)

C3(H2O), an inactive form of C3 present to a variable extent in most C3 preparations, has been isolated in 40 min from previously purified C3 using FPLC ion exchange chromatography on a Mono Q column. As many as six peaks were obtained from some C3 preparations, corresponding to different molecular forms of the protein. One of these peaks consisted of a molecular form of C3 with intact alpha and beta chains, a free sulfhydryl group but no hemolytic activity and was identified as C3(H2O). C3(H2O) eluted as a homogeneous peak well resolved from native C3, C3b, high molecular weight aggregates and small degradation fragments. The same C3(H2O) peak was generated from native C3 by repeated freeze-thaw cycles or NH2OH treatment. C3(H2O) alpha chain appeared as a doublet about 2 kDa heavier than native C3 alpha chain in low cross-linked gels. Two forms of C3b could be separated on the Mono S column, both able to form the C3 convertase. The present report describes a very fast method to resolve and isolate to homogeneity C3(H2O) and native C3 from C3 preparations. Both molecular forms of C3 are very suitable for studies of the initial and amplification C3 convertases of the alternative pathway of complement.

Two forms of guinea pig factor B of the alternative complement pathway with different molecular weights

Two forms of guinea pig factor B (B) of the alternative complement pathway with different mol. wts (Mr) have been isolated from plasma and characterized. The Mr of the two B species, tentatively termed B1 and B2, were estimated to be about 100,000 and 96,000, respectively, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Incubation of B with guinea pig C3 and human factor D (D) in the presence of Mg2+ generated two cleavage fragments of B, namely Ba and Bb. Although the Bb fragments showed the same migration corresponding to an Mr of 62,000, Ba fragments showed different mobilities corresponding to an Mr of 38,000 from B1 and 34,000 from B2. Digestion of B1-Ba, the Ba fragment derived from B1, and B2-Ba, the Ba fragment derived from B2, with endoglycosidase F resulted in a band at Mr 30,000 on an SDS-PAGE in both cases, indicating a difference in structure of the asparagine-linked oligosaccharide moiety in B1-Ba and B2-Ba. No difference in antigenicity was noted between B1 and B2 on immunodiffusion with anti-B sera. Immunoblotting analysis showed that all individual Hartley guinea pigs examined in this study possessed both B1 and B2 at similar levels, as determined by the intensity of staining of their sera. Furthermore, treatment of their serum with zymosan led to the generation of two Ba species corresponding to the Ba fragments from B1 and B2. The capacity to form C3/C5 convertase, as determined by hemolytic assay, was found to be similar between B1 and B2. Furthermore, kinetics of the decay of C3 convertase showed the same half-life of 3.0 min at 30 degrees C. The NH2-terminal amino acid sequences of B1 and B2 and their Bb fragments were determined and found to be identical.

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.

A fluorimetric assay for native C3. The hemolytically active form of the third component of human complement

The content of native C3 in samples of purified C3 may be accurately determined using the fluorescent probe ANS (8-anilino-1-napthalene sulfonate). The assay is based on the 11.5-fold increase in fluorescence intensity of ANS which accompanies proteolytic conversion of native C3 to C3b. The assay may be performed in the presence of hemolytically inactive derivatives of C3 such as C3b and C3(H2O). It exhibits the unique feature of being independent of protein concentration and it does not require a C3 standard, other purified complement components, C3 depleted serum, cells or cell-bound intermediate complexes, such as EAC142. A method utilizing cation exchange chromatography (Mono S, Pharmacia) is also described for the rapid (30 min) analytical or preparative separation of native C3 from inactive forms of C3 and from C3 fragments.