Kinetic analysis of the interactions between vaccinia virus complement control protein and human complement proteins C3b and C4b

The vaccinia virus complement control protein (VCP) is an immune evasion protein of vaccinia virus. Previously, VCP has been shown to bind and support inactivation of host complement proteins C3b and C4b and to protect the vaccinia virions from antibody-dependent complement-enhanced neutralization. However, the molecular mechanisms involved in the interaction of VCP with its target proteins C3b and C4b have not yet been elucidated. We have utilized surface plasmon resonance technology to study the interaction of VCP with C3b and C4b. We measured the kinetics of binding of the viral protein to its target proteins and compared it with human complement regulators factor H and sCR1, assessed the influence of immobilization of ligand on the binding kinetics, examined the effect of ionic contacts on these interactions, and sublocalized the binding site on C3b and C4b. Our results indicate that (i) the orientation of the ligand is important for accurate determination of the binding constants, as well as the mechanism of binding; (ii) in contrast to factor H and sCR1, the binding of VCP to C3b and C4b follows a simple 1:1 binding model and does not involve multiple-site interactions as predicted earlier; (iii) VCP has a 4.6-fold higher affinity for C4b than that for C3b, which is also reflected in its factor I cofactor activity; (iv) ionic interactions are important for VCP-C3b and VCP-C4b complex formation; (v) VCP does not bind simultaneously to C3b and C4b; and (vi) the binding site of VCP on C3b and C4b is located in the C3dg and C4c regions, respectively.     

A thermodynamic study of the interaction between human complement components C3b or C3(H2O) and factor B in solution

The fluid-phase interaction between factor B and an activated form of C3 (C3b or C3(H2O)) is fundamental to the formation of the alternative complement pathway C3 convertase. The present study reports on the thermodynamic parameters that govern these interactions. The extrinsic fluorescent probe 8-anilino-1-naphthalene sulfonate (ANS) and factor B were found to act as competitive ligands in binding to C3b. Thus, complex formation between C3b or C3(H2O) and factor B could be monitored by the quenching of C3b/C3(H2O)-dependent ANS fluorescence upon the addition of B. Under physiological conditions (0.5 mM Mg2+, 37 degrees C, mu = 0.15), the Ka governing the binding of C3b to B was 2.5 X 10(6) M-1, whereas the interaction of C3(H2O) with factor B was of 5-fold lower affinity. Both reactions were endothermic, with the van't Hoff enthalpy being approximately +16.0 kcal mol-1 in each case. Thus, a large positive entropy change provides the net driving force in these interactions. Although Ka increased at higher Mg2+ concentrations, this was not an enthalpy-mediated phenomenon. Taken together, these data are consistent with hydrophobic interactions being dominant in C3b.B or C3(H2O).B complex formation. The enhancement of complex formation by Mg2+ and concomitant increase in delta S suggests that the metal ion plays a role in increasing the number of hydrophobic contacts.     

Interaction of uromodulin and complement factor H enhances C3b inactivation

Recent studies suggest that uromodulin plays an important role in chronic kidney diseases. It can interact with several complement components, various cytokines and immune system cells. Complement factor H (CFH), as a regulator of the complement alternative pathway, is also associated with various renal diseases. Thus, we have been suggested that uromodulin regulates complement activation by interacting with CFH during tubulointerstitial injury. We detected co‐localization of uromodulin and CFH in the renal tubules by using immunofluorescence. Next, we confirmed the binding of uromodulin with CFH in vitro and found that the affinity constant (K_D) of uromodulin binding to CFH was 4.07 × 10^?6M based on surface plasmon resonance results. The binding sites on CFH were defined as the short consensus repeat (SCR) units SCR1–4, SCR7 and SCR19–20. The uromodulin‐CFH interaction enhanced the cofactor activity of CFH for factor I‐mediated cleavage of C3b to iC3b. These results indicate that uromodulin plays a role via binding and enhancing the function of CFH.     

Purification of the human complement control protein C3b inactivator.

An alternative method of isolation from human plasma is described for C3b inactivator, C3bINA, the proteinase that in conjunction with either beta 1H or C4b-binding protein will hydrolyse respectively C3b or C4b, the activation products of the third, C3 and fourth, C4, components of complement. The purification is by chromatography of plasma on columns of QAE-Sephadex, wheat-germ agglutinin-Sepharose, hydroxyapatite and Sephacryl S-200. The yield of C3bINA (6 mg from 500ml of plasma) is severalfold higher than in previously described methods. The sensitivity of the assay for C3bINA has been increased by including optimal amounts of beta 1H, and it was observed that beta 1H was essential for hydrolysis by C3bINA of C3b, whether the C3b was in solution or bound to a cell surface. Native C3 is not hydrolysed by C3bINA + beta 1H, but the haemolytically inactive form that appears on prolonged storage at 4 degrees C or on freezing and thawing is hydrolysed and gives fragments of the alpha-chain of 75000 and 43000 apparent mol.wt. As the alpha'-chain of C3b, which has lost an N-terminal peptide C3a, gives fragments of 67000 and 43000 apparent mol.wt. when incubated with C3bINA + beta 1H, this suggests that the larger fragment is N-terminal and the smaller one C-terminal. The pH optimum of C3bINA with soluble substrates is 6.0, but no clear classification of the type of proteinase to which this enzyme belongs has been obtained.     

Phylogeny of regulatory proteins of the complement system. Isolation and characterization of a C4b/C3b inhibitor and a cofactor from sand bass plasma

We have previously demonstrated that the alpha'-chain of human activated form of the fourth (C4b) and third (C3b) component of C are cleaved by plasma or serum from vertebrate species spanning through 300,000,000 yr of evolution yielding fragments identical with those obtained with human plasma. In this study, we investigated the molecular basis of this reaction. We chose barred sand bass plasma because this is the most primitive species analyzed possessing these activities. Barred sand bass plasma proteins were separated on a Sephadex G-200 column and the eluted samples analyzed for C4b and C3b cleavage. Individual fractions were inactive, but degradation was obtained when proteins of 380 and 155 kDa were combined. In contrast to the human regulatory proteins, the sand bass proteins require Ca2+ ions. K76COOH, an inhibitor of human factor I, inhibited the function of the 155-kDa but not of the 380 kDa-fraction. Thus it appears that the 155-kDa fraction functions as the C4b/C3b cleaving enzyme (I) and the 380-kDa material as its cofactor. Further purification of the 380-kDa fraction yielded a protein that by SDS-PAGE consisted of two noncovalently linked subunits of 110 and 42 kDa at a molecular ratio of 2:1. These two chains were antigenically distinct, and constitute domains of the same protein. The 110-kDa peptide binds C4b and not C3b but it fully expresses the cofactor function for the 155-kDa fraction on the cleavage of both C4b and C3b. Limited tryptic digestion of the 110-kDa domain demonstrated C4b binding activity in fragments of 34, 25, and 23 kDa. The activity of the 34-kDa fragment was the same as that of the undigested protein. Comparison of the amino acid composition of the barred sand bass cofactor and of human C4bp shows similar high content of cysteine and proline but not of tryptophan. It differs from human factor H in cysteine, serine, proline, and tryptophan. These studies indicate that regulatory proteins for the C4b and C3b C fragments may have appeared very early phylogenetically.     

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.     

Differences between the binding sites of the complement regulatory proteins DAF, CR1, and factor H on C3 convertases

Binding studies using purified decay-accelerating factor (DAF), CR1, and Factor H indicate that the primary interaction of DAF with C3 convertases is with the Bb or C2a subunits, whereas CR1 and Factor H interact primarily with the C3b or C4b subunits. The ability of soluble DAF, CR1, or Factor H to decay C3b,Bb bound to zymosan was inhibited by various concentrations of fluid-phase competitors (C3b, Bb, C3b,Bb, C3b,B, C4b, or C4b,C2a) in 0.1% NP-40 at 22 degrees C. The apparent association constants (appKa) for DAF were 0.045, 0.067, 0.91, 0.71, 0.00045, and 0.53 microM-1, respectively. The appKa for CR1 were 0.50, 0.0040, 1, 1, 1, and 1.1 microM-1, respectively. The appKa for Factor H were 4.3, 0.0005, 2.9, 6.3, 0.27, and 0.29 microM-1, respectively. Thus, C3b binds to DAF with a 10-fold lower affinity than to CR1 and a 100-fold lower affinity than to Factor H. The appKa of C3b,Bb for the three proteins were more similar: DAF (0.91 microM-1), CR1 (1 microM-1), and Factor H (2.9 microM-1). DAF binds to Bb with a 50% higher affinity than to C3b, and to C4b,C2a with a 1000-fold higher affinity than to C4b alone. In contrast, CR1 and Factor H bind almost equally well to the C3 convertases and to their noncatalytic subunits. The affinity of DAF for CVF,Bb was similar to its affinity for Bb alone, suggesting that DAF does not recognize conformational determinants unique to Bb in C3 convertases.     

Limited proteolysis of complement protein C3b by regulatory enzyme C3b inactivator: isolation and characterization of a biologically active fragment, C3d,g

Limited proteolysis of C3b by C3b inactivator (factor I) consists of a two-step reaction; rapid cleavage of C3b to yield a nicked C3b derivative, iC3b, and followed by slow cleavage of iC3b to yield two antigenically distinct fragments, C3c and C3d,g. Using a fluorescence-labeled C3b as a substrate for I, we have investigated in detail the optimal conditions for the sequential cleavages of C3b by I. The pH optimum for the first cleavage was markedly affected by the ionic strength of buffers. The cleavage was maximum at pH 6.0 under physiological ionic strength but at pH 8.5 under low ionic strength (such as 1.7 mS). The second cleavage was a slow reaction and occurred only under low ionic strength and within a narrow pH range around pH 6.0. One of the products of the second cleavage, C3d,g, was isolated and shown to be a single polypeptide chain of 41,000 daltons with pI 5.0. C3d,g had leucocytosis-inducing activity, like C3d-k, which is a C3d fragment released by the action of plasma kallikrein. Trypsin digestion of C3d,g produced two fragments of 30,000 and 10,000 daltons and the 10,000-dalton fragment retained the leucocytosis inducing activity.     

Ultrastructures and interactions of complement factors H and I.

The human complement regulatory protein, factor H, was examined by high resolution transmission electron microscopy. Results of electron microscopy confirm hydrodynamic analysis and indicate that factor H is a monomer of M(r) approximately 155,000. Factor H is an extended flexible molecule with a contour length of 495 A and a cross-sectional diameter of 34 A. Most images of factor H indicate that its polypeptide chain typically folds back on itself with the result that the average length of a factor H molecule is about half its contour length. Only one end of factor H associates with C3b. When bound to C3b, factor H still shows considerable conformational flexibility. Factor I is a bilobal protein of 130 A in length, and its two globular parts have maximal diameters of 54 and 49 A. The results establish that factor I is a two domain protein where the smaller subunit is a protease and the larger one is involved with binding C3b. Factor I binds C3b with a one-to-one stoichiometry in an ionic strength-dependent fashion. In the absence of sodium chloride an affinity constant of 5.7 x 10(5) M-1 was determined for factor I interaction with C3b. Whereas the Scatchard plot of factor I binding to C3b in the absence of factor H is linear, in the presence of factor H a curvilinear graph is obtained. The strong binding sites on C3b for factor I have an affinity at least 15-fold higher in the presence of factor H than in its absence. The results of both electron microscopy and binding studies were combined to compose a scheme envisioning how factors H and I cooperate for the processing of C3b.     

Use of time-resolved FRET to validate crystal structure of complement regulatory complex between C3b and factor H (N terminus)

Structural knowledge of interactions amongst the ～ 40 proteins of the human complement system, which is central to immune surveillance and homeostasis, is expanding due primarily to X‐ray diffraction of co‐crystallized proteins. Orthogonal evidence, in solution, for the physiological relevance of such co‐crystal structures is valuable since intermolecular affinities are generally weak‐to‐medium and inter‐domain mobility may be important. In this current work, Förster resonance energy transfer (FRET) was used to investigate the 10 μM K_D (210 kD) complex between the N‐terminal region of the soluble complement regulator, factor H (FH1‐4), and the key activation‐specific complement fragment, C3b. Using site‐directed mutagenesis, seven cysteines were introduced individually at potentially informative positions within the four CCP modules comprising FH1‐4, then used for fluorophore attachment. C3b possesses a thioester domain featuring an internal cycloglutamyl cysteine thioester; upon hydrolysis this yields a free thiol (Cys988) that was also fluorescently tagged. Labeled proteins were functionally active as cofactors for cleavage of C3b to iC3b except for FH1‐4(Q40C) where conjugation with the fluorophore likely abrogated interaction with the protease, factor I. Time‐resolved FRET measurements were undertaken to explore interactions between FH1‐4 and C3b in fluid phase and under near‐physiological conditions. These experiments confirmed that, as in the cocrystal structure, FH1‐4 binds to C3b with CCP module 1 furthest from, and CCP module 4 closest to, the thioester domain, placing subsequent modules of FH near to any surface to which C3b is attached. The data do not rule out flexibility of the thioester domain relative to the remainder of the complex.     

Functional properties of complement factor H-related proteins FHR-3 and FHR-4: binding to the C3d region of C3b and differential regulation by heparin

The human factor H-related proteins FHR-3 and FHR4 are members of a family of proteins related to the complement factor H. Here, we report that the two proteins bind to the C3d region of complement C3b. The apparent K(A) values for the interactions of FHR-3 and FHR-4 with C3b are 7.5 x 10(6) M(-1) and 2.9 x 10(6) M(-1), respectively. Binding studies performed with C3b-coated pneumococci confirmed the results obtained with the biosensor system. A C-terminal construct of factor H showed similar binding characteristics. The interaction of FHR-3, but not of FHR4, with opsonised pneumococci was inhibited by heparin.     

Targeting of complement to tumor cells by heteroconjugates composed of antibodies and of the complement component C3b

Tumor cells have adapted several strategies which permit them to grow in an immunologically hostile environment. The C system can potentially destroy these cells; however, its action needs to be specifically potentiated on the surface of the tumor cells. To this end, a heteroconjugate composed of a mouse mAb and of the human C3b C component has been generated by using the heterobifunctional reagent N-succinimidyl-3-(2-pyridyldithio)propionate. The two mAb which were used in this study are V1-10 and TIB219 which bind to the human and mouse transferrin receptors, respectively. The mAb-C3b conjugates were purified by gel filtration and were each composed of one mAb and one C3b. They bound to the human K562 and HL60 or mouse ALB1 cell lines and amplified the killing of these cells by C from 10 to 15% to 70 to 100%. Fresh normal human or mouse sera were used as a source of C. The mAb-C3b conjugates activated primarily the alternative pathway of C since only C3 and factor B but not C4 were cleaved in the sera. After disulfide-linking to the mAb, the C3b became highly resistant to inactivation by factors H and I, probably due to its reduced factor H binding capacity. On the other hand, the conjugated C3b bound factor B better than free C3b and produced more C3 convertases which expressed increased stability. These results suggest that mAb-C3b conjugates may serve as an effective tool for the specific activation of the cytolytic C system on selected cells. As such, they may be used in vitro or in vivo to target the autologous C to tumor cells or to lymphocytes and may promote tumor immunotherapy.     

Reconstitution of C5 convertase of the alternative complement pathway with isolated C3b dimer and factors B and D

C5 convertase of the alternative complement pathway is a trimolecular complex consisting of two molecules of C3b and one molecule of Bb. We previously proposed a model of the alternative pathway C5 convertase in which the second C3b molecule binds covalently to the first C3b molecule bearing Bb, and the C5 molecule binds to each C3b molecule of the covalently linked C3b dimer, resulting in its appropriate presentation to the catalytic site on Bb. In the present study, we purified the covalently linked C3b dimer and reconstituted the C5 convertase with the C3b dimer and factors B and D to obtain evidence in support of this model. An insoluble glucan, OMZ-176, was incubated with human serum to activate the alternative pathway and to allow formation of the alternative C5 convertase on the surface of the glucan, and the glucan bearing the C5 convertase was then solubilized by incubation with glucosidases. In this way, the covalently linked C3b dimer was obtained in solution without using a detergent. The C3b dimer was then separated from enzymes, C3b monomer, C3b oligomer, and other materials by chromatographies. SDS-PAGE analysis demonstrated that the purified C3b dimer had intact alpha'-chains. Alternative pathway C5 convertase was reconstituted when the isolated C3b dimer was incubated with factors B and D. The presence of P enhanced C5 convertase formation threefold. These results support the notions that the formation of the covalently linked C3b dimer is a general phenomenon associated with activation of the alternative pathway and that the C3b dimer acts as a part of the C5 convertase.     

Kinetic and thermodynamic study of the tetramerization equilibrium of phosphorylase b

The association equilibrium of phosphorylase b, induced by AMP and in the presence of Mg2+, has been shown to be a reversible process that follows second order and first order reversible rate laws in the direction of tetramerization and dimerization respectively, this fact being independent of temperature and of enzyme and AMP concentrations. Moreover, rate and equilibrium constants have been evaluated and their dependence on temperature and AMP concentration studied in this work. An important role that the existence of two classes of AMP binding sites per enzymatic subunit plays in the aggregation properties of the enzyme has also been emphasized. In the presence of 0.1 and 1 mM AMP (binding to the high affinity site), the values of the change in enthalpy, activation energy of dimerization and activation energy of tetramerization are: -36 kcal/mol, +36 kcal/mol, and 0 kcal/mol respectively. Binding of AMP to the low affinity site (10 mM AMP) yields significant changes in the self-association equilibrium, since the preceding parameters reach the following values: -18, +32, and +14 kcal/mol.     

Kinetic and thermodynamic control of ATP synthesis by sarcoplasmic reticulum adenosinetriphosphatase

Several experimental parameters, critical to the analysis of ATP synthesis by sarcoplasmic reticulum ATPase, were determined experimentally. 1) The phosphorylated enzyme intermediate obtained with acetylphosphate in the presence of a Ca2+ gradient was shown to be entirely ADP sensitive but quite stable in the absence of added ADP. On the contrary, the phosphoenzyme obtained with ATP is unstable due to the ADP formed during the phosphoryl transfer reaction. For this reason, addition of ADP to [32P]phosphoenzyme obtained with [32P]acetylphosphate provides the simplest conditions for kinetic studies on [gamma-32P]ATP synthesis. 2) The dissociation rate constant of newly synthesized ATP (in the reverse direction of the ATPase cycle) was measured experimentally and found to be 16 s-1. This value agrees well with the dissociation rate constant determined for adenyl-5'-yl imidodiphosphate bound to this enzyme. 3) ATP synthesis observed in the absence of a Ca2+ gradient was shown to be a kinetic overshoot due to ligand-induced perturbation of a limited number of partial reactions and occurring before equilibration of the entire system. Most of the ATP formed under these conditions was subsequently hydrolyzed as the overall equilibrium was reached. 4) Based on these and other (previously characterized) parameters, satisfactory simulations of single and multiple cycle ATP synthesis, in the presence and in the absence of a Ca2+ gradient, were obtained.     

Complement C3b/C3d and cell surface polyanions are recognized by overlapping binding sites on the most carboxyl-terminal domain of complement factor H

Factor H (FH) is a potent suppressor of the alternative pathway of C in plasma and when bound to sialic acid- or glycosaminoglycan-rich surfaces. Of the three interaction sites on FH for C3b, one interacts with the C3d part of C3b. In this study, we generated recombinant constructs of FH and FH-related proteins (FHR) to define the sites required for binding to C3d. In FH, the C3d-binding site was localized by surface plasmon resonance analysis to the most C-terminal short consensus repeat domain (SCR) 20. To identify amino acids of FH involved in binding to C3d and heparin, we compared the sequences of FH and FHRs and constructed a homology-based molecular model of SCR19-20 of FH. Subsequently, we created an SCR15-20 mutant with substitutions in five amino acids that were predicted to be involved in the binding interactions. These mutations reduced binding of the SCR15-20 construct to both C3b/C3d and heparin. Binding of the wild-type SCR15-20, but not the residual binding of the mutated SCR15-20, to C3d was inhibited by heparin. This indicates that the heparin- and C3d-binding sites are overlapping. Our results suggest that a region in the most C-terminal domain of FH is involved in target recognition by binding to C3b and surface polyanions. Mutations in this region, as recently reported in patients with familial hemolytic uremic syndrome, may lead to indiscriminatory C attack against self cells.     

Binding of fluid-phase complement components C3 and C3b to human lymphocytes.

It is known that a population of B-lymphocytes has receptors for the third component of complement, C3, and that these lymphocytes may be identified by their ability to form rosettes with sheep erythrocytes coated with covalently bound fragments of complement component C3. Human tonsil lymphocytes, enriched for B-cells, form rosettes with sheep erythrocytes coated with antibody and complement components C1, C4b and C3b (EAC143b cells). Fluid-phase C3 will inhibit rosette formation between EAC143b and human tonsil lymphocytes over the same concentration range as fluid-phase C3b. C3 is not cleaved to C3b during incubation with lymphocytes or with lymphocytes and EAC143b cells. Fluid-phase 125I-labelled C3 and 125I-labelled C3b bind to lymphocytes in a specific manner. The characteristics of binding of both radioiodinated C3 and radioiodinated C3b are very similar, but the binding oc C3 is again not a result of cleavage to C3b. Salicylhydroxamic acid does not inhibit binding of 125I-labelled C3 to tonsil lymphocytes at concentrations that completely inhibit binding of 125I-labelled C3 to EAC142 cells via the nascent binding site of C3b. It is concluded that C3 and C3b share a common feature involved in binding to lymphocytes bearing receptors for the third component of complement.     

Intracellular degradation of the complement C3b/C4b receptor in the absence of ligand

Human neutrophils (PMN) respond to various soluble stimuli by translocating intracellular complement C3b/C4b receptors (CR1) to the cell surface. Ligand-independent internalization of surface CR1 has been demonstrated previously, but the fate of total cellular CR1 during PMN stimulation has not been determined. In order to study the fate of CR1 during neutrophil activation, we have employed a unique approach for the quantitative analysis of intracellular antigens which allows simultaneous measurement of total cellular and surface membrane antigen pools. Stimulation of isolated PMN with N-formyl-Met-Leu-Phe or ionomycin resulted in a mean 7-fold increase in surface CR1 expression within 15 min. Total cellular CR1 decreased by as much as 45% within 15 min, with loss continuing for up to 1 h. Inclusion of NH4Cl during PMN stimulation inhibited the loss of total CR1 without affecting surface CR1 expression. Addition of phenylmethylsulfonyl fluoride inhibited loss of total CR1 and enhanced the stimulus-induced increases in surface CR1. These data suggest that intracellular degradation of CR1 occurs during stimulation of PMN and may involve proteolysis in an acidic intracellular compartment. Since our experiments were done with isolated PMN in the absence of serum and complement components, this degradation occurred in the absence of C3b, the ligand for CR1. To our knowledge, ligand-independent degradation of a cell surface receptor has not been previously detected.