Characterization of the active sites in decay-accelerating factor.
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Decay-accelerating factor (DAF) is a complement regulator that dissociates autologous C3 convertases, which assemble on self cell surfaces. Its activity resides in the last three of its four complement control protein repeats (CCP2-4). Previous modeling on the nuclear magnetic resonance structure of CCP15-16 in the serum C3 convertase regulator factor H proposed a positively charged surface area on CCP2 extending into CCP3, and hydrophobic moieties between CCPs 2 and 3 as being primary convertase-interactive sites. To map the residues providing for the activity of DAF, we analyzed the functions of 31 primarily alanine substitution mutants based in part on this model. Replacing R69, R96, R100, and K127 in the positively charged CCP2-3 groove or hydrophobic F148 and L171 in CCP3 markedly impaired the function of DAF in both activation pathways. Significantly, mutations of K126 and F169 and of R206 and R212 in downstream CCP4 selectively reduced alternative pathway activity without affecting classical pathway activity. Rhesus macaque DAF has all the above human critical residues except for F169, which is an L, and its CCPs exhibited full activity against the human classical pathway C3 convertase. The recombinants whose function was preferentially impaired against the alternative pathway C3bBb compared with the classical pathway C4b2a were tested in classical pathway C5 convertase (C4b2a3b) assays. The effects on C4b2a and C4b2a3b were comparable, indicating that DAF functions similarly on the two enzymes. When CCP2-3 of DAF were oriented according to the crystal structure of CCP1-2 of membrane cofactor protein, the essential residues formed a contiguous region, suggesting a similar spatial relationship. (+info)
Expression and characterisation of the thrombospondin type I repeats of human properdin.
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Properdin, an upregulator of the alternative complement pathway, is central to deposition of the activated complement fragment C3b on the surfaces of the pathogens, which it achieves by preventing the dissociation of the Bb catalytic subunit from the inherently labile C3bBb complexes. It is also known to bind sulphated glycoconjugates, such as sulphatides. Properdin has an unusual structure formed by oligomerisation of a rod-like monomer into cyclic dimers, trimers and tetramers. The monomer (approximately 53 kDa) contains an N-terminal region of no known homology, followed by six non-identical repeats of 60 amino acids (based on exon/intron boundaries), called 'thrombospondin type I repeats' or TSR modules. We have expressed and purified the N-terminal region and each of the individual TSR repeats in Escherichia coli. Although the individual recombinant TSRs, after a denaturation-renaturation cycle, appeared to be correctly folded modules, as judged by the one-dimensional (1D)- and 2D-nuclear magnetic resonance spectra of TSR3, they did not show binding to either C3b or sulphatide. Polyclonal antibodies were raised against each TSR and were found to be module-specific. The anti-TSR5 polyclonal antibody was found to inhibit binding of native human properdin to solid-phase C3b, or sulphatides. It could also block properdin-dependent haemolysis of rabbit erythrocytes. These results are consistent with the view that the TSR5 contains the major site in properdin which is involved in both C3b and sulphatide binding. It also suggests that a co-operative intramolecular interaction between TSRs, as found in the native molecule, is required for TSR5 to bind either C3b or sulphatides. (+info)
Decay-accelerating factor (DAF), complement receptor 1 (CR1), and factor H dissociate the complement AP C3 convertase (C3bBb) via sites on the type A domain of Bb.
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The AP C3 convertase, C3bBb(Mg(2+)), is subject to irreversible dissociation (decay acceleration) by three proteins: DAF, CR1, and factor H. We have begun to map the factor B (fB) sites critical to these interactions. We generated a panel of fB mutations, focusing on the type A domain because it carries divalent cation and C3b-binding elements. C3bBb complexes were assembled with the mutants and subjected to decay acceleration. Two critical fB sites were identified with a structural model. 1) Several mutations centered at adjacent alpha helices 4 and 5 (Gln-335, Tyr-338, Ser-339, Asp-382) caused substantial resistance to DAF and CR1-mediated decay acceleration but not factor H. 2) Several mutations centered at the alpha 1 helix and adjoining loops (especially D254G) caused resistance to decay acceleration mediated by all three regulators and also increased C3b-binding affinity and C3bBb stability. In the simplest interpretation of these results, DAF and CR1 directly interact with C3bBb at alpha 4/5; factor H likely interacts at some other location, possibly on the C3b subunit. Mutations at the C3b.Bb interface interfere with the normal dissociation of C3b from Bb, whether it is spontaneous or promoted by DAF, CR1, or factor H. (+info)
C3 adsorbed to a polymer surface can form an initiating alternative pathway convertase.
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Contact between blood and a biomaterial surface induces an immediate complement-mediated inflammatory response. Under these conditions, the alternative pathway of complement is often initiated and amplified on the biomaterial surface. Adsorption of a protein such as C3 to a polymer surface induces conformational changes in the protein. Based on the expression on adsorbed C3 of conformational neoepitopes specific for bound C3 fragments, we have hypothesized that adsorbed C3 is able to bind factor B and form a functional C3,Bb convertase. Using a quartz crystal microbalance to monitor binding of proteins to a polymer surface, we have demonstrated that a functional C3-containing alternative pathway convertase can be formed, in particular, in the presence of properdin. These data indicate that adsorption of C3 induces conformational changes that turn C3 into a C3b-like molecule that is able to participate in the functioning of the alternative convertase, and they suggest a new mechanism for complement activation on a biomaterial surface. (+info)
Flavoxobin, a serine protease from Trimeresurus flavoviridis (habu snake) venom, independently cleaves Arg726-Ser727 of human C3 and acts as a novel, heterologous C3 convertase.
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We have recently shown that crude Trimeresurus flavoviridis (habu snake) venom has a strong capability for activating the human alternative complement system. To identify the active component, the crude venom was fractionated and purified by serial chromatography using Sephadex G-100, CM-cellulose C-52, diethylaminoethyl-Toyopearl 650M, and Butyl-Toyopearl, and the active fractions were evaluated by the C3a-releasing and soluble membrane attack complex-forming activities. Two peak fractions with the highest activities were detected after gel filtration and ion exchange chromatography, and the first fraction was purified to homogeneity. The homogeneous protein was examined for its N-terminal amino acid sequence by Edman degradation. The determined sequence of 25 amino acids completely coincided with that of a previously reported serine protease with coagulant activity, flavoxobin, purified from the same snake venom. To elucidate the molecular mechanism of the complement activation, the reactive products of the mixture of the purified human C3 and flavoxobin were examined by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. The digesting pattern revealed that flavoxobin cleaves the alpha chain of the C3 molecule into two fragments. The N-terminal amino acid sequences for the remnant fragments of C3 disclosed that flavoxobin severs the human C3 at the Arg726-Ser727 site to form C3b and C3a the way C3bBb, the human alternative C3 convertase, does. In conclusion, flavoxobin acts as a novel, heterologous C3 convertase that independently cleaves human C3 and kick-starts the complement cascade. (+info)
Mechanisms of effects of complement inhibition in murine collagen-induced arthritis.
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OBJECTIVE: To determine the mechanisms of amelioration of collagen-induced arthritis (CIA) in DBA/1J mice by inhibition of complement activation. METHODS: Mice received 2 intradermal injections of bovine type II collagen (CII), on days 0 and 21. From day 21 (immediately after the second injection of CII) through day 35, mice received intraperitoneal injections of either phosphate buffered saline (PBS), a monoclonal mouse antibody to murine C5 (anti-C5 antibody), or the C3 convertase inhibitor Crry-Ig. RESULTS: On days 30 and 32, the clinical disease activity score was lower in mice treated with anti-C5 antibody than in those treated with Crry-Ig. Histopathologic evidence of joint damage was 75% lower in the mice treated with anti-C5 antibody than in those treated with either PBS or Crry-Ig. Spleen cells from mice receiving either form of complement inhibition exhibited decreased CII-stimulated proliferation, whereas increased proliferative responses were exhibited by lymph node cells from mice treated with Crry-Ig. Treatment with anti-C5 antibody decreased production of IgG1 anticollagen antibody, while production of IgG2a antibody was inhibited by both complement inhibitory treatments. CII-stimulated spleen cells from anti-C5-treated mice produced lower levels of tumor necrosis factor alpha (TNFalpha) and interleukin-10 (IL-10) compared with those from mice treated with Crry-Ig. Lower steady-state messenger RNA (mRNA) levels for TNFalpha, interferon-gamma (IFNgamma), IL-18, and IL-6 were observed in the joints of anti-C5-treated mice, and for IFNgamma and IL-6 in mice receiving Crry-Ig, all in comparison with PBS-treated mice. However, mRNA levels for IL-1beta and TNFalpha were lower in the joints after treatment with anti-C5 compared with Crry-Ig. CONCLUSION: These results indicate that inhibition of complement in CIA leads to decreased production of IgG2a antibody and suppressed CII-induced spleen cell proliferation. The greater inhibitory effects on CIA of anti-C5 antibody in comparison with Crry-Ig may be attributable primarily to decreased levels of IL-1beta and TNFalpha mRNA in the joints. (+info)
Solution structure of a functionally active fragment of decay-accelerating factor.
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The second and third modules of human decay accelerating factor (DAF) are necessary and sufficient to accelerate decay of the classical pathway (CP) convertase of complement. No structure of a mammalian protein with decay-accelerating activity has been available to date. We therefore determined the solution structure of DAF modules 2 and 3 (DAF approximately 2,3). Structure-guided analysis of 24 mutants identified likely contact points between DAF and the CP convertase. Three (R96, R69, and a residue in the vicinity of L171) lie on DAF approximately 2,3's concave face. A fourth, consisting of K127 and nearby R100, is on the opposite face. Regions of module 3 remote from the semiflexible 2-3 interface seem not to be involved in binding to the CP convertase. DAF thus seems to occupy a groove on the CP convertase such that both faces of DAF close to the 2-3 junction (including a positively charged region that encircles the protein at this point) interact simultaneously. Alternative pathway convertase interactions with DAF require additional regions of CCP 3 lying away from the 2-3 interface, consistent with the established additional requirement of module 4 for alternative pathway regulation. (+info)
Formation of high affinity C5 convertase of the classical pathway of complement.
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C3/C5 convertase is a serine protease that cleaves C3 and C5. In the present study we examined the C5 cleaving properties of classical pathway C3/C5 convertase either bound to the surface of sheep erythrocytes or in its free soluble form. Kinetic parameters revealed that the soluble form of the enzyme (C4b,C2a) cleaved C5 at a catalytic rate similar to that of the surface-bound form (EAC1,C4b,C2a). However, both forms of the enzyme exhibited a poor affinity for the substrate, C5, as indicated by a high Km (6-9 microM). Increasing the density of C4b on the cell surface from 8,000 to 172,000 C4b/cell did not influence the Km. Very high affinity C5 convertases were generated only when the low affinity C3/C5 convertases (EAC1,C4b,C2a) were allowed to deposit C3b by cleaving native C3. These C3b-containing C3/C5 convertases exhibited Km (0.0051 microM) well below the normal concentration of C5 in blood (0.37 microM). The data suggest that C3/C5 convertase assembled with either monomeric C4b or C4b-C4b complexes are inefficient in capturing C5 but cleave C3 opsonizing the cell surface with C3b for phagocytosis. Deposition of C3b converts the enzymes to high affinity C5 convertases, which cleave C5 in blood at catalytic rates approaching Vmax, thereby switching from C3 to C5 cleavage. Comparison of the kinetic parameters with those of the alternative pathway convertase indicates that the 6-9-fold greater catalytic rate of the classical pathway C5 convertase may compensate for the fewer numbers of C5 convertase sites generated upon activation of this pathway. (+info)