Functional insights from the structure of the multifunctional C345C domain of C5 of complement

The complement protein C5 initiates assembly of the membrane attack complex. This remarkable process results in lysis of target cells and is fundamental to mammalian defense against infection. The 150-amino acid residue domain at the C terminus of C5 (C5-C345C) is pivotal to C5 function. It interacts with enzymes that convert C5 to C5b, the first step in the assembly of the membrane attack complex; it also binds to the membrane attack complex components C6 and C7 with high affinity. Here a recombinant version of this C5-C345C domain is shown to adopt the oligosaccharide/oligonucleotide binding fold, with two helices packed against a five-stranded beta-barrel. The structure is compared with those from the netrin-like module family that have a similar fold. Residues critical to the interaction with C5-convertase cluster on a mobile, hydrophobic inter-strand loop that protrudes from the open face of the beta-barrel. The opposite, helix-dominated face of C5-C345C carries a pair of exposed hydrophobic side chains adjacent to a striking negatively charged patch, consistent with affinity for positively charged factor I modules in C6 and C7. Modeling of homologous domains from complement proteins C3 and C4, which do not participate in membrane attack complex assembly, suggests that this provisionally identified C6/C7-interacting face is indeed specific to C5.     

Activation of C1

The first component of complement, C1, is a calcium-dependent complex of two loosely interacting subunits: C1q, responsible for the binding of activators to C1; C1r2-C1s2, which supports the autoactivation potential of C1, together with the proteolytic activity of activated C1- on its two substrates, C4 and C2. Isolated dimeric C1r2 is able to autoactivate through an intradimer cross-proteolysis; this capacity is lost when C1r2 is associated with two molecules of C1s inside the calcium-dependent C1r2-C1s2 subunit; this capacity is again observed in reconstituted C1. A model for reconstituted soluble C1 is proposed, based on electron microscopy, neutron diffraction, ultra-centrifugation, various biochemical findings, as well as functional properties of C1 or of its subcomponents. The flexible rod-like structure of C1r2-C1s2 is folded around two arms of C1q, with the catalytic domains of C1r and C1s inserted inside the cone defined by the C1q stalks. Activation of C1 which, in vivo, is controlled by C1 inhibitor, can be achieved by various activators, such as immune complexes; it appears to result from the suppression of a negative control and resides in a positive modulation of the intrinsic autocatalytic potential of C1r inside C1.     

Role of C5a-C5aR axis in the development of atherosclerosis

Complement component 5a (C5a) is a 74 amino acid glycoprotein and an important proinflammatory mediator that is cleaved enzymatically from its precursor, C5, on activation of the complement cascade. C5a is quickly metabolised by carboxypeptidases, forming the less-potent C5a desArg. C5a and C5a desArg interact with their receptors (C5aR and C5L2), which results in a number of effects which are essential to the immune response. C5a has a broad range of biological effects throughout the human body because the widespread expression of C5a receptors throughout the human organs enables C5a and C5a desArg to elicit a broad range of biological effects. Recently, accumulating evidence in humans and experimental animal models shows that the C5a-C5aR axis is involved in the development of atherosclerosis lesions. The absence or blockade of C5aRs greatly reduces the formation of atherosclerotic lesions or wire-injury-induced neointima formation in atherosclerosis-prone mice. Serum C5a level was related to the major adverse cardiovascular events in patients with advanced atherosclerosis and those with drug-eluting stent implantation. Thus, the C5a-C5aR axis may be a significant pathogenic driver of arteriosclerotic vascular disease, making C5a-C5aR inhibition an attractive therapeutic strategy.     

X-ray structure of the Ca2+-binding interaction domain of C1s. Insights into the assembly of the C1 complex of complement

C1, the complex that triggers the classical pathway of complement, is assembled from two modular proteases C1r and C1s and a recognition protein C1q. The N-terminal CUB1-EGF segments of C1r and C1s are key elements of the C1 architecture, because they mediate both Ca2+-dependent C1r-C1s association and interaction with C1q. The crystal structure of the interaction domain of C1s has been solved and refined to 1.5 A resolution. The structure reveals a head-to-tail homodimer involving interactions between the CUB1 module of one monomer and the epidermal growth factor (EGF) module of its counterpart. A Ca2+ ion is bound to each EGF module and stabilizes both the intra- and inter-monomer interfaces. Unexpectedly, a second Ca2+ ion is bound to the distal end of each CUB1 module, through six ligands contributed by Glu45, Asp53, Asp98, and two water molecules. These acidic residues and Tyr17 are conserved in approximately two-thirds of the CUB repertoire and define a novel, Ca2+-binding CUB module subset. The C1s structure was used to build a model of the C1r-C1s CUB1-EGF heterodimer, which in C1 connects C1r to C1s and mediates interaction with C1q. A structural model of the C1q/C1r/C1s interface is proposed, where the rod-like collagen triple helix of C1q is accommodated into a groove along the transversal axis of the C1r-C1s heterodimer.     

The purification and properties of the second component of guinea-pig complement.

A method has been developed for the purification to homogeneity of guinea-pig complement component C2. Contrary to previous reports, guinea-pig C2 is a single polypeptide chain with apparent mol.wt. of 102000, the same as human C2. It is cleaved by C1s to yield fragments C2a (apparent molwt. 74000) and C2b (apparent mol.wt. 34000). The amino acid composition and N-terminal sequences of these fragments are similar to those of human C2a and C2b. Human and guinea-pig C2 show more extensive sequence homology to Factor B than previously identified. The known homology around the sites of cleavage by C1s and Factor D has now been extended by a stretch of ten identical or conservatively substituted residues. Sequence homology has now been identified at the N-terminal of C2b and Factor Ba. The properties of the classical-pathway C3 convertases assembled from human C4b, C1s and human or guinea-pig C2 have been compared. The rates of cleavage of human and guinea-pig C2 by C1s (and therefore the rates of assembly of the C3 convertases) are similar. The rate of decay of the activity of the C3 convertase formed from guinea-pig C2 is 10-fold lower than for human C2. This greater stability reflects a higher affinity of guinea-pig C2a for human C4b. The presence of C2b is not necessary for C3 convertase activity.     

Covalent binding of C3b to C4b within the classical complement pathway C5 convertase. Determination of amino acid residues involved in ester linkage formation.

C5 convertase of the classical complement pathway is a protein complex consisting of C4b, C2a, and C3b. Within this complex C3b binds to C4b via an ester linkage. We now present evidence that the covalent C3b-binding site on human C4b is Ser at position 1217 of C4. We also show that formation of the covalently linked C4b.C3b complex occurs in the mouse complement system and that the C3b-binding site on mouse C4b is Ser at position 1213 which is homologous to Ser-1217 of human C4. Therefore, covalent binding of C3b to a single specific site on C4b within the classical pathway C5 convertase is likely a common phenomenon in the mammalian complement system. Specific noncovalent association of metastable C3b with C4b would occur first, leading to reaction of the thioester with a specific hydroxy group. This is supported by two lines of experimental evidence, one which shows that a mutant C4 that does not make a covalent linkage with C3b is still capable of forming C5 convertase and a second in which the C4b.C3b complex has been demonstrated by cross-linking erythrocytes bearing this C5 convertase.     

An indel within the C8 alpha subunit of human complement C8 mediates intracellular binding of C8 gamma and formation of C8 alpha-gamma

Human C8 is one of five complement components (C5b, C6, C7, C8, and C9) that interact to form the cytolytic membrane attack complex, or MAC. It is an oligomeric protein composed of three subunits (C8alpha, C8beta, C8gamma) that are products of different genes. In C8 from serum, these are arranged as a disulfide-linked C8alpha-gamma dimer that is noncovalently associated with C8beta. In this study, the site on C8alpha that mediates intracellular binding of C8gamma to form C8alpha-gamma was identified. From a comparative analysis of indels (insertions/deletions) in C8alpha and its structural homologues C8beta, C6, C7, and C9, it was determined that C8alpha contains a unique insertion (residues 159-175), which includes Cys(164) that forms the disulfide bond to C8gamma. Incorporation of this sequence into C8beta and coexpression of the resulting construct (iC8beta) with C8gamma produced iC8beta-gamma, an atypical disulfide-linked dimer. In related experiments, C8gamma was shown to bind noncovalently to mutant forms of C8alpha and iC8beta in which Cys(164)-->Gly(164) substitutions were made. In addition, C8gamma bound specifically to an immobilized synthetic peptide containing the mutant indel sequence. Together, these results indicate (a) intracellular binding of C8gamma to C8alpha is mediated principally by residues contained within the C8alpha indel, (b) binding is not strictly dependent on Cys(164), and (c) C8gamma must contain a complementary binding site for the C8alpha indel.     

Suppression of T lymphocyte functions by human C3 fragments. I. Inhibition of human T cell proliferative responses by a kallikrein cleavage fragment of human iC3b

Cleavage of human iC3b by kallikrein isolated from human plasma generates a fragment, C3d-K, which is capable of inhibiting mitogen-, antigen-, and alloantigen-induced T lymphocyte proliferation. Native C3, C3a, C3b, and C3c-K had no effect on lymphocyte proliferative responses. In addition to being a potent suppressor of mitogen- and antigen-induced proliferation, C3d-K is capable of inducing leukocytosis in both mice and rabbits. Intravenous injection of C3d-K, but not C3, C3a, C3b, or C3c-K, results in a twofold to threefold increase in the number of circulating leukocytes. Thus, C3d-K exhibits two apparently independent functions, namely suppression of T cell proliferation and leukocytosis. Cleavage of iC3b by kallikrein results in the production of only two fragments. The larger fragment, C3c-K, is 144,000 m.w. and has a chemical structure analogous to that of C3c obtained from the cleavage of C3 by trypsin or elastase. The smaller fragment, C3d-K, is 41,000 m.w. and contains the metastable binding site of C3. It is through this site located in the C3d region of the molecule that C3 attaches covalently to target cells. Analysis of the amino terminal region of C3d-K provided a sequence that fails to overlap with any sequence yet reported for other characterized C3 fragments, including C3d originally obtained from elastase digestion. A revised model of the C3 molecule is proposed, with locations of the C3e and C3d fragments assigned on the basis of chemical analyses.     

The effects of iodine and thiol-blocking reagents on complement component C2 and on the assembly of the classical-pathway C3 convertase

I2 can react with complement component C2 in a two-stage process. In the first stage, a form of C2 with enhanced haemolytic activity is produced. This form of C2 is cleaved to C2a and C2b by C1s at the same rate as native C2. The enhanced C2 haemolytic activity correlates with the ability to form a stable fluid-phase C3 convertase on addition of the C2 to C4b and C1s. It reflects an increased affinity for C4b of C2a formed from I2-treated C2, although the affinity for C4b of I2-treated C2 itself is not markedly increased. The specific activity of C3 convertase formed from I2-treated C2 is the same as that formed from native C2. The second stage of the reaction with I2, which is favoured at high pH or in the presence of excess I2, inactivates C2 on production of a species that cannot be cleaved by C1s. The presence of a single free thiol group in C2, which is the site of modification by I2, was confirmed by titration with p-chloromercuribenzoate, iodoacetamide and 5,5'-dithiobis-(2-nitrobenzoic acid). A single thiol group is also present in Factor B, and the cysteine residue, like that in C2, requires denaturation of the protein before reaction with iodoacetamide and 5,5'-dithiobis-(2-nitrobenzoic acid) but not p-chloro- mercuribenzoate .     

Structure and function of lysosomal phospholipase A2: identification of the catalytic triad and the role of cysteine residues

Lysosomal phospholipase A2 (LPLA2) is an acidic phospholipase that is highly expressed in alveolar macrophages and that may play a role in the catabolism of pulmonary surfactant. The primary structure found in LCAT is conserved in LPLA2, including three amino acid residues potentially required for catalytic activity and four cysteine residues. LPLA2 activity was measured in COS-7 cells transfected with c-myc-conjugated mouse LPLA2 (mLPLA2) or mutated LPLA2. Single alanine substitutions in the catalytic triad resulted in the elimination of LPLA2 activity. Four cysteine residues (C65, C89, C330, and C371), conserved between LPLA2 and LCAT, were replaced with alanine. Quadruple mutations at C65, C89, C330, and C371, double mutations at C65 and C89, and a single mutation at C65 or C89 resulted in the elimination of activity. Double mutations at C330 and C371 and a single mutation at C330 or C371 resulted in a partial reduction of activity. Thus, the presence of a disulfide bond between C330 and C371 is not required for LPLA2 activity. We propose that one disulfide bond between C65 and C89 and free cysteine residues at C330 and C371 and the triad, serine-198, aspartic acid-360, and histidine-392, are required for the full expression of mLPLA2 activity.     

Gene duplication of the seventh component of complement in rainbow trout

The seventh component of complement is a single-chain plasma glycoprotein that is involved in the cytolytic phase of complement activation through a sequence of polymerization reactions with other terminal components. We have previously isolated and characterized a C7 gene in rainbow trout (Oncorhynchus mykiss). Here, we report the cloning of a second trout C7 gene (C7-2). The deduced amino acid sequence of the C7-2 gene exhibits 43 and 50% identity with human C7 and trout C7-1, respectively. The structural motifs of trout C7-2 resemble those of mammalian C7 more than trout C7-1, and the cysteine backbone shows a high degree of conservation. C7-2 presents a different tissue expression profile from trout C7-1, which correlates with that of mammalian counterparts. Although duplication of complement genes is a common observation in teleost fish, this is the first report of two gene isotypes of a terminal membrane attack complex/perforin complement component in any organism.     

The human complement system: assembly of the classical pathway C3 convertase.

The assembly of the classical pathway C3 convertase in the fluid phase has been studied. The enzyme is assembled from C2 and C4 on cleavage of these proteins by C1s. Once assembled, the enzyme activity decays rapidly. Kinetic evidence has been obtained that this decay is even more rapid than previously suggested (kdecay is 2.0 min-1 at 37 degrees C). As a result, optimal C3 convertase activity is only observed with high C1s levels, which result in rapid rates of cleavage of C2 and increased rates of formation of the C3 convertase. Using high concentrations of C1s at lower temperatures (22 degrees C) in the presence of excess substrate we have demonstrated kinetically that the enzyme comprises an equimolar complex of C4b and cleaved C2. We have obtained direct evidence from gel-filtration experiments for the role of C2a as the catalytic subunit of the enzyme. C2b appears to mediate the interaction between C4 (or C4b) and C2 at pH 8.5 and at low ionic strength where the interactions can easily be detected. It may therefore be important in the assembly of the enzyme, though it is not involved in the catalytic activity. The decay of the C3 convertase reflects the release of C2a from the C4b x (C2b) x C2a complex, and the stabilizing effect of iodine on the C3 convertase is therefore apparently one of stabilizing the C4b-C2z interaction, which is otherwise weak. C1s is not a part of the C3 convertase enzyme.     

利用RAPD技术分析云南兰属部分种的种间关系

采用RAPD技术对云南兰属的11个种和3个变种中的39个样本进行了相似性分析。在相似系数0．58水平上,大花亚属的虎头兰、西藏虎头兰、长叶兰和碧玉兰聚为一支;建兰亚属的寒兰、墨兰、蜜蜂兰、蕙兰、春兰、豆瓣兰、春剑、莲瓣兰和送春聚为另一支,兔耳兰与大花亚属关系更近。春剑和莲瓣兰相似性更高,它们与春兰的关系较远,不支持送春作为蕙兰下的变种。这些结果可为开展兰属育种提供重要参考价值。     

Complete primary structure of human C4a anaphylatoxin

C4a anaphylatoxin is derived from the fourth component (C4) of the blood complement system. The C4 alpha-chain is selectively cleaved between positions 77 and 78 by the protease C1s, a subcomponent of C1, generating the fragments C4a and C4b. Human C4a was isolated directly from fresh serum after C1 of the classical pathway of complement was activated by heat-aggregated gamma-globulin. The C4a anaphylatoxin is a cationic polypeptide of Mr = 9000 composed of 77 residues and devoid of histidine, tryptophan, and carbohydrate. The primary structure of human C4a was deduced from sequence analysis of two cyanogen bromide fragments and of peptides obtained after chymotryptic digestion of the COOH-terminal cyanogen bromide fragment. The proposed sequence is: (formula, see text) Manual alignment of the linear structures of human C3a, C4a, and C5a, based primarily on the location of two Cys-Cys sequences in each indicate a 30% homology between C3a and C4a and a 36% homology between C5a and C4a. It was concluded from the sequence comparison that C3a, C4a, and C5a are a family of bioactive factors derived from precursor molecules that share a common genetic origin. Although the human anaphylatoxins share a partial structural identity and express similar biological activities, these factors ae immunologically distinct molecules having no antigenic determinants in common as judged by radioimmunoassay.     

Complement C3a enhances CXCL12 (SDF-1)-mediated chemotaxis of bone marrow hematopoietic cells independently of C3a receptor

Complement C3a promotes CXCL12-induced migration and engraftment of human and murine hemopoietic progenitor cells, suggesting a cross-influence between anaphylatoxin and chemokine axes. Here we have explored the underlying mechanism(s) of complement anaphylatoxin and chemokine cooperation. In addition to C3a, C3a-desArg and C4a but not C5a, are potent enhancers of CXCL12-induced chemotaxis of human and murine bone marrow (BM) stem/progenitor cells and B lineage cells. C3a enhancement of chemotaxis is chemokine specific because it is also observed for chemotaxis to CCL19 but not to CXCL13. The potentiating effect of C3a on CXCL12 is independent of the classical C3a receptor (C3aR). First, human BM CD34(+) and B lineage cells do not express C3aR by flow cytometry. Second, the competitive C3aR inhibitor SB290157 does not affect C3a-mediated enhancement of CXCL12-induced chemotaxis. Third, enhancement of chemotaxis of hemopoietic cells is also mediated by C3a-desArg, which does not bind to C3aR. Finally, C3a enhances CXCL12-induced chemotaxis of BM cells from C3aR knockout mice similar to BM cells from wild-type mice. Subsequent studies revealed that C3a increased the binding affinity of CXCL12 to human CXCR4(+)/C3aR(-), REH pro-B cells, which is compatible with a direct interaction between C3a and CXCL12. BM stromal cells were able to generate C3a, C3a-desArg, C4a, as well as CXCL12, suggesting that this pathway could function in vivo. Taken together, we demonstrate a C3a-CXCL12 interaction independent of the C3aR, which may provide a mechanism to modulate the function of CXCL12 in the BM microenvironment.     

利用RAPD 技术分析云南兰属部分种的种间关系

采用RAPD 技术对云南兰属的11 个种和3 个变种中的39 个样本进行了相似性分析。在相似系数0. 58 水平上, 大花亚属的虎头兰、西藏虎头兰、长叶兰和碧玉兰聚为一支; 建兰亚属的寒兰、墨兰、蜜蜂兰、蕙兰、春兰、豆瓣兰、春剑、莲瓣兰和送春聚为另一支, 兔耳兰与大花亚属关系更近。春剑和莲瓣兰相似性更高, 它们与春兰的关系较远, 不支持送春作为蕙兰下的变种。这些结果可为开展兰属育种提供重要参考价值。     

The binding of human complement component C4 to antibody-antigen aggregates.

The binding of human complement component C4 to antibody-antigen aggregates and the nature of the interaction have been investigated. When antibody-antigen aggregates with optimal C1 bound are incubated with C4, the C4 is rapidly cleaved to C4b, but only a small fraction (1-2%) is bound to the aggregates, the rest remaining in the fluid phase as inactive C4b. It has been found that C4b and th antibody form a very stable complex, due probably to the formation of a covalent bond. On reduction of the C4b-immunoglobulin G (IgG) complex, the beta and gamma chains, but not the alpha' chain, of C4b are released together with all the light chain, but only about half of the heavy chain of IgG. The reduced aggregates contain two main higher-molecular-weight complexes, one shown by the use of radioactive components to contain both IgG and C4b and probably therefore the alpha' chain of C4b and the heavy chain of IgG, and the other only C4b and probably an alpha' chain dimer. The aggregates with bound C1 and C4b show maximal C3 convertase activity, in the presence of excess C2, when the alpha'-H chain component is in relatively highest amounts. When C4 is incubated with C1s in the absence of aggregates, up to 15% of a C4b dimer is formed, which on reduction gives an alpha' chain complex, probably a dimer. The apparent covalent interaction between C4b and IgG and between C4b and other C4b molecules cannot be inhibited by iodoacetamide and hence cannot be catalysed by transglutaminase (factor XIII). The reaction is, however, inhibited by cadaverine and putrescine and 14C-labelled putrescine is incorporated into C4, again by a strong, probably covalent, bond. It is suggested that a reactive group, possibly an acyl group, is generated when C4 is activated by C1 and that this reactive group can react with IgG, with another C4 molecule, or with water.     

Macrophage C1q: characterization of a membrane form of C1q and of multimers of C1q subunits

It has been shown recently that C1q, a subcomponent of the first component of the classical complement pathway, is synthesized by macrophages and that endogenous C1q is detectable on the macrophage membrane. In this report, we demonstrate that membrane-associated C1q, which contains the A, B, and C chains of C1q, is structurally distinct from fluid-phase C1q in that the B chain of the membrane species is approximately 1000 m.w. less than its fluid-phase counterpart. By using biosynthetically ([3H]proline) labeled C1q from guinea pig peritoneal macrophages, we found that the membrane form of C1q is derived from already secreted C1q. The demonstration of a distinct membrane form of C1q supports earlier functional studies which implicated C1q as a membrane-associated molecule with receptor functions for those molecules which also interact with fluid-phase C1q, such as polyanions, immune complexes, and bacteria. Furthermore, we show that, in the vicinity of macrophages, C1q is very susceptible to oxidation manifested by the formation of disulfide bonds. By SDS-PAGE (nonreduced and reduced), we demonstrate the existence of disulfide-linked multimers (180,000 m.w., 360,000 m.w.) which are composed of the A, B, and C chains of C1q.     

Effects of zinc on factor I cofactor activity of C4b-binding protein and factor H

Complement inhibition is to a large extent achieved by proteolytic degradation of activated complement factors C3b and C4b by factor I (FI). This reaction requires a cofactor protein that binds C3b/C4b. We found that the cofactor activity of C4b-binding protein towards C4b/C3b and factor H towards C3b increase at micromolar concentrations of Zn(2+) and are abolished at 2 mM Zn(2+) and above. 65Zn(2+) bound to C3b and C4b molecules but not the cofactors or FI when they were immobilized in a native form on a nitrocellulose membrane. Zn(2+) binding constants for C3met (0.2 microM) and C4met (0.1 microM) were determined using fluorescent chelator. It appears that higher cofactor activity at low zinc concentrations is due to an increase of affinity between C4b/C3b and cofactor proteins as assessed by surface plasmon resonance. Inhibition of the reaction seen at higher concentrations is due to aggregation of C4b/C3b.