Ultrastructure of C4b-binding protein fragments formed by limited proteolysis using chymotrypsin

C4b-binding protein is a regulator of the classical pathway of the complement system, acting as a cofactor to the serine protease factor I in the degradation of C4b. Its molecular weight is approximately 570,000 and it is composed of multiple, disulfide-linked 70-kDa subunits. Visualized by electron microscopy (Dahlb?ck, B., Smith, C. A., and Muller-Eberhard, H. J. (1983) Proc. Natl. Acad. Sci. U. S. A. 80, 3641-3645), it has an unusual spider-like structure with multiple thin (30 A), elongated (330 A) tentacles. The number of tentacles was estimated to be seven. Limited proteolysis by chymotrypsin produces fragments of approximately 50- and 160-kDa, the latter composed of multiple, disulfide-linked, 25-kDa polypeptides. We now have isolated the undenatured C4b-binding protein fragments formed by treatment of the protein with chymotrypsin and have visualized them by electron microscopy. The 160-kDa fragment comprises the central portion of the C4b-binding protein, which appears as a ringlike structure with an inner diameter of 13 A and an outer diameter of 60 A and having attached an approximately 40-A long piece of each tentacle. The liberated 50-kDa fragment constitutes the major part (290-A long) of the tentacles. Chymotrypsin digestion of C4b-binding protein was also monitored as a function of time by polyacrylamide gel electrophoresis and the number of subunits cleaved was found to be seven, supporting our previous ultrastructural data which suggested that C4b-binding protein contains seven identical tentacle-like subunits.     

Purification of human C4b-binding protein and formation of its complex with vitamin K-dependent protein S.

C4b-binding protein was purified from human plasma in high yield by a simple procedure involving barium citrate adsorption and two subsequent chromatographic steps. Approx. 80% of plasma C4b-binding protein was adsorbed on the barium citrate, presumably because of its complex-formation with vitamin K-dependent protein S. The purified C4b-binding protein had a molecular weight of 570 000, as determined by ultracentrifugation, and was composed of about eight subunits (Mr approx. 70 000). Uncomplexed plasma C4b-binding protein was purified from the supernatant after barium citrate adsorption. On sodium dodecyl sulphate/polyacrylamide-gel electrophoresis in non-reducing conditions and on agarose-gel electrophoresis it appeared as a doublet, indicating two forms differing slightly from each other in molecular weight and net charge. The protein band with the higher molecular weight in the doublet corresponded to the C4b-binding protein purified from the barium citrate eluate. Complex-formation between protein S and C4b-binding protein was studied in plasma, and in a system with purified components, by an agarose-gel electrophoresis technique. Protein S was found to form a 1:1 complex with the higher-molecular-weight form of C4b-binding protein, whereas the lower-molecular-weight form of C4b-binding protein did not bind protein S. The KD for the C4b-binding protein-protein S interaction in a system with purified components was approx. 0.9 X 10(-7) M. Rates of association and dissociation at 37 degrees C were low, namely about 1 X 10(3) M-1 . S-1 and 1.8 X 10(-4)-4.5 X 10(-4) S-1 respectively. In human plasma free protein S and free higher-molecular-weight C4b-binding protein were in equilibrium with the C4b-binding protein-protein S complex. Approx. 40% of both proteins existed as free proteins. From equilibrium data in plasma a KD of about 0.7 X 10(-7) M was calculated for the C4b-binding protein-protein S interaction.     

Evidence that C4b-binding protein is an acute phase protein

C4b-binding protein is a regulatory factor for both complement and coagulation systems. We found that a human hepatoma cell line, Hep G2, was capable of synthesizing C4b-binding protein and that the secretion of C4b-binding protein was enhanced by interleukin-6 and tumor necrosis factor, which are known to be modulators of acute phase proteins. In addition, the plasma content of C4b-binding protein was found to increase in patients of acute pneumonia. These results suggest that C4b-binding protein is an acute phase protein.     

Molecular cloning and characterization of the cDNA coding for C4b-binding protein, a regulatory protein of the classical pathway of the human complement system.

By using synthetic oligonucleotides as probes, plasmid clones containing portions of cDNA coding for human C4b-binding protein were isolated from a liver cDNA library. The entire amino acid sequence of the C4b-binding protein can be predicted from this study of the cloned cDNA when allied to a previous sequence study at the protein level [Chung, Gagnon & Reid (1985) Mol. Immunol. 22, 427-435], in which over 55% of the amino acid sequence, including the N-terminal 62 residues, was obtained. The plasmid clones isolated allowed the unambiguous determination of 1717 nucleotides of cDNA sequence between the codon for the 32nd amino acid in the sequence of C4b-binding protein and the 164th nucleotide in the 3' non-translated region. The sequence studies show that the secreted form of C4b-binding protein, found in plasma, is composed of chains of apparent Mr 70 000 that contains 549 amino acid residues. Examination of the protein and cDNA sequence results show that there are at least two polymorphic sites in the molecule. One is at position 44, which can be glutamine or threonine, and the other is at position 309, which can be tyrosine or histidine. Northern-blot analysis indicated that the mRNA for C4b-binding protein is approx. 2.5 kilobases long. The N-terminal 491 amino acids of C4b-binding protein can be divided into eight internal homologous regions, each approx. 60 amino acids long, which can be aligned by the presence in each region of four half-cystine, one tryptophan and several other conserved residues. These regions in C4b-binding protein are homologous with the three internal-homology regions that have been reported to be present within the Ba region of the complement enzyme factor B and also to the internal-homology regions found in the non-complement beta 2-glycoprotein I.     

Inhibition of cofactor activity of protein S by a complex of protein S and C4b-binding protein. Evidence for inactive ternary complex formation between protein S, C4b-binding protein, and activated protein C

To elucidate the mechanism by which C4b-binding protein inhibits the cofactor activity of protein S for anticoagulant-activated protein C, the interactions between protein S, activated protein C, and C4b-binding protein were studied using solid-phase enzyme immunoassays. Both activated protein C and C4b-binding protein bound to protein S fixed to microplate wells. C4b-binding protein did not inhibit the binding of activated protein C to protein S, nor did activated protein C inhibit the binding of C4b-binding protein to protein S. Activated protein C bound to a protein S-C4b-binding protein complex which was cross-linked with a chemical reagent as well as it bound to free protein S. Protein S-C4b-binding protein complex competitively inhibited activated protein C-binding to free protein S and also the cofactor activity of free protein S. Immunoblotting analysis showed ternary complex formation with protein S, C4b-binding protein, and activated protein C in the liquid phase by treatment with the cross-linking reagent. These findings suggest that the protein S-C4b-binding protein complex inhibits the cofactor activity of free protein S probably by inhibition of functionally active protein S-activated protein C complex formation by the apparent competitive formation of an inactive ternary complex with protein S, C4b-binding protein, and activated protein C.     

Structural investigation of C4b-binding protein by molecular modeling: Localization of putative binding sites

C4b-binding protein (C4BP) contributes to the regulation of the classical pathway of the complement system and plays an important role in blood coagulation. The main human C4BP isoform is composed of one β-chain and seven α-chains essentially built from three and eight complement control protein (CCP) modules, respectively, followed by a nonrepeat carboxy-terminal region involved in polymerization of the chains. C4BP is known to interact with heparin, C4b, complement factor I, serum amyloid P component, streptococcal Arp and Sir proteins, and factor VIII/VIIIa via its α-chains and with protein S through its β-chain. The principal aim of the present study was to localize regions of C4BP involved in the interaction with C4b, Arp, and heparin. For this purpose, a computer model of the 8 CCP modules of C4BP α-chain was constructed, taking into account data from previous electron microscopy (EM) studies. This structure was investigated in the context of known and/or new experimental data. Analysis of the α-chain model, together with monoclonal antibody studies and heparin binding experiments, suggests that a patch of positively charged residues, at the interface between the first and second CCP modules, plays an important role in the interaction between C4BP and C4b/Arp/Sir/heparin. Putative binding sites, secondary-structure prediction for the central core, and an overall reevaluation of the size of the C4BP molecule are also presented. An understanding of these intermolecular interactions should contribute to the rational design of potential therapeutic agents aiming at interfering specifically some of these protein–protein interactions. Proteins 31:391–405, 1998. © 1998 Wiley-Liss, Inc.     

Size and shape of bovine interphotoreceptor retinoid-binding protein by electron microscopy and hydrodynamic analysis

Individual molecules of interphotoreceptor retinoid-binding protein (IRBP), a protein likely to be important in the visual cycle, were visualized by means of electron microscopy. IRBP was coated with a very thin layer of tungsten and photographed by dark-field imaging. IRBP is seen to be a flexible, elongated molecule about 24 nm in length by 3-4 nm in width (statistical modes). These dimensions agree very well with those calculated from the frictional ratio obtained from sedimentation data. Approximately half of these rod-shaped IRBP molecules are straight, and half are bent in the middle, usually with an angle of 60-90 degrees between the two arms. A representation of IRBP as a bendable string of beads yields calculations of dimensions and of hydrodynamic parameters consistent with the electron microscopic and sedimentation data; the sedimentation coefficients derived from this representation are nearly insensitive to molecular bending. When IRBP is bound to saturating amounts of its endogenous ligands, all-trans- or 11-cis-retinol, its sedimentation behavior is unchanged, and the same types of particles are visualized by electron microscopy as with the free protein; however, a greater proportion of the molecules are bent. Deglycosylation of IRBP (with peptide:N-glycosidase F) results in a somewhat smaller molecule that retains its rod-like shape, as shown by gel filtration and sedimentation data. The results indicate that IRBP is an elongated molecule and suggest that a structural change may occur upon ligand binding.     

Characterization of a synthetic peptide that inhibits the interaction between protein S and C4b-binding protein

Protein S is unique among the vitamin K-dependent proteins found in blood plasma because it is a cofactor rather than a zymogen of a serine protease. Instead of a trypsin-like domain, protein S contains a domain that has sequence homology with steroid binding proteins. In order to understand the function of this structural domain, peptides have been synthesized with amino acid sequences that are homologous between human protein S and rat androgen binding protein. Two peptides, corresponding to amino acids 400-407 (PINPRLDG) and 605-614 (GVQLDLDEAI) of the protein S sequence have been tested for their effects on protein S function. Neither peptide altered the clotting of bovine or human plasma. The peptide GVQLDLDEAI enhanced the anticoagulant activity of human-activated protein C in human plasma while the peptide PINPRLDG had no effect. The peptide GVQLDLDEAI was observed to inhibit the binding of protein S to C4b-binding protein in plasma, resulting in increased concentrations of free protein S. GVQLDLDEAI was also observed to enhance the disassociation of the protein S.C4b-binding protein complex when purified complex was used. Finally, C4b-binding protein was observed to bind to GVQLDLDEAI. These results suggest that the carboxyl-terminal region of protein S, which contains the sequence GVQLDLDEAI, is involved in the interaction between protein S and C4b-binding protein.     

Interaction with C4b-binding protein contributes to nontypeable Haemophilus influenzae serum resistance

Complement evasion by various mechanisms is important for microbial virulence and survival in the host. One strategy used by some pathogenic bacteria is to bind the complement inhibitor of the classical pathway, C4b-binding protein (C4BP). In this study, we have identified a novel interaction between nontypeable Haemophilus influenzae (NTHi) and C4BP, whereas the majority of the typeable H. influenzae (a-f) tested showed no binding. One of the clinical isolates, NTHi 506, displayed a particularly high binding of C4BP and was used for detailed analysis of the interaction. Importantly, a low C4BP-binding isolate (NTHi 69) showed an increased deposition of C3b followed by reduced survival as compared with NTHi 506 when exposed to normal human serum. The main isoform of C4BP contains seven identical alpha-chains and one beta-chain linked together with disulfide bridges. Each alpha-chain is composed of eight complement control protein (CCP) modules and we have found that the NTHi 506 strain did not interact with rC4BP lacking CCP2 or CCP7 showing that these two CCPs are important for the binding. Importantly, C4BP bound to the surface of H. influenzae retained its cofactor activity as determined by analysis of C3b and C4b degradation. Taken together, NTHi interferes with the classical complement activation pathway by binding to C4BP.     

The properties of Bacillus cereus hemolysin II pores depend on environmental conditions

Hemolysin II (HlyII), one of several cytolytic proteins encoded by the opportunistic human pathogen Bacillus cereus, is a member of the family of oligomeric beta-barrel pore-forming toxins. This work has studied the pore-forming properties of HlyII using a number of biochemical and biophysical approaches. According to electron microscopy, HlyII protein interacts with liposomes to form ordered heptamer-like macromolecular assemblies with an inner pore diameter of 1.5-2 nm and an outer diameter of 6-8 nm. This is consistent with inner pore diameter obtained from osmotic protection assay. According to the 3D model obtained, seven HlyII monomers might form a pore, the outer size of which has been estimated to be slightly larger than by the other method, with an inner diameter changing from 1 to 4 nm along the channel length. The hemolysis rate has been found to be temperature-dependent, with an explicit lag at lower temperatures. Temperature jump experiments have indicated the pore structures formed at 37 degrees C and 4 degrees C to be different. The channels formed by HlyII are anion-selective in lipid bilayers and show a rising conductance as the salt concentration increases. The results presented show for the first time that at high salt concentration HlyII pores demonstrate voltage-induced gating observed at low negative potentials. Taken together we have found that the membrane-binding properties of hemolysin II as well as the properties of its pores strongly depend on environmental conditions. The study of the properties together with structural modeling allows a better understanding of channel functioning.     

Role of CCP2 of the C4b-binding protein beta-chain in protein S binding evaluated by mutagenesis and monoclonal antibodies.

Complement regulator C4b-binding protein (C4BP) and the anticoagulant vitamin K-dependent protein S form a high affinity complex in human plasma. C4BP is composed of seven alpha-chains and a unique beta-chain, each chain comprising repeating complement control protein (CCP) modules. The binding site for protein S mainly involves the first of the three beta-chain CCPs (CCP1). However, recently it has been suggested that CCP2 of the beta-chain also contributes to the binding of protein S. To elucidate the structural background for the involvement of CCP2 in the protein S binding, several recombinant beta-chain CCP1-2 variants having mutations in CCP2 were expressed and tested for protein S binding. Mutations were chosen based on analysis of a homology model of the beta-chain and included R60A/R101A, D66A, L105A, F114A/I116A and H108A. All mutant proteins bound equally well as recombinant wild type to protein S. Several monoclonal antibodies against the beta-chain CCP2 were raised and their influence on protein S binding characterized. Taken together, the results suggest that the role of CCP2 in protein S binding is to orient and stabilize CCP1 rather than to be directly part of the binding site.     

The protein S-binding site localized to the central core of C4b-binding protein

Human C4b-binding protein (C4BP) is a regulator of the classical pathway of the complement system. It appears in two forms in plasma, as free protein and in a noncovalent complex with the vitamin K-dependent coagulation protein, protein S. In the electron microscope C4BP has a spider-like structure with a central core and seven extended tentacles, each of which has a binding site for C4b, although the protein S-binding site has not been unequivocally pinpointed. C4BP was subjected to chymotrypsin digestion which yielded two major fragments, one of 160 kDa representing the central core, and one of 48 kDa representing the cleaved-off tentacles. We have now localized the protein S-binding site to the 160-kDa central core fragment. Using immunoblotting with a panel of polyclonal antisera, the isolated central core was shown to be completely devoid of 48-kDa fragments. The protein S-binding site was susceptible to proteolysis by chymotrypsin, but was protected by a molar excess of protein S included during the proteolysis. The 160-kDa central core fragment consisted of identical, disulfide-linked 25-kDa peptides and a proper disulfide bond arrangement was crucial to protein S binding. Using a direct binding assay it was shown that the isolated central core had the same affinity for protein S as intact C4BP.     

Structural and functional studies on C4b-binding protein,a regulatory component of the human complement system

The binding and cofactor activities of C4b-binding protein were examined before and after limited proteolysis by pepsin, trypsin and chymotrypsin. The major fragments generated were characterized by amino acid sequencing, thus establishing the precise points of limited proteolysis. These studies allow a tentative assignment of the cofactor activity site to the residues 177-322 of the 549 amino acid long chain of C4b-binding protein but indicated that residues in the region 332-395 are important in the binding activity.     

A short consensus repeat-containing complement regulatory protein of lamprey that participates in cleavage of lamprey complement 3

The prototype of the short consensus repeat (SCR)-containing C regulatory protein is of interest in view of its evolutionary significance with regard to the origin of the C regulatory system. Lamprey is an agnathan fish that belongs to the lowest class of vertebrates. Because it does not possess lymphocytes, it lacks Ig and consequently the classical C pathway. We identified an SCR-containing C regulatory protein from the lamprey. The primary structure predicted from the cDNA sequence showed that this is a secretary protein consisting of eight SCRs. This framework is similar to the alpha-chain of C4b-binding protein (C4bp). SCR2 and -3 of human C4bp are essential for C4b inactivation, and this region is fairly well conserved in the lamprey protein. However, the other SCRs of this protein are similar to those of other human C regulatory proteins. The lamprey protein binds to the previously reported lamprey C3b/C3bi deposited on yeast and cleaves lamprey C3b-like C3 together with a putative serum protease. The scheme resembles the C regulatory system of mammals, where factor I and its cofactor inactivate C3b. Unlike human cofactors, the lamprey protein requires divalent cations for C3b-like C3 cleavage. Its artificial membrane-anchored form protects host cells from lamprey C attack via the lectin pathway. Thus, the target of this protein appears to be C3b and/or its family. We named this protein Lacrep, the lamprey C regulatory protein. Lacrep is a member of SCR-containing C regulators, the first of its kind identified in the lowest vertebrates.     

Further identification of human plasma glycoproteins interacting with the galactose-specific lectin Jacalin

In this report we show that Jacalin binds the heme-binding protein hemopexin and the C4b-binding protein sgp120 in human plasma. The interaction of Jacalin with hemopexin confirms that a single O-linked oligosaccharide is sufficient to mediate binding of a protein to this lectin. Retention of sgp120 by immobilized Jacalin demonstrated that this protein was O-glycosylated and, therefore, clearly different from another C4b-binding protein, the complement protein C2 which is physicochemically similar but exclusively N-glycosylated. In addition, Jacalin was also shown to bind several proteolytic enzymes which remain to be identified.     

Binding site for vitamin K-dependent protein S on complement C4b-binding protein

Half of the protein S in plasma is present as a complex with a C4b-binding protein (C4bp), a complement component (Mr 570,000). In this study, the protein S-binding site on C4bp was examined by using monoclonal anti-C4bp-IgGs. C4bp was cleaved by chymotryptic digestion into seven NH2-terminal arm fragments (Mr 48,000) and a COOH-terminal core fragment (Mr 160,000). The COOH-terminal fragment inhibited the cofactor activity of protein S and its binding to C4bp in a dose-dependent manner. A monoclonal anti-C4bp-IgG (MFbp16), which binds to the COOH-terminal fragment, inhibited the binding of protein S to C4bp. The chymotryptic digest of the reduced and carboxymethylated COOH-terminal fragment was subjected to MFbp16-Sepharose 4B column affinity chromatography, and a peptide of Mr 2,500 was obtained. Protein S bound to the Mr 2,500 peptide, and this binding was inhibited by C4bp in a dose-dependent manner. The sequence of this peptide corresponded to Ser447-Tyr467 near the COOH terminus of the C4bp subunit. MFbp16, which bound to Mr 570,000 C4bp (C4bp-high), did not bind to Mr 510,000 C4bp (C4bp-low) in human plasma that does not form a complex with protein S. This suggests that C4bp-low lacks the protein S-binding site present in the COOH-terminal region of C4bp-high. Since C4bp-low also dissociates into identical subunits when reduced, the interchain disulfide bond region that links the seven subunits of C4bp appears to be closer to the NH2-terminal end than the protein S-binding site.     

Novel subunit in C4b-binding protein required for protein S binding

C4b-binding protein (C4BP) is a multimeric protein with regulatory functions in the complement system. It also interacts with vitamin K-dependent protein S, which is involved in the regulation of the coagulation system. It has been demonstrated that C4BP consists of seven disulfide-linked, identical 70-kDa subunits, which are arranged to give the molecule a spider-like structure. We now have evidence for the presence of a new subunit in C4BP. On sodium dodecyl sulfate-poly-acrylamide gel electrophoresis it appears as a weakly stainable band with a molecular weight of approximately 45,000. The subunit was isolated by gel filtration in 6 M guanidine hydrochloride of reduced and carboxymethylated C4BP. Its amino-terminal sequence is distinct from previously known protein sequences. The stoichiometry of 45- to 70-kDa subunits was estimated to be 1:9, indicating the presence of one 45-kDa subunit per C4BP molecule. The new subunit was demonstrated to be a disulfide-linked component of the central core of C4BP. It was sensitive to proteolysis by chymotrypsin, and when cleaved the protein S binding ability of C4BP was lost. With protein S bound to C4BP, the 45-kDa subunit was protected from degradation by chymotrypsin, and the protein S binding site remained intact. These data suggest that the new subunit is directly involved in protein S binding.     

The complement regulator C4b-binding protein (C4BP) interacts with both the C4c and C4dg subfragments of the parent C4b ligand: evidence for synergy in C4BP subsite binding

C4b-binding protein (C4BP) is a multimeric serum protein that is a potent regulator of the classical and lectin complement pathways. The binding site for C4b has been localized to complement control protein (CCP) domains 1-3 of the C4BP alpha-chain and, in particular, to a cluster of positively charged amino acids predicted to be at the interface between CCP 1 and CCP 2. To determine the regions of C4b contributing to C4BP binding, we have examined via surface plasmon resonance technology the binding of the C4c and C4dg subfragments of C4b to C4BP. At half-physiologic ionic strength, specific and saturable binding was observed for both C4c and C4dg. C4c exhibited much greater ionic strength sensitivity in its binding than did C4dg. Analysis of the effect on binding of the subfragments to various C4b-binding-defective C4BP mutants, together with cross-competition experiments, suggests that the subsites in C4BP for C4c and C4dg are adjacent, but distinct. Additionally, we observed synergy in subsite filling such that the presence of C4dg enhanced the extent of C4c binding over its basal level, and vice versa. The enhanced binding of C4c in the presence of C4dg was not due to an increase in affinity but rather reflected a 2-3-fold increase in the number of sites capable of binding C4c. This suggests the existence of a conformational equilibrium between high- and low-affinity states in the C4c binding subsite within each C4BP subunit, an equilibrium which is shifted in favor of the high-affinity state by the filling of the C4dg subsite.     

The properties of Bacillus cereus hemolysin II pores depend on environmental conditions

Hemolysin II (HlyII), one of several cytolytic proteins encoded by the opportunistic human pathogen Bacillus cereus, is a member of the family of oligomeric β-barrel pore-forming toxins. This work has studied the pore-forming properties of HlyII using a number of biochemical and biophysical approaches. According to electron microscopy, HlyII protein interacts with liposomes to form ordered heptamer-like macromolecular assemblies with an inner pore diameter of 1.5-2 nm and an outer diameter of 6-8 nm. This is consistent with inner pore diameter obtained from osmotic protection assay. According to the 3D model obtained, seven HlyII monomers might form a pore, the outer size of which has been estimated to be slightly larger than by the other method, with an inner diameter changing from 1 to 4 nm along the channel length. The hemolysis rate has been found to be temperature-dependent, with an explicit lag at lower temperatures. Temperature jump experiments have indicated the pore structures formed at 37 °C and 4 °C to be different. The channels formed by HlyII are anion-selective in lipid bilayers and show a rising conductance as the salt concentration increases. The results presented show for the first time that at high salt concentration HlyII pores demonstrate voltage-induced gating observed at low negative potentials. Taken together we have found that the membrane-binding properties of hemolysin II as well as the properties of its pores strongly depend on environmental conditions. The study of the properties together with structural modeling allows a better understanding of channel functioning.     

Molecular modeling of the domain structure of C9 of human complement by neutron and X-ray solution scattering.

C9 is the most abundant component of the membrane attack complex of the complement system of immune defense. This is a typical mosaic protein with thrombospondin (TSR) and low density lipoprotein receptor (LDLr) domains at its N-terminus and an epidermal growth factor-like (EGF) domain at its C-terminus. Between these lies a perforin-like sequence. In order to define the arrangement in solution of these four moieties in C9, high-flux neutron and synchrotron X-ray solution scattering studies were carried out. The neutron radius of gyration RG at infinite contrast is 3.33 nm, and its cross-sectional RG (RXS) is 1.66 nm. Similar values were obtained by synchrotron X-ray scattering after allowance for radiation effects. Stuhrmann analyses showed that the neutron radial inhomogeneity of scattering density alpha is 35 X 10(-5) from the RG data and 16 X 10(-5) from the RXS data. These values are typical for soluble glycoproteins and show no evidence for the existence of any large hydrophobic surface patches on free C9 that might form contacts with lipids. Indirect transformation of the neutron and X-ray scattering curves into real space showed that C9 had a maximum dimension estimated at 12 +/- 2 nm, and this suggests that the lengths of 7-8 nm deduced from previous electron microscopy studies in vacuo are underestimated. Molecular modeling of the C9 scattering curves utilized small spheres in the Debye equation, in which the analyses were constrained by the known volumes of the four moieties of C9 and the known sizes of the TSR and EGF-like domains. The most likely models for C9 suggest that these four regions of C9 are arranged in a V-shaped structure, with an angle of 10 degrees between the two arms, each of length 11.1 nm. This structure has a more hydrophobic character between the two arms. The scattering model is fully consistent with hydrodynamic sedimentation data on C9. Similar V-shaped hydrodynamic models could be developed for C6, C7, C8, and C9 of complement. Such a compact structure is atypical of other multidomain complement proteins so far studied by solution scattering and is fully compatible with mechanisms in which C9 is postulated, on activation, to undergo a drastic unfolding of its domain structure and to expose a more hydrophobic surface which can be embedded into lipid bilayers.