Functional analyses of rare genetic variants in complement component C9 identified in patients with age-related macular degeneration.

Age-related macular degeneration (AMD) is a progressive disease of the central retina and the leading cause of irreversible vision loss in the western world. The involvement of abnormal complement activation in AMD has been suggested by association of variants in genes encoding complement proteins with disease development. A low-frequency variant (p.P167S) in the complement component C9 (C9) gene was recently shown to be highly associated with AMD; however, its functional outcome remains largely unexplored. In this study, we reveal five novel rare genetic variants (p.M45L, p.F62S, p.G126R, p.T170I and p.A529T) in C9 in AMD patients, and evaluate their functional effects in vitro together with the previously identified (p.R118W and p.P167S) C9 variants. Our results demonstrate that the concentration of C9 is significantly elevated in patients' sera carrying the p.M45L, p.F62S, p.P167S and p.A529T variants compared with non-carrier controls. However, no difference can be observed in soluble terminal complement complex levels between the carrier and non-carrier groups. Comparing the polymerization of the C9 variants we reveal that the p.P167S mutant spontaneously aggregates, while the other mutant proteins (except for C9 p.A529T) fail to polymerize in the presence of zinc. Altered polymerization of the p.F62S and p.P167S proteins associated with decreased lysis of sheep erythrocytes and adult retinal pigment epithelial-19 cells by carriers' sera. Our data suggest that the analyzed C9 variants affect only the secretion and polymerization of C9, without influencing its classical lytic activity. Future studies need to be performed to understand the implications of the altered polymerization of C9 in AMD pathology.

Neuromodulatory state and sex specify alternative behaviors through antagonistic synaptic pathways in C. elegans.

Pheromone responses are highly context dependent. For example, the C. elegans pheromone ascaroside C9 (ascr#3) is repulsive to wild-type hermaphrodites, attractive to wild-type males, and usually neutral to "social" hermaphrodites with reduced activity of the npr-1 neuropeptide receptor gene. We show here that these distinct behavioral responses arise from overlapping push-pull circuits driven by two classes of pheromone-sensing neurons. The ADL sensory neurons detect C9 and, in wild-type hermaphrodites, drive C9 repulsion through their chemical synapses. In npr-1 mutant hermaphrodites, C9 repulsion is reduced by the recruitment of a gap junction circuit that antagonizes ADL chemical synapses. In males, ADL sensory responses are diminished; in addition, a second pheromone-sensing neuron, ASK, antagonizes C9 repulsion. The additive effects of these antagonistic circuit elements generate attractive, repulsive, or neutral pheromone responses. Neuronal modulation by circuit state and sex, and flexibility in synaptic output pathways, may permit small circuits to maximize their adaptive behavioral outputs.

Incorporation of human complement C8 into the membrane attack complex is mediated by a binding site located within the C8beta MACPF domain.

Human C8 is one of five complement components (C5b, C6, C7, C8, C9) that interact to form the membrane attack complex (MAC). C8 is an oligomeric protein composed of a disulfide-linked C8alpha-gamma heterodimer and a noncovalently associated C8beta chain. C8alpha and C8beta are homologous; both contain N- and C-terminal modules and an intervening approximately 40 kDa segment referred to as the membrane attack complex/perforin (MACPF) domain. C8beta participates in at least two binding interactions. It has a high affinity binding site for C8alpha, which facilitates its interaction with C8alpha-gamma. C8beta also mediates incorporation of C8 into the MAC by binding to C5b-7, an intermediate in the MAC assembly pathway. Little is known about the location or properties of the respective binding sites on C8beta. In this study, the MACPF domain of C8beta (betaMACPF) was expressed in Escherichia coli and its role in binding C8alpha and C5b-7 examined. Recombinant betaMACPF was shown to bind C8alpha-gamma in solution and form a noncovalent complex (betaMACPF*C8alpha-gamma) that exhibited C8 hemolytic activity. betaMACPF was also capable of binding independently to erythrocytes carrying C5b-7. Subsequent addition of C8alpha-gamma and C9 to these cells produced a hemolytically active MAC. The ability to produce a soluble, recombinant betaMACPF that retains the binding functions of C8beta suggests this segment of C8beta is an independently folded domain. Furthermore, results indicate the principal binding sites for C8alpha and C5b-7 are located within this domain, and that C8beta binding specificity is not determined by the N- and C-terminal modules.

Supplemental complement component C9 enhances the capacity of neonatal serum to kill multiple isolates of pathogenic Escherichia coli.

Previous studies demonstrated that, compared with adult serum, neonatal serum contained a diminished concentration of complement component C9 and that supplemental C9 enhanced the capacity of neonatal serum to kill an isolate of Escherichia coli. Therefore, experiments were designed to determine the mechanisms by which supplemental C9 enhances the bactericidal capacity of neonatal serum and to determine whether supplemental C9 enhances the capacity of neonatal serum to kill several different pathogenic strains of E. coli. A radiobinding assay and immunogold electron microscopy using a monoclonal anti-C9 antibody revealed that, compared with 40% adult serum, neonatal serum deposited a diminished quantity of C9 onto E. coli O7w:K1:NM. Supplemental C9 (75 mg/L) significantly enhanced the quantity of C9 deposited by the neonatal serum. Treatment with 10 mM MgEGTA (a mixture of 100 mM MgCl2 and 100 mM EGTA that blocks activation of the classic complement pathway but leaves the alternative pathway intact) abolished the capacity of neonatal serum to deposit C9 and to kill the bacteria. Supplemental C9 enhanced the capacity of neonatal serum to kill eight different blood isolates of E. coli. Therefore, supplemental C9 enhanced the capacity of neonatal serum to kill E. coli by increasing the total quantity of C9 deposited via activation of the classic complement pathway. Neonatal serum contained sufficient quantities of classic pathway components, other than C9, to deposit the supplemental C9 onto E. coli and to enhance bacterial killing. The bactericidal activity of neonatal serum against multiple isolates of pathogenic E. coli was increased after C9 supplementation.(ABSTRACT TRUNCATED AT 250 WORDS)

The expression of hemolytically active human complement protein C9 in mammalian, insect, and yeast cells.

The cDNA sequence encoding mature human C9 protein and its signal peptide was cloned into three expression vectors for expression in COS-7 (mammalian), Spodoptera frugiperda IPLB-SF-21AE (insect), and Saccharomyces cerevisiae (yeast) cells. In addition, C9 cDNA encoding only the mature protein was fused to the yeast invertase leader sequence (SUC2) and cloned for expression in yeast. Under optimal conditions COS-7 and IPLB-SF-21AE cells secreted recombinant C9 (rC9) at concentrations of about 111 and 700 ng C9/ml culture supernatant, respectively. By comparison S. cerevisiae, whether transformed with C9 cDNA containing its native or yeast invertase leader sequence, secreted only very small amounts of rC9 (5-10 ng/ml). However, upon lysis concentrations of up to 500 ng/mg dry wt were found in yeast cells transformed with C9 cDNA. SDS-PAGE followed by Western blot analysis revealed COS-7 cell and S. cerevisiae expressed rC9 to have a MW similar to that of native C9 purified from human serum, while rC9 from IPLB-SF-21AE cells was about 4 kDa smaller. No hemolytic activity of S. cerevisiae secreted rC9 could be detected and the specific hemolytic activity of S. cerevisiae intracellular rC9 was also very low. However, the specific hemolytic activities of COS-7 and IPLB-SF-21AE secreted rC9 were indistinguishable from that of purified native human C9. Thus, for future studies on the structure and function of C9 where the production of large quantities of mutant protein would be desirable, the baculovirus-insect cell expression system appears to offer considerable advantages.

Effect of the late complement components C5b-9 and of platelet-derived growth factor on the prostaglandin release of human synovial fibroblast-like cells.

We examined the prostaglandin E (PGE) synthesis of cultured adherent synovial fibroblast-like cells (SFC) from patients with osteoarthritis (OA) in the noninflammatory state as well as with rheumatoid arthritis (RA). In cells from RA patients the spontaneous PGE release was generally higher compared to that of OA patients, but decreased fast with time in culture. After cell passage, similar PGE baseline levels were seen in cells of the two patient groups. The cells could then be stimulated by the terminal complement components C5b-9 or C5b-8. PGE synthesis was also stimulated by the platelet-derived growth factor (PDGF), interleukin-1 (IL-1), or lipopolysaccharide (LPS). The amount of PGE synthesis after incubation with PDGF, LPS and IL-1 was comparable to that released after C5b-9. Thus, like other inflammatory mediators C5b-9 and PDGF trigger the increased PGE production by SFC and thus may participate in the development of synovial inflammation and contribute to the pathogenesis of RA.

The ninth component of human complement (C9). Functional activity of the b fragment.

The domain structure of human complement protein C9 was investigated by determining the functional activities of the NH2-terminal (C9a) and COOH-terminal (C9b) fragments obtained by cleavage of C9 with alpha-thrombin. The two fragments were separated by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis and renatured by dialysis against buffers containing zwitterionic detergents. The C9b fragment produced membranolytic activities in three independent assays. First, it produced single, ion-conducting channels of varying conductances in planar lipid membranes. Most of the channels had an average conductance of 11 picoSiemens and an average lifetime of about 30 s. The channels showed lipid specificity and a 3-fold preference for conducting K+ over Na+. Second, the fragment also caused specific marker release from liposomes which was inhibitable by a C9b-specific monoclonal antibody, and third, it lysed erythrocytes in the absence of a fully assembled C5b-8 complex. The isolated C9a fragment did not produce single channels in planar lipid membranes but was also effective in releasing markers from liposomes and in lysing erythrocytes. Secondary structure predictions indicate the presence of several amphiphilic, "surface-seeking" segments in the primary structure of C9 which are mainly alpha-helices in C9b and beta-sheets in C9a. These results may indicate the presence of surface-binding domains in the NH2-terminal half and channel-forming domains in the COOH-terminal portion of native, monomeric C9.

Assembly of the membrane attack complex of complement on small unilamellar phospholipid vesicles.

Light-scattering intensity was shown to be a reliable, direct, and quantitative technique for monitoring the assembly of the membrane attack complex of complement (proteins C5b-6, C7, C8, and C9) on small unilamellar phosphatidylcholine vesicles. The assembly on vesicles occurred in a simple fashion; complexes of C5b-7 bound noncooperatively to the vesicles, and final assembly of C5b-9 did not induce vesicle aggregation or fragmentation. When C5b-6 and C7 were mixed in the presence of vesicles but at molar protein/vesicle ratios of less than 1, there was quantitative binding of C5b-7 to the vesicles with no concomitant aggregation of C5b-7. If C7 was added at a slower rate, quantitative binding was obtained at molar C5b-7/vesicle ratios of up to 5. The latter observations (a) were consistent with the proposal that C5b-7 aggregation and membrane binding were competitive events and (b) defined conditions under which light-scattering intensity measurements could monitor C5b-9 assembly on vesicles without contribution from the fluid-phase assembly. The C8/C5b-7 ratio in the phospholipid-C5b-8 complex was 0.97 +/- 0.12, and the maximum ratio of C9/C5b-8 in the final complex was 16.2 +/- 2.0. One C9 molecule associated rapidly with each phospholipid-C5b-8, followed by slower incorporation of the remaining C9 molecules. The initial velocity of the slow phase of C9 addition was easily saturated with C9 and gave an activation energy of 37 kcal/mol. This was identical with the value measured for the analogous process in the fluid-phase assembly.(ABSTRACT TRUNCATED AT 250 WORDS)

Membrane fluidity change in erythrocytes induced by complement system.

The structural change in erythrocyte membranes induced by antibody and complement was studied using phospholipid spin-labels. Sheep erythrocytes were labeled with phosphatidylcholine spin-label and various intermediate cells (erythrocyte-antibody complex (EA), EA bound with complement components from C1 to C7 (EAC1-7), EAC1-8, and EAC1-9) were prepared. Electron spin resonance spectra of EA, EAC1-7, and EAC1-8 were very similar to that of the erythrocytes, while that of EAC1-9 was markedly different. The overall splitting value for the lysed EAC1-9 (53 G) was much smaller than that for the erythrocytes (57 G), indicating a marked fluidization around the phosphatidylcholine label. The unlysed EAC1-9 membranes contained a limited fraction of the fluidized area. When EA was reacted with complement in the presence of 36% bovine serum albumin, the membranes were fluidized similarly to the lysed EAC1-9, although the hemolysis was largely blocked. The membranes of unlysed EAC1-9 prepared in isotonic (ethylenedinitrilo)tetraacetic acid were also fluidized, but to somewhat smaller extent. The role of C9 in the modification of erythrocyte membranes was also demonstrated using Mg2+ ghosts, which were prepared by hypotonic hemolysis in the presence of Mg2+. The membranes of Mg2+ ghost of EAC1-7 were markedly fluidized when bound with C8 and C9, but not affected by binding of C8 only. The component C8 was found to give a latent effect on the membranes that caused irreversible fluidization upon osmotic shock. The terminal component thus creates a fluidized area in the erythrocyte membranes through which small ions and molecules may diffuse more easily and the resulting osmotic unbalance may finally cause hemolysis.

Increased ion permeability of planar lipid bilayer membranes after treatment with the C5b-9 cytolytic attack mechanism of complement.

The ion permeability of planar lipid bilayers, as measured electrically, was found to increase modestly upon treatment with purified complement complex C5b,6 and complement components C7 and C8. The subsequent addition C9 greatly amplified this change. No permeability changes occurred when components were added individually to the membrane, or when they were used in paired combinations, or when C5b, C7, C8, and C9 were admixed prior to addition. Thus, there is a significant parallel between the permeability changes induced in the model membrane and damage produced in biological membranes by the C5b-9 complement attack sequence. The efficiency of membrane action by C5b-9 was critically dependent on the order in whcih components were added to the membrane. There were also differences in the electrical properties of membranes treated with C5b-8 and C5b-9, though in both cases the enhanced bilayer permeability is best attributed to the formation of trans-membrane channels. Collectively, the data are consistent with the hypothesis that the mechanism of membrane action by complement involves the production of a stable channel across the lipid bilayer, resulting in cell death by colloid-osmotic lysis.