The homologous restriction factor is immunologically related to complement components C8 and C9 and to lymphocyte pore-forming protein perforin through cysteine-rich domains

The 65 kDa C8-binding protein or homologous restriction factor (C8bp/HRF) protects cells from complement (C)-mediated lysis by binding to C8 and abrogating lytic channel formation. Human C8bp/HRF is shown here to be immunologically related to human C8 and C9 and to murine lymphocyte poreforming protein (PFP, perforin). Polyclonal antibodies raised against purified C8, C9 and perforin react with C8bp/HRF. The antigenic epitopes shared by these four proteins are limited to cysteine-rich or disultide bridge-masked domains. Only complement proteins or perforin that have been disulfide-reduced elicit the production of cross-reactive antibodies when used as immunogens. Analogously, only C8bp/HRF that has been disulfide-reduced reacts with these antibodies. These results suggest that C8bp/HRF may belong to the complement/perforin supergene family. The function of homologous domains shared by these four proteins remains to be elucidated.     

Differential susceptibility of type III erythrocytes of paroxysmal nocturnal hemoglobinuria to lysis mediated by complement and perforin

Previous reports have suggested that a 65 kDa membrane protein, termed homologous restriction factor (HRF), in addition to protecting erythrocytes (E) against lysis by homologous complement (C), may also be involved in protecting cytolytic lymphocytes against lysis mediated by a pore-forming protein (PFP/perforin), one of their own lytic mediators. Here, we used HRF-deficient type III E of patients with paroxysmal nocturnal hemoglobinuria (PNH) to study their susceptibility to lysis mediated by homologous C and perforin, and compared it with lysis of HRF-bearing control or PNH type I E. We show that type III E of PNH patients are indeed more susceptible to lysis mediated by homologous C than control or type I E, but they are as susceptible to perforin-mediated lysis as type I E. In addition, all human E (type I or III) tested here are equally susceptible to lysis mediated by either human (homologous) or murine (heterologous) perforin. By immunoblot analysis, we confirm that type III E, in contrast to type I E, were deficient in the 65 kDa HRF. These results support the notion that homologous species restriction is seen in the C- but not in the lymphocyte perforin-system and argue against an active participation of HRF in protecting cells from perforin-mediated lysis.     

Structure of human complement C8, a precursor to membrane attack

Complement component C8 plays a pivotal role in the formation of the membrane attack complex (MAC), an important antibacterial immune effector. C8 initiates membrane penetration and coordinates MAC pore formation. High-resolution structures of C8 subunits have provided some insight into the function of the C8 heterotrimer; however, there is no structural information describing how the intersubunit organization facilitates MAC assembly. We have determined the structure of C8 by electron microscopy and fitted the C8α-MACPF (membrane attack complex/perforin)-C8γ co-crystal structure and a homology model for C8β-MACPF into the density. Here, we demonstrate that both the C8γ protrusion and the C8α-MACPF region that inserts into the membrane upon activation are accessible.     

Paroxysmal nocturnal haemoglobinuria (PNH) is caused by somatic mutations in the PIG-A gene.

Paroxysmal nocturnal haemoglobinuria (PNH), an acquired clonal blood disorder, is caused by the absence of glycosyl phosphatidylinositol (GPI)-anchored surface proteins due to a defect in a specific step of GPI-anchor synthesis. The cDNA of the X-linked gene, PIG-A, which encodes a protein required for this step has recently been isolated. We have carried out a molecular and functional analysis of the PIG-A gene in four cell lines deficient in GPI-linked proteins, obtained by Epstein-Barr virus (EBV) transformation of affected B-lymphocytes from PNH patients. In all four cell lines transfection with PIG-A cDNA restored normal expression of GPI-linked proteins. In three of the four cell lines the primary lesion is a frameshift mutation. In two of these there is a reduction in the amount of full-length mRNA. The fourth cell line contains a missense mutation in PIG-A. In each case the mutation was present in the affected granulocytes from peripheral blood of the patients, but not in normal sister cell lines from the same patient. These data prove that PNH is caused in most patients by a single mutation in the PIG-A gene. The nature of the mutation can vary and most likely occurs on the active X-chromosome in an early haematopoietic stem cell.     

Enhanced reactive lysis of paroxysmal nocturnal hemoglobinuria erythrocytes by C5b-9 does not involve increased C7 binding or cell-bound C3b

The most complement (C)-sensitive type of erythrocytes (E) occurring in paroxysmal nocturnal hemoglobinuria (type III PNH E) have previously been found to exhibit approximately twofold to fourfold greater lysis than normal human E when exposed to isolated human C5b6, C7, C8, and C9 (reactive lysis), in the absence of a known source of C3- or C5-convertases or fluid-phase C3. In further studies on the mechanism of this phenomenon, we now report that C5b6-dependent binding of 125I-C7 to two samples of PNH E (greater than 95% type III) is equal to that found with normal human E at each of several C5b6 inputs tested. Lysis developed by excess C8 and C9, however, was consistently greater for the PNH E. Thus, the exaggerated sensitivity of type III PNH E to reactive lysis cannot be explained by abnormally high uptake of C5b6 or C7 from the fluid phase. Rather, the data indicate that cell-bound C5b67 sites are converted to effective hemolytic sites with greater efficiency on type III PNH E than on normal human E, assuming that the distribution of cell-bound C7 throughout both cell populations is similar. In related studies we have addressed the proposal by other investigators that C3b putatively bound to PNH E in vivo might account for their increased sensitivity to reactive lysis in vitro, by analogy to prior observations on C3b-potentiated reactive lysis of sheep E. The latter hypothesis was made more appealing by the recent discovery that type III PNH E lack an integral membrane protein, decay-accelerating factor (DAF), which in normal E accelerates the decay of membrane-bound C3 convertases. Against this hypothesis, however, is our present finding that preincubation of PNH E with four different goat or rabbit polyclonal antibodies to human C3 failed to inhibit the subsequent reactive lysis of these cells. Under these same conditions, the C3b-dependent increment in reactive lysis of sheep EAC4b3b was abrogated by pretreatment with similar dilutions of these anti-C3 antibodies, generally in association with agglutination. Furthermore, sheep EAC4b3b displayed increased 125I-C7 binding in proportion to augmented lysis, in contrast to the findings with PNH E. Therefore, deficiency of DAF in type III PNH E does not adequately explain their supranormal sensitivity to reactive lysis unless DAF can modulate the terminal lytic steps by a mechanism distinct from its effect on C3 convertase decay. Alternatively, type III PNH E could have a more general abnormality in which DAF deficiency is one manifestation and increased sensitivity to reactive lysis is another.     

Binding of the complement inhibitor C4bp to serogroup B Neisseria meningitidis

Neisseria meningitidis (meningococcus) is an important cause of meningitis and sepsis. Currently, there is no effective vaccine against serogroup B meningococcal infection. Host defense against neisseriae requires the complement system (C) as indicated by the fact that individuals deficient in properdin or late C components (C6-9) have an increased susceptibility to recurrent neisserial infections. Because the classical pathway (CP) is required to initiate efficient complement activation on neisseriae, meningococci should be able to evade it to cause disease. To test this hypothesis, we studied the interactions of meningococci with the major CP inhibitor C4b-binding protein (C4bp). We tested C4bp binding to wild-type group B meningococcus strain (H44/76) and to 11 isogenic mutants thereof that differed in capsule expression, lipo-oligosaccharide sialylation, and/or expression of either porin (Por) A or PorB3. All strains expressing PorA bound radiolabeled C4bp, whereas the strains lacking PorA bound significantly less C4bp. Increased binding was observed under hypotonic conditions. Deleting PorB3 did not influence C4bp binding, but the presence of polysialic acid capsule reduced C4bp binding by 50%. Bound C4bp remained functionally active in that it promoted the inactivation of C4b by factor I. PorA-expressing strains were also more resistant to C lysis than PorA-negative strains in a serum bactericidal assay. Binding of C4bp thus helps Neisseria meningitidis to escape CP complement activation.     

Binding of the lipocalin C8gamma to human complement protein C8alpha is mediated by loops located at the entrance to the C8gamma ligand binding site

Human C8 is one of five complement components (C5b, C6, C7, C8 and C9) that interact to form the membrane attack complex (MAC). C8 is composed of a disulfide-linked C8alpha-gamma heterodimer and a noncovalently associated C8beta chain. C8alpha and C8beta are homologous to C6, C7 and C9, whereas C8gamma is the only lipocalin in the complement system. Lipocalins have a core beta-barrel structure forming a calyx with a binding site for a small molecule. In C8gamma, the calyx opening is surrounded by four loops that connect beta-strands. Loop 1 is the largest and contains Cys40 that links to Cys164 in C8alpha. To determine if these loops mediate binding of C8alpha prior to interchain disulfide bond formation in C8alpha-gamma, the loops were substituted separately and in combination for the corresponding loops in siderocalin (NGAL, Lcn2), a lipocalin that is structurally similar to C8gamma. The siderocalin-C8gamma chimeric constructs were expressed in E. coli, purified, and assayed for their ability to bind C8alpha. Results indicate at least three of the four loops surrounding the entrance to the C8gamma calyx are involved in binding C8alpha. Binding near the calyx entrance suggests C8alpha may restrict and possibly regulate access to the C8gamma ligand binding site.     

Enhanced expression of the complement-regulatory factor C8 binding protein (C8bp) on U937 cells after stimulation with IL-1 beta, endotoxin, IFN-gamma, or phorbol ester.

C8 binding protein (C8bp) is a 65-kDa membrane glycoprotein that inhibits complement-mediated lysis by homologous C5b-9. C8bp was first identified on human erythrocytes, but could also be detected on peripheral blood cells, platelets, glomerular cells and synovial fibroblasts. Lack of C8bp as seen in patients with paroxysmal nocturnal hemoglobinuria type III results in enhanced susceptibility of the cells toward C5b-9. We studied C8bp expression on the promonocytic cell line U937. In addition to the membrane-bound C8bp, a cytoplasmic form of C8bp could also be identified by immunofluorescence, blotting, and precipitation. Stimulation of the cells with IL-1 beta, endotoxin, IFN-gamma, or phorbol ester increased C8bp surface expression. Because cycloheximide did not inhibit enhanced surface expression, it was most probably mobilized from cytoplasmic reservoirs. Thus, resistance of nuclear cells to complement attack seems to be based on two events: 1) the removal of the C5b-9 complex from the membrane; and 2) expression of regulatory surface proteins such as C8bp, which inhibit C5b-9-mediated lysis. We propose that the C8bp mobilization by cytokines might provide an additional protection against complement attack by its known interference with the C5b-9 assembly.     

Regulation of the membrane attack complex of complement. Evidence that C8 gamma is not the target of homologous restriction factors

Inability of the membrane attack complex of C (C5b-9) to efficiently lyse E from the same species has been attributed to one or more membrane-associated proteins that are collectively called homologous restriction factors. These include a 65,000 Mr protein referred to as the C8 binding protein or homologous restriction factor and a 20,000 Mr protein referred to as P-18, HRF20, CD59 Ag, or MIRL. Both are found on nucleated cells as well as E and both protect against complement-mediated lysis by interfering with C8 and/or C9 function within C5b-9. The exact mechanism by which these factors restrict activity is unknown but studies with purified C8 binding protein suggest they may interact specifically with the gamma subunit of C8. To determine directly if gamma is the target of restriction factors, a derivative of human C8 lacking this subunit was evaluated for its potential to lyse homologous cells. This derivative (C8') was previously shown to be functionally equivalent to normal C8 in a heterologous sheep E system. Here, it is compared to normal C8 by using human E as target cells. Results indicate no difference between the ability of C8 and C8' to incorporate into HuEAC1-7, to mediate subsequent C9 binding and to promote hemolysis. Thus, the presence or absence of gamma has no effect on homologous restriction of C5b-9, therefore gamma cannot be the primary target of homologous restriction factors.     

Effect of complement on the lateral mobility of erythrocyte membrane proteins. Evidence for terminal complex interaction with cytoskeletal components

The lateral mobilities of erythrocyte membrane proteins and terminal complement complexes (TCC) were measured on C-treated erythrocyte ghosts by the technique of fluorescence redistribution after photobleaching. Results showed that the lateral diffusion coefficient of the bulk membrane proteins decreased with the assembly of TCC on the membrane at low C dose and was significantly reduced with assembly of the full membrane attack complex (C5b-9), even in the absence of cell lysis. At high serum doses, the mobility of the membrane proteins increased slightly above that of the control cells. The diffusion coefficients of the TCC on the erythrocyte membrane range from 1.18 to 4.37 x 10(-11) cm2/s, values characteristic of anchored membrane proteins. Spectrin-depletion of the C-lysed erythrocytes results in 25- and 45-fold increases in the diffusion coefficients of the membrane proteins and the C5b-9 complex, respectively. Conversely, oxidative cross-linking of spectrin by diamide reduced the diffusion coefficients of both membrane and C proteins. These studies indicate that the deposition of TCC on an erythrocyte can result in a substantial change in the physical and structural properties of the target membrane, aside from the creation of functional lesions. The low mobilities of the terminal complexes on the target membrane suggest possible interactions with cytoskeletal elements or with anchored membrane proteins.     

Molecular composition of the terminal membrane and fluid-phase C5b-9 complexes of rabbit complement. Absence of disulphide-bonded C9 dimers in the membrane complex

The terminal membrane C5b-9(m) and fluid-phase SC5b-9 complexes of rabbit complement were isolated from target sheep erythrocyte membranes and from inulin-activated rabbit serum respectively. In the electron microscope, rabbit C5b-9(m) was observed as a hollow protein cylinder, a structure identical with that of human C5b-9(m). Monodispersed rabbit C5b-9(m) exhibited an apparent sedimentation coefficient of 29 S in deoxycholate-containing sucrose density gradients, corresponding to a composite protein-detergent molecular-weight of approx. 1.4 X 10(6). Protein subunits corresponding to human C5b-C9 were found on sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. By densitometry, there were consistently six molecules of monomeric C9 present for each monomeric C5b-8 complex. Fluid-phase rabbit SC5b-9 was a hydrophilic 23 S ma macromolecule that differed in subunit composition from its membrane counterpart in that it contained S-protein and only two to three molecules of C9 per monomer complex. The data are in accord with the previous report on human C5b-9 that C5b-9(m) contains more C9 molecules than SC5b-9 [Ware & Kolb (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 6426-6430]. They corroborate the previous molecular-weight estimate of approx. 10(6) for C5b-9(m) and thus support the concept that the fully assembled, unit lesion of complement is a C5b-9 monomer [Bhakdi & Tranum-Jensen (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 1818-1822]. They also show that C9 dimer formation is not required for assembly of the rabbit C5b-9(m) protein cylinder, or for expression of its membrane-damaging function.     

Activation of glomerular mesangial cells by the terminal membrane attack complex of complement

Treatment of cultured renal glomerular mesangial cells (MC) with nonlytic concentrations of the purified components (C5b-9) of the terminal membrane attack complex (MAC) of complement induced significant functional alterations characteristic of cellular activation. C5b-9-treated MC released large quantities of primarily vasodilatory prostaglandins. In addition, the secretion of an MC-derived auto-growth factor (MC interleukin 1) was greatly enhanced. Examination of the action of C5b-9 on MC phospholipid metabolism indicated that complement induced the activation of phospholipases, leading to quantitative changes in the fatty acid profile of MC membrane phospholipids. These findings demonstrate that cultured MC are highly responsive to nonlytic concentrations of the C5b-9 complex, and suggest that the mesangial deposition of the MAC in many forms of glomerular disease, with resultant cellular activation, may play a major role in the hemodynamic and cellular proliferative events characteristic of these disorders.     

Recombinant C345C and factor I modules of complement components C5 and C7 inhibit C7 incorporation into the complement membrane attack complex

Complement component C5 binds to components C6 and C7 in reversible reactions that are distinct from the essentially nonreversible associations that form during assembly of the complement membrane attack complex (MAC). We previously reported that the approximately 150-aa residue C345C domain (also known as NTR) of C5 mediates these reversible reactions, and that the corresponding recombinant module (rC5-C345C) binds directly to the tandem pair of approximately 75-residue factor I modules from C7 (C7-FIMs). We suggested from these and other observations that binding of the C345C module of C5 to the FIMs of C7, but not C6, is also essential for MAC assembly itself. The present report describes a novel method for assembling a complex that appears to closely resemble the MAC on the sensor chip of a surface plasmon resonance instrument using the complement-reactive lysis mechanism. This method provides the ability to monitor individually the incorporation of C7, C8, and C9 into the complex. Using this method, we found that C7 binds to surface-bound C5b,6 with a K(d) of approximately 3 pM, and that micromolar concentrations of either rC5-C345C or rC7-FIMs inhibit this early step in MAC formation. We also found that similar concentrations of either module inhibited complement-mediated erythrocyte lysis by both the reactive lysis and classical pathway mechanisms. These results demonstrate that the interaction between the C345C domain of C5 and the FIMs of C7, which mediates reversible binding of C5 to C7 in solution, also plays an essential role in MAC formation and complement lytic activity.     

Inhibition of homologous complement by CD59 is mediated by a species-selective recognition conferred through binding to C8 within C5b-8 or C9 within C5b-9.

The capacity of the human complement regulatory protein CD59 to interact with terminal complement proteins in a species-selective manner was examined. When incorporated into chicken E, CD59 (purified from human E membranes) inhibited the cytolytic activity of the C5b-9 complex in a manner dependent on the species of origin of C8 and C9. Inhibition of C5b-9-mediated hemolysis was maximal when C8 and C9 were derived from human (hu) or baboon serum. By contrast, CD59 showed reduced activity when C8 and C9 were derived from dog or sheep serum, and no activity when C8 and C9 were derived from either rabbit or guinea pig (gp) serum. Similar specificity on the basis of the species of origin of C8 and C9 was also observed for CD59 endogenous to the human E membrane, using functionally blocking antibody against this cell surface protein to selectively abrogate its C5b-9-inhibitory activity. When E bearing human CD59 were exposed to C5b-8hu, CD59 was found to inhibit C5b-9-mediated lysis, regardless of the species of origin of C9, suggesting that the inhibitory function of CD59 can be mediated through recognition of species-specific domains expressed by human C8. Consistent with this interpretation, CD59 was found to bind to C5b-8hu but not to C5b67hu or C5b67huC8gp. Although CD59 failed to inhibit hemolysis mediated by C5b67huC8gpC9gp, its inhibitory function was observed for C5b67huC8gpC9hu, suggesting that, in addition to its interaction with C5b-8hu, CD59 also interacts in a species-selective manner with C9hu incorporated into C5b-9. Consistent with this interpretation, CD59 was found to bind both C5b67huC8gpC9hu and C5b-8huC9gp, but not C5b67huC8gpC9gp. Taken together, these data suggest that the capacity of CD59 to restrict the hemolytic activity of human serum complement involves a species-selective interaction of CD59, which involves binding to both the C8 and C9 components of the membrane attack complex. Although CD59 expresses selectivity for C8 and C9 of human origin, this "homologous restriction" is not absolute, and this human complement regulatory protein retains functional activity toward C8 and C9 of some nonprimate species.     

Structure of human C8 protein provides mechanistic insight into membrane pore formation by complement

C8 is one of five complement proteins that assemble on bacterial membranes to form the lethal pore-like “membrane attack complex” (MAC) of complement. The MAC consists of one C5b, C6, C7, and C8 and 12–18 molecules of C9. C8 is composed of three genetically distinct subunits, C8α, C8β, and C8γ. The C6, C7, C8α, C8β, and C9 proteins are homologous and together comprise the MAC family of proteins. All contain N- and C-terminal modules and a central 40-kDa membrane attack complex perforin (MACPF) domain that has a key role in forming the MAC pore. Here, we report the 2.5 Å resolution crystal structure of human C8 purified from blood. This is the first structure of a MAC family member and of a human MACPF-containing protein. The structure shows the modules in C8α and C8β are located on the periphery of C8 and not likely to interact with the target membrane. The C8γ subunit, a member of the lipocalin family of proteins that bind and transport small lipophilic molecules, shows no occupancy of its putative ligand-binding site. C8α and C8β are related by a rotation of ∼22° with only a small translational component along the rotation axis. Evolutionary arguments suggest the geometry of binding between these two subunits is similar to the arrangement of C9 molecules within the MAC pore. This leads to a model of the MAC that explains how C8-C9 and C9-C9 interactions could facilitate refolding and insertion of putative MACPF transmembrane β-hairpins to form a circular pore.     

Inhibition of the formation of the complement membrane-attack complex by a monoclonal antibody to the complement component C8 alpha subunit.

The effect of nine monoclonal antibodies to complement component C8 on the interaction of C9 with preformed cell-surface C5b-8 complexes and on the functional insertion of C8 into the membrane-attack complex (MAC) was investigated. None of the antibodies prevented C9 insertion into a preformed C5b-8 complex. One antibody (F1) directed to the C8 alpha subunit clearly inhibited formation of a functional MAC. It is proposed that this antibody prevents the C8 alpha subunit unfolding and distorting the bilayer to allow C9 insertion.     

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.