Release of C8 binding protein (C8bp) from the cell membrane by phosphatidylinositol-specific phospholipase C.
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Erythrocytes from patients with paroxysmal nocturnal hemoglobinuria (PNH) are abnormally sensitive to complement. Two membrane proteins, the C8 binding protein (C8bp) and the decay accelerating factor (DAF), which are expressed on normal cells, function to restrict lysis by homologous complement, and both of these proteins are absent from PNH erythrocytes. DAF is anchored to the plasma membrane on normal cells by a phosphatidylinositol linkage. The investigators found that a purified phosphatidylinositol-specific phospholipase C cleaved C8bp from the surface of normal lymphocytes and monocytes. This finding indicates that the abnormal complement sensitivity of PNH erythrocytes arises from a common defect, the inability to attach the phosphatidylinositol-containing anchor that is necessary for the membrane expression of both membrane complement regulatory proteins, the C8bp, and DAF. (+info)
Human C81 (alpha-gamma) polymorphism: detection in the alpha-gamma subunit on SDS-PAGE, formal genetics and linkage relationship.
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The molecular basis of human C81 (alpha-gamma) polymorphism could be elucidated by immunoprecipitation of human C81 allotypes and separation of the alpha-gamma and beta subunits on sodium dodecylsulfate polyacrylamide gel electrophoresis (SDS-PAGE) under nonreducing conditions. If the C8 molecules were completely reduced, C81 polymorphism was no longer detectable on SDS-PAGE. It is concluded that C81 variation depends on charge rather than molecular weight differences. Four C81 allotypes, the common A and B and two rare allotypes provisionally named A2 and B1, could be distinguished. The rare allotype A1 as detected by isoelectric focusing with subsequent C8 (alpha-gamma)-dependent functional overlay could no longer be visualized on SDS-PAGE. This allotype may therefore be elicited only in the intact C8 molecule. The beta-chain polymorphism named C82, probably also reflecting charge variation of the C8 molecule, could not be detected yet on SDS-PAGE. The distributions of C81 phenotypes and their respective allele frequencies were in good agreement with previously reported data. In the study of 30 families with 100 offspring, no deviation from the rule of at least four codominant alleles at one genetic locus was found. Linkage between C81 gene(s) and PGM1a encoded on chromosome 1 could be confirmed. The following estimates were obtained: (formula; see text) with S theta being the standard error of the maximum likelihood estimate theta. The new technique for allotyping human C81 at the subunit may provide a new tool for the differentiation of qualitative and quantitative variation of the eighth component of human complement. (+info)
Does complement kill E. coli by producing transmural pores?
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Three lines of evidence are presented to indicate that C5b-9 kills serum-sensitive E. coli K 12 cells by generating functional pores across the outer and inner bacterial membrane. First, viable cells carrying C5b-8 complexes are impermeable to o-nitrophenyl-beta-D-galactoside (ONPG), but lose viability and become permeable to this marker upon post-treatment with purified C9 in the absence of lysozyme. Cells killed with colicin E1 or gentamicin are also impermeable to ONPG but take up the marker if they are post-treated with lysozyme-free serum. Second, killing by C5b-9 is highly effective, deposition of only a small number of complexes being lethal. This has been demonstrated in experiments where viable cells carrying 2000-4000 C5b-7 complexes per CFU were permitted to multiply in broth culture, and the daughter generations subsequently treated with purified C8 and C9. Fifty percent killing was observed in the fifth to sixth generation, corresponding to a dilution of C5b-7 complexes to 50-100 molecules/CFU. In the presence of 2 mM EDTA, further dilution of C5b-7 down to 8-30 complexes/CFU still caused 50% killing of daughter cells. Third, treatment of C5b-7 cells with purified CC8 and C9 results in the release of intracellular K+, which commences immediately after addition of C8/C9. This was shown in experiments where C5b-7 cells were packed to high density in saline, post-treated with C8 + C9, and K+ directly measured in the cell supernatants. Based on these results, we propose that C5b-9 pores deposited in the outer bacterial membrane periodically fuse with the inner membrane, the transmural pores thus generated permitting rapid K+ efflux, with cell death ensuing through the collapse of membrane potential. (+info)
Bactericidal-activities of human polymorphonuclear leukocyte proteins against Escherichia coli O111:B4 coated with C5 or C8.
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The postnuclear supernatant of disrupted polymorphonuclear leukocytes exhibited bactericidal activity on Escherichia coli O111:B4 coated with immunoglobulin M antibodies and C5 or C8 but not on C3- or C7-coated bacteria. To characterize this antimicrobial activity further, granules obtained from the postnuclear supernatant were extracted with sodium acetate (pH 4) and the soluble extract was subsequently fractionated through carboxymethyl cellulose and Sephacryl S-200. Over 90% of the activity present in the starting material was recovered in the soluble granule extract. Kinetic and dose-response analyses of the bacterial activity of the polymorphonuclear leukocyte extract on BAC1-5 and BAC1-8 revealed different susceptibilities to killing of these two bacterial intermediates; they also differed for their susceptibilities to killing at 37 degrees C and at room temperature. The suggestion raised by these data, that BAC1-5 and BAC1-8 could be killed by different bactericidal factors, was confirmed by the findings that separate fractions of the soluble granule extract obtained by carboxymethyl cellulose and Sephacryl S-200 chromatography exhibited specific activity on either BAC1-5 or BAC1-8, whereas other fractions were active on both intermediates. (+info)
The pore-forming protein (perforin) of cytolytic T lymphocytes is immunologically related to the components of membrane attack complex of complement through cysteine-rich domains.
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Structural, functional and immunological similarities between the ninth component of complement (C9) and the lymphocyte pore-forming protein (PFP, perforin) have recently been described (8-10). PFP is shown here to be immunologically related to all other components of the membrane attack complex (MAC) of human complement, namely, C5b-6, C7, C8, and C9. Polyclonal antibodies raised against purified human C5b-6, C7, C8, or C9 react with other components of the MAC and with mouse lymphocyte PFP. The antigenic epitopes shared by human complement proteins and mouse lymphocyte PFP are limited to cysteine-rich domains. Only complement proteins that have been reduced and alkylated elicit the production of crossreactive antibodies when used as immunogens. The nonreduced forms of complement components or lymphocyte PFP neither react with these antibodies nor give rise to crossreactive antibodies. The homologous domains of complement proteins and lymphocyte PFP may play related functions in their attachment to lipid membranes and assembly of membrane lesions. (+info)
Killing of human melanoma cells by the membrane attack complex of human complement as a function of its molecular composition.
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The efficiency of the membrane attack complex (MAC) in killing M21 melanoma cells was determined varying the molar ratio of cell-bound C9:C8. It was found that C5b-8 produced functional channels as evidenced by 86Rb release and propidium iodide uptake; cell killing occurred in the absence of C9 with greater than 5 X 10(5) C5b-8/cell; the maximal molar ratio of C9:C8 was 6.6:1; using nonlytic numbers of C5b-8 (4.7 X 10(5)/cell), greater than 90% killing ensued at a C9:C8 molar ratio of 2.8:1 at which approximately 9,000 poly C9/cell were formed, and 50% killing at a ratio of 1:1; (e) when the MAC was assembled on cells at 0 degree C, consisting of C5b-8(1)9(1), and unbound C9 was removed before incubation at 37 degrees C, killing was similar to that observed when poly C9 formation was allowed to occur. Thus, MAC lytic efficiency toward M21 cells may be enhanced by but does not depend on poly C9 formation. (+info)
Paroxysmal nocturnal hemoglobinuria type III. Lack of an erythrocyte membrane protein restricting the lysis by C5b-9.
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The complement-mediated lysis is inefficient when complement and target cells are homologous with regard to the species. In erythrocytes from patients suffering from paroxysmal nocturnal hemoglobinuria (PNH), the species restriction is lost: PNH-erythrocytes (PNH-E) are susceptible to lysis by human complement. In human erythrocytes (huE) the species restriction is ascribed to an integral membrane protein, designated C8-binding protein (C8bp). In the present study, we tested membranes of PNH-E type III for the presence of C8bp. A protein with C8-binding capacity could not be detected. C8bp, which was isolated from the membrane of huE, inhibited the lysis of PNH-E by C5b-9 as well as the C9 polymerization. Thus, addition of C8bp restored the species restriction in PNH-E. In conclusion, we propose that lack of C8bp might represent the defect in PNH-E type III membranes, which is responsible for their enhanced lytic susceptibility towards lysis by the late complement components. (+info)
C3-independent immune haemolysis: mechanism of membrane attack complex formation.
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The isolated active complex of C5 and C6, C56, was found to bind to EAC142 in the absence of C3 or C7, and to form a unique intermediate, EAC14256, which is susceptible to lysis by the addition of C7, C8 and C9. Further studies revealed that C56 alone could bind to EAC142 but not to E, EA, EAC1 or EAC4, nor to EAC14 in the absence of C7, that the C56 binding to EAC142 was highly dependent on temperature and on the ionic strength of the buffer, and that the degree of EAC14256 formation from EAC142 and C56 depended on the amount of C2 on EAC142 and on the amount of added C56. These findings suggest that C2 or C42 on EAC142 may be an acceptor for C56. In addition, C56 appears to bind to EAC142 much more efficiently than to unsensitized erythrocytes, even in the presence of C7. Thus, binding of C56 to EAC142 is likely to be an initial step of membrane attack complex formation in C3-independent immune haemolysis. (+info)