Identification of a Naegleria fowleri membrane protein reactive with anti-human CD59 antibody

Naegleria fowleri, the causative agent of primary amebic meningoencephalitis, is resistant to complement lysis. The presence of a complement regulatory protein on the surface of N. fowleri was investigated. Southern blot and Northern blot analyses demonstrated hybridization of a radiolabeled cDNA probe for CD59 to genomic DNA and RNA, respectively, from pathogenic N. fowleri. An 18-kDa immunoreactive protein was detected on the membrane of N. fowleri by Western immunoblot and immunofluorescence analyses with monoclonal antibodies for human CD59. Complement component C9 immunoprecipitated with the N. fowleri "CD59-like" protein from amebae incubated with normal human serum. In contrast, a gene or protein similar to CD59 was not detected in nonpathogenic, complement-sensitive N. gruberi amebae. Collectively, our studies suggest that a protein reactive with antibodies to human CD59 is present on the surface of N. fowleri amebae and may play a role in resistance to lysis by cytolytic proteins.

Detecting distant homologies of mosaic proteins. Analysis of the sequences of thrombomodulin, thrombospondin complement components C9, C8 alpha and C8 beta, vitronectin and plasma cell membrane glycoprotein PC-1

Recognition of homologies may give hints about the structure and function of proteins; therefore, we are developing strategies to aid sequence comparisons. Detecting homology of mosaic proteins is especially difficult since the modules constituting these proteins are usually distantly related and their homology is not readily recognized by conventional computer programs. In the present work we show that the rules of the evolution of mosaic proteins can guide the identification of modules of mosaic proteins and can delineate the group of sequences in which the presence of homologous sequences may be expected. By this approach we can concentrate the search for homology to a limited group of sequences; thus ensuring a more intense and more fruitful search. The power of this approach is illustrated by the fact that it could detect homologies not identified by earlier methods of sequence comparison. In this paper we show that thrombomodulin contains a domain homologous with animal lectins, that complement components C9, C8 alpha and C8 beta have modules homologous with one of the repeat units of thrombospondin and that the somatomedin B module of vitronectin is homologous with the internal repeats of plasma cell membrane glycoprotein PC-1.

Molecular weight of poly(C9). 12 to 18 C9 molecules form the transmembrane channel of complement

Poly(C9), the tubular 27 S complex forming the transmembrane channel of the membrane attack complex of complement, was purified to homogeneity by gel filtration and sucrose density gradient ultracentrifugation. The molecular weight of poly(C9) was determined by two independent methods in addition to sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. First, sedimentation equilibrium analysis using 0.2% SDS or 1% deoxycholate containing buffer as solvents yielded a point weight average molecular weight exclusive of bound detergent of 0.9 to 1.3 X 10(6) and a weight average molecular weight of all poly(C9) complexes of 1,050,000 +/- 40,000 (S.D.). SDS and deoxycholate binding to poly(C9) was measured in an air-driven ultracentrifuge and was determined to be 0.53 +/- 0.065 (S.D.) g of SDS and 0.26 +/- 0.015 (S.D.) g of deoxycholate/g of poly(C9), respectively. Second, the mass of 27 S poly(C9) devoid of bound detergent was determined by electron scattering of unstained specimens in the scanning transmission electron microscope. The molecular weight obtained by this method was 1,078,000 +/- 194,000. The inner diameter of poly(C9) tubules imaged in top view projections by negative staining electron microscopy varied between 9 and 12 mm. The accumulated data suggest a true heterogeneity of the molecular weight of poly(C9) due to polymers with varying protomer numbers. Using a mean value of 73,500 for the molecular weight of monomeric C9, the protomer number of poly(C9) tubules appear to vary between 12 and 18 C9 subunits. Approximately 50-75% of the tubules have 14 to 16 subunits as deduced from the mass distribution determined by electron scattering and from ring size measurements. It is suggested that poly(C9) tubules with various protomer numbers may arise due to limited flexibility in the C9-C9 interaction.

Ultrastructure of the membrane attack complex of complement: detection of the tetramolecular C9-polymerizing complex C5b-8

The ultrastructure of the membrane attack complex (MAC) of complement had been described as representing a hollow cylinder of defined dimensions that is composed of the proteins C5b, C6, C7, C8, and C9. After the characteristic cylindrical structure was identified as polymerized C9 [poly(C9)], the question arose as to the ultrastructural identity and topology of the C9-polymerizing complex C5b-8. An electron microscopic analysis of isolated MAC revealed an asymmetry of individual complexes with respect to their length. Whereas the length of one boundary (+/- SEM) was always 16 +/- 1 nm, the length of the other varied between 16 and 32 nm. In contrast, poly(C9), formed spontaneously from isolated C9, had a uniform tubule length (+/- SEM) of 16 +/- 1 nm. On examination of MAC-phospholipid vesicle complexes, an elongated structure was detected that was closely associated with the poly(C9) tubule and that extended 16-18 nm beyond the torus of the tubule and 28-30 nm above the membrane surface. The width of this structure varied depending on its two-dimensional projection in the electron microscope. By using biotinyl C5b-6 in the formation of the MAC and avidin-coated colloidal gold particles for the ultrastructural analysis, this heretofore unrecognized subunit of the MAC could be identified as the tetramolecular C5b-8 complex. Identification also was achieved by using anti-C5 Fab-coated colloidal gold particles. A similar elongated structure of 25 nm length (above the surface of the membrane) was observed on single C5b-8-vesicle complexes. It is concluded that the C5b-8 complex, which catalyzes poly(C9) formation, constitutes a structure of discrete morphology that remains as such identifiable in the fully assembled MAC, in which it is closely associated with the poly(C9) tubule.

Activation of the fifth and sixth component of the complement system: similarities between C5b6 and C(56)a with respect to lytic enhancement by cell-bound C3b or A2C, and species preferences of target cell

Brief shift of purified C5 and C6 at 0 degrees C to pH 6.4, followed by immediate neutralization, results in the generation of a factor, designated C(56)a, that lyses erythrocytes together with C7, C8, and C9. We compared C(56)a and C5b6 generated by an alternative-pathway convertase, with regard to their action on different target cells. We found tht C(56)a is similar to C5b6 in the following properties: 1) Together with C7, C(56)a forms a stable intermediate on either sheep or guinea pig erythrocytes. 2) Membrane-bound C3b, or A2C incorporated in the membrane, enhances lysis by C(56)a-9, as well as lysis by C5b6-9. We also found that the lysis of EC(56)a7 or EC5b67 intermediates by C8 and C9 depends on the species of the erythrocytes and the species of C8 and C9. Thus, lysis of sheep erythrocytes is more efficient with guinea pig C8 and C9 than with human C8 and C9. In the case of guinea pig erythrocytes, this relationship is reversed, i.e., these cells lyse more efficiently when human C8 and C9 are used. Enhancement of lysis by membrane-bound C3b or A2C does not abrogate this species incompatibility pattern.

Proteolysis of the monomeric and dimeric C5b-9 complexes of complement: alteration in the susceptibility to proteases of the C9 subunits associated with C5b-9 dimerization

The C5b-9 monomer having the sedimentation coefficient of 23S was extracted from the rabbit erythrocyte membranes that had been treated with a limiting amount of C9-deficient human serum and of 125I-C9. Upon proteolysis by trypsin and chymotrypsin, the C9 subunits of this complex were cleaved by these enzymes at multiple sites, yielding fragments with m.w. ranging fro 40,000 to 19,000. The uncomplexed C9 was also cleaved by both enzymes at multiple sites. By contrast, the C9 subunits of the C5b-9 dimer were found to be totally insusceptible to chymotrypsin under the conditions studied (37 degrees C; 24 hr) and only partially susceptible to trypsin (33% of the C9 subunits were cleaved by trypsin into 2 fragments during incubation at 37 degrees C for up to 24 hr). Therefore, these results indicate that, although the binding of C9 molecules to the C5b-8 complex (C5b-9 monomer formation) does not significantly affect the susceptibility to proteases of the C9 molecules, C5b-9 dimer formation markedly limits the accessibility of proteases to the C9 subunit molecules. A implication of this finding to a role for C9 in C5b-9 dimerization is discussed.

Hemolytic complement and its components in Syrian hamsters: a study of five strains uninfected and infected with Brugia pahangi

Complement profiles were tested in outbred (LVG) Syrian hamsters (Mesocricetus auratus) and compared to the MHA, LHC, PD4, and CB inbred strains. The total C and C component concentrations in the sera varied among the strains and were in the following ranges in untreated animals (in CH50 units per ml): total C, 140-260 (undetectable in PD4 and CB); Cl, 14,000-25,000; C2, 200-800 (except PD 4 and CB); C3, 40,000 and 80,000; C4, 2,000-2,800 (except PD4 and CB); C4, 40,000-80,000; C6, 3,600-6,000 (undetectable in PD4 and CB); C7, 50,000-350,000; C8, 10,000-30,000; C9, 30,000-60,000. The PD4 and CB strains had undetectable total C and C6, and their exact C2 and C4 levels could not be determined, but were lower than in the other strains. The MHA strain had the highest total C levels, but had significantly lower (1/3 or less) C7 levels than the other strains of hamsters. Infection of hamsters with the filarid nematode Brugia pahangi for four to five months produced moderate decreases in the total C and C3 levels, but varied changes in other C components. Six infected and three uninfected animals died during the experiment from spontaneous enteritis and weight loss.

Differences in cell-bound C8 sites on chicken erythrocytes measured by their reactivity with guinea pig and human C9

Methods for preparing chicken erythrocytes (CE) with C7 bound to their surface were devised by using either the classical pathway (CEA1-7) or an activated 56hu reagent (CE567) derived from inulin-treated human serum. These intermediates were used to study the lysis of CE by functionally purified C8 and C9 isolated from guinea pig and human serum. The results indicated that GPC9 was less efficient in lysing CEA1-8 or CE5678 than HuC9. This finding was observed irrespective of the species of C8 used. Experiments designed to analyze this difference indicated that there were two functionally distinct forms of C5b-8 that were randomly distributed among the cells but differed in their ability to generate a C lesion depending on the species of C9 used to complete the reaction. The implications of these results on the mechanism of generation of C lesions are briefly discussed.

The terminal membrane C5b-9 complex of human complement. Evidence for the existence of multiple protease-resistant polypeptides that form the trans-membrane complement channel

C5b-9(m) complexes were incorporated into lecithin liposomes and subjected to proteolysis in the presence of DTT to remove the externally oriented annulus. Liposomes were recovered that selectively carried the membrane-bound, thin-walled cylindrical portion of the C5b-9(m) complex. The presence of DTT during proteolysis enhanced peptide bond cleavage in the C5b-9(m) complex. All C5-C9 components were degraded to lower m.w. fragments. A protease-resistant, but hydrophilic 85 to 86,000-dalton polypeptide derivative of C5, possibly representing the C5 beta-chain, was recovered in the fluid phase. This component is not intimately associated with the target lipid bilayer. Immunochemical analyses yielded evidence for the existence of minor C5-C9 antigenic determinants on the membrane-bound C5b-9(m) residue. SDS polyacrylamide gel electrophoreses of liposomes carrying the C5b-9(m) residues revealed the persistence of at least six major polypeptides of approximately m.w. 50,000, 45,000, 40,000, 38,000, 20,000, and 16,000. The data are interpreted to indicate that multiple protease-resistant polypeptide chains derived from several terminal C components participate in formation of the trans-membrane C channel.

Membrane attack complex of complement: a structural analysis of its assembly

This study was conducted to gain insight into the process of assembly of the membrane attack complex (MAC) of complement through structural analysis. Four intermediate complexes and the MAC were examined by electron microscopy and by sucrose density-gradient ultracentrifugation. The C5b-6 complex has a sedimentation rate of 11S, an elongated, slightly curved shape and dimensions of 160 x 60 x 60 A. At protein concentrattions greater than 1 mg/ml, and physiologic ionic strength and pH, the complex forms paracrystals that have the appearance of parallel strands. Equimolar quantities of C5b-6 and C7 mixed in the absence of lipids or detergents give rise to C5b-7 protein micelles which are soluble in aqueous media and have a sedimentation rate of 36S, suggesting a tetrameric composition. Ultrastructurally, C5b-7 protein micelles consist of four half-rings, each measuring 200 x 50 A, which are connected to one another by short stalks extending from the convex side of the half-rings. C5b-7 bound to dioleoyl lecithin (DOL) vesicles has a similar ultrastructural appearance. After extraction with deoxycholate (DOC), C5b-7 has a sedimentation velocity of 36S which further suggests the occurrence of C5b-7 in the form of tetrameric protein micelles. Attachment of C8 to vesicle-bound C5b-7 results in dissociation of the protein micelles. An individual C5b-8 complex appears as a half-ring attached to the DOL-vesicle via a 100-A-long and 30-A-wide stalk. After extraction from the DOL-vesicles with DOC, C5b-8 has a sedimentation velocity of approximately 18S. Binding of C9 to DOL-vesicle bound C5b-8 induces the formation of the typical ultrastructural complement lesions. C5b-9 extracted from the vesicles with DOC has a sedimentation rate of 33S, which is characteristic of the C5b-9 dimer. It is concluded that dimerization is a function of C9. C5b-9 monomers are visualized when a single C5b-9 complex or an odd number of complexes were bound per DOL-vesicle. The C5b-9 monomer has an ultrastructural appearance that is theoretically expected of a half-dimer: a 200- x 50-A half-ring which is attached to the DOL-vesicle by a 100- x 80-A appendage. Extracted with DOC, the C5b-9 monomer has a sedimentation rate of 23S. At a higher multiplicity of MAC per DOL-vesicle, large structural defects in the lipid bilayer are seen which are attributed to direct physical destruction of membranes by the known lipid-binding capacity of the MAC. It is proposed that protein micelle formation at the C5b-7 stage of MAC assembly and dissociation of these micelles upon binding of C8 are events that facilitate dimerization of C5b-9 and thus MAC formation.

The hemolytic equivalence of human, guinea pig and canine complement proteins

The ability of functionally pure human, guinea pig and canine complement proteins to fulfill the hemolytic function of a substituted analagous component in an otherwise totally homogeneous complement sequence was investigated by means of conventional hemolytic assays. A striking feature was the observation that for hemolysis to occur, differing requirements for enzyme-substrate homology were exhibited by each of the three species of C3 and C5 convertases (C3 and C5 CVA). The results suggest that different strategies of molecular interaction evolved in complement systems of different species.

Quantitation of the membrane attack complex of complement in an air-driven ultracentrifuge

A sensitive assay of complement (C) activation via either the classical or alternative pathway was developed by evaluating assembly of the terminal complexes (C5b-9)2 or SC5b-9. Activation of serum containing [125I]C7 resulted in the formation of a stable, radiolabeled complex which was separable from its precursors by sedimentation in an air-driven ultracentrifuge. The radioactivity in the sediment was directly proportional to the amount of complex formed and assembly of the complex could be detected after C activation by aggregated IgG in concentrations as low as 10 micrograms/ml. Mild detergents such as Triton X-100 could be included in the reaction mixture, because they affected neither the assembly nor the integrity of the complexes. The assay, which detects both assembly of the membrane attack complex (MAC or (C5b-9)2) on target membranes and formation of SC5b-9 in fluid phase, measures the potential of certain substances to trigger the cytolytic phase of C regardless of whether the classical or alternative pathway was activated. However, by using serum depleted of either factor B or C1q, activation of either pathway can be assessed individually.

[Action of complement in normal pregnancy and gestosis]

Behaviour of the complement system was studied in normal pregnancy, puerperium and in pre-eclampsia. CH50 showed no variations during normal pregnancy, excepting for first trimester, whereas it increased in puerperium. CVFAH50 increased steadily during all trimesters. C1q, C1s and C1-INH progressively decreased, while C3, C5, C9 and C3PA augmented. All values were clearly raised in puerperium. The decreased values of the early classical pathway components could be attributed to "blocking factors" (antibodies or immune-complexes) which could interfere with cellular immunity at fetoplacental level. The other components probably increase because there is a hormone-stimulated raised synthesis and a high turnover. The data obtained from pre-eclampsia did not reveal significant variations as compared to normal third trimester pregnancy, excepting for CVFAH50 which was reduced. This, however, does not exclude the possibility that there is an immunological pathogenesis of the pre-eclampsia, since activation of the C system is not always detectable in circulation.

Complement lysis: evidence for an amphiphilic nature of the terminal membrane C5b-9 complex of human complement

The terminal, membrane-derived C5b-9 complex of human complement (C) is an apparently hollow, cylindrical macromolecule vertically oriented on the target membrane. In the present study, an antiserum to the complex has been used to probe its immunobiochemical properties. "Neoantigenic" determinants characteristic of the complex have been detected, which are absent on native C5-C9 molecules. Evidence that the C5b-9 complex is an amphiphilic molecule that possesses apolar, detergent-binding surfaces has been obtained by using charge-shift crossed immunoelectrophoresis, and by direct demonstration of Triton X-100 binding to the complex in quantitative immunoelectrophoresis. By the same criteria, serum C5, C6, and C9 are hydrophilic molecules. The results indicate that assembly of C5-C9 into the terminal membrane C5b-9 complex is accompanied by conformational changes in the individual C components that lead to the exposure of apolar molecular regions in the complex. It is proposed that this constitutes the basis for the lipid-binding properties of the macromolecule, which enable it to become inserted into biologic and artificial lipid membranes with apparent generation of a transmembrane pore.

Steady-state analysis of tracer exchange across the C5b-9 complement lesion in a biological membrane

Resealed erythrocyte ghosts have been used to define the kinetics of tracer exchange across the membrane-bound terminal complex of the complement cascade (C5b-9). Under steady-state conditions and at net chemical equilibrium, C5b-9 ghosts showed no significant lysis above control levels as measured by hemoglobin efflux. In 1 mM sucrose at 37 degrees C, [14C]sucrose isotopic exchange diffusion into C5b-9 ghosts occurred at 4.8 (+/- 0.5, SEM) X 10(-20) mol sec-1 per functional lesion, equivalent to an apparent permeability coefficient of 4.8 X 10(-14) cm3 sec-1 for the single C5b-9 lesion. No significant uptake of [14C]sucrose above control levels was observed in C5b67 ghosts. The apparent rate of tracer permeation through the complement lesion is one to two orders of magnitude slower than predicted by a model of a transmembrane channel of dimensions permitting free diffusion of sucrose. The data support earlier assertions from this laboratory that diffusion of small molecules across the complement lesion in biological membranes is significantly restricted.

Studies on the terminal stages of immune hemolysis. III. Distinction between the insertion of C9 and the formation of a transmembrane channel

The intermediate product EAC1-8 released cytoplasmic components as a result of at least two sequential reactions after its interaction with C9. Binding of C9 to EAC1-8 occurred in a few minutes even at 0 degrees C. Trypsinization of EAC1-9 prepared and held at low temperature resulted in nullification of the potential hemolysis of these cells. A brief incubation at 30 or 37 degrees resulted in the formation of an intermediate whose hemolytic potential could not be nullified by trypsin. The failure of trypsin to nullify hemolysis was attributed to the insertion of C9 into the cell membrane. Studies on the effec of EDTA or low temperature suggested that the reported temperature-dependent step in E* formation described by Frank et al. was the insertion of C9. The results of the studies with 86Rb-labeled EAC1-8 indicated that a transmembrane channel was not formed until after the C9 had been inserted and a further reaction or reactions had occurred.

Differences in the terminal steps of complement lysis of normal and paroxysmal nocturnal hemoglobinuria red cells

The number of microscopically visible lesions produced on the membrane for a given degree of lysis on normal cells as on PNH cells. Since complement lesions were not formed until C8 or C9 was incorporated into the complement sequence, the results suggest that increased lysis of red cells in PNH is due at least in part to more efficient penetration of the PNH membrane by the terminal lytic sequence of complement. Furthermore, the efficiency of the terminal lytic sequence in the lysis of PNH cells when complement was activated by the alternative pathway and the classical pathway was analyzed. There was no significant difference (p less than 0.01) in the number of lesion present at an equivalent degree of lysis when initiated by antibody, cobra venom factor, or acidification. Thus, the efficiency of the terminal lytic sequence does not vary with different modes of activation.

Serum complement profile in human leprosy and its comparison with immune complex diseases

In the present study we have estimated the serum levels of early, middle, and distal complement components, e.g., Clq, C3, C4, C5, C8, and C9 along with C1-inactivator and CH50 in patients with tuberculoid and lepromatous leprosy and have compared these results with the levels in healthy subjects as well as with levels in patients with other immune complex diseases. We have also analyzed the cryoglobulins present in the sera of these patients; they consisted of either a single or mixed IgG, IgA, IgM or fibrinogen in most instances. The component C3 was found in only one sample. It appears that unlike lupus nephritis, in which complement is activated by direct path in which complement is activated by direct path in about 30% to 50% of leprosy patients, significant C3 complement consumption takes place primarily via the alternate pathway and is probably initiated by the aggregated immunoglobulins represented in cryoprecipitates. This is further supported by the study of serum factor B and its breakdown product (Ba) in these patients. The question of the role of the middle and distal complement components, such as C5, C8 and C9, during total hemolytic complement and C3 consumption in leprosy remains unanswered.

Lytic activity of C5-9 complexes for erythrocytes from the species other than sheep: C9 rather than C8-dependent variation in lytic activity

With the reactive lysis system, a form of hemolysis mediated solely by the late-acting complement components (C56, C7, C8, and C9), guinea pig C9 (C9gp) was found to be very inefficient in inducing the lysis of guinea pig and mouse erythrocytes bearing human C5-8. By contrast, C9gp could efficiently induce the lysis of sheep and goat erythrocytes bearing human C5-8. By contrast, C9gp could efficiently induce the lysis of sheep and goat erythrocytes bearing human C5-8. Human C9 was efficient in the lysis of erythrocytes from the species mentioned above. Further study showed: 1) the observed inefficiency in the lysis of guinea pig erythrocytes was not due to incompatibility between human C7 or C8 and C9gp; 2) C9gp could efficiently bind to guinea pig erythrocytes bearing human C5-8 but was inactive in the subsequent lytic process. The present finding emphasizes a role for C9 in complement-mediated membrane damage which may not be a simple effector function of C8 action.

[Herpes gestationis. Immunopathologic studies in mother and child]

Herpes gestationis is a nosologically undefined uncommon bullous disease in pregnancy. In a patient with herpes gestationis C3, C5 und C9 deposits could be demonstrated by immunohistological methods at the epidermal basement membrane (BM). Deposits of immunoglobulins, properdin and C3PA were absent. Autoantibodies against BM were found in the serum of the mother by using rabbit oesophagus but not with normal human skin as antigen. In the sera of mother and child a factor could be demonstrated which in vitro leads to complement fixation in human epidermal BM. Immunopathological findings may speak in favor of a nosological entity of herpes gestationis with respect to dermatitis herpetiformis and bullous pemphigoid.

Deviated lysis: Transfer of complement lytic activity to unsensitized cells II. Generation of the activity by inulin and by antigen antibody complexes

Deviated lysis (d.l.) activity, i.e. lysis of unsensitized cells by lytic C activity, was generated via the classical pathway of Cactivation (ag ab complexes) and via the alternative pathway (inulin). The activity was observed on the surface of the activating particles and in the fluid phase. The activity was relatively stable at 32 degrees C. Its generation involved the C components C6 through C9 and possibly also C5.

Trypsin-activated complex of human factor B with cobra venom factor (CVF), cleaving C3 and C5 and generating a lytic factor for unsensitized guinea pig erythrocytes. I. Generation of the activated complex

A complex formed between cobra venom factor (CVF) and isolated human factor B (B) was found to be converted by trypsin to a stable enzyme, CVF-B which cleaved the third component (C3) and the fifth component (C5) of human complement. The formation of CVF-B by trypsin required divalent cations, whereas the formation of the lytic factor from human serum occurred even in the presence of EDTA. CVF-B purified by gel filtration could initiate the hemolysis of unsensitized guinea pig erythrocytes when incubated with human complement components C5 to C9 in 0.01 M EDTA buffer. C3 was not required for the lysis of guinea pig erythrocytes initiated by CVF-B because of the beta1C precipitation line formed between human serum and anti-beta1C antibody did not inhibit the hemolysis by CVF-B in agarose gel. Treatment of beta1C and beta1F globulins in whole human serum with CVF-B in the presence of 0.01 M EDTA converted them to components with higher mobilities on immunoelectrophoresis.

On the mechanism of cytolysis by complement: evidence on insertion of C5b and C7 subunits of the C5b,6,7 complex into phospholipid bilayers of erythrocyte membranes

The doughnut hypothesis of cytolysis by complement [Mayer, M. M. (1972) Proc. Nat. Acad. Sci. USA 69, 2954-2958] describes an annular structure made up of C5b-9 (complement factors C5b, C6, C7, C8, and C9) which becomes inserted in the lipid bilayer of the cell membrane, thus creating a hole. We now present initial explorations of this hypothesis. EAC1-6 and EAC1-7 (sheep erythrocytes carrying rabbit antibody and complement factors C1 through C6 or C1 through C7, respectively), prepared with either 125I-C3 or 125I-C5 were incubated with trypsin and the release of bound 125I was measured. In the case of 125I-C3, all of the radioactivity was released by trypsin from both intermediates. With 125I-C5, trypsin released all of the 125I from EAC1-6, but only 40-55% from EAC1-7. Possible reasons for resistance of the C5b subunit in EAC1-7 to tryptic digestion are discussed; in terms of the doughnut hypothesis it would be due to shielding by lipid molecules as a consequence of insertion into the lipid bilayer. In accord with this interpretation we have also found that C5b in EAC1-7, but not in EAC1-6, resists elution by 0.3 M NaC1. Similarly, we have found that 125I-C7 in EAC1-7 resists stripping by trypsin. Hence, we now propose the hypothesis that hydrophobic polypeptide chains from the C5b and the C7 subunits of C5b,6,7 complex become inserted in the phospholipid bilayer and that subsequent reactions with C8 and C9 open a channel across the membrane.

Extracorporeal immunoadsorption of circulating specific serum factors in cancer patients

Circulating serum factors have been said to abrogate the effects of immune response in cancer, i.e. "blocking" and "antigenic inhibition". The aim of this investigation was to isolate such specific factors in a purified and native state. F(ab)2 fragments isolated from hypernephroma were insolubilized on the surfaces of an extracorporeal perfusion chamber which was inserted into the circulation by means of an arterio-venous shunt. As a result, 3 proteins not present in normal serum were isolated and eluted for further study. In immunoelectrophoresis the 3 proteins were specifically precipitated by heterolgous (rabbit) antihypernephroma serum but not by anti-serum directed against normal serum components. Moreover C9 components, C3 activator and C3 were isolated in the chamber, the latter complement factor in large concentrations. This further sustained that specific antigen-antibody reactions had occurred in the chamber. One of the 2 patients studied were perfused for 60 h and 40 min. During this period 450 litres of blood were brought into intimate contact with the immunoadsorbent. Proteins in amounts sufficient for immunochemical analysis were isolated within 3 h.