Human blood platelets possess specific binding sites for C1q

Although platelet interactions with C1q are implied by the inhibitory effect of C1q on collagen-induced platelet aggregation, specific receptors have not as yet been identified. To address the question of platelet receptors for free C1q, direct radioligand binding studies were performed by using human blood platelets and purified, 125I-labeled C1q, and a monoclonal antibody (II1/D1) (IgM, lambda) directed against C1q receptors on peripheral blood leukocytes. Washed platelets bound both purified 125I-labeled C1q and II1/D1 in a specific and saturable manner under physiologic ionic strength conditions. At equilibrium, approximately 4000 molecules of C1q bound per platelet with an apparent dissociation constant of 3.5 X 10(-7) M. Maximum C1q binding was achieved in 5 min and correlated well with inhibition of collagen-induced platelet aggregation. Equilibrium binding of 125I-labeled II1/D1 to washed platelets required an incubation period of 15 to 30 min and II1/D1 concentrations approaching 50 micrograms/ml. Approximately 2000 molecules of II1/D1 bound per platelet, with an apparent dissociation constant of 2.8 X 10(-8) M. II1/D1 binding could be inhibited by the collagenous tail of C1q (c-C1q), suggesting that platelet receptors for these ligands are either the same or in close proximity. The data demonstrate that human blood platelets possess specific and saturable binding sites for free C1q that may function as collagen receptors, and may antigenically resemble C1q receptors on peripheral blood leukocytes.     

A monoclonal antibody to C1q which appears to interact with C1r2C1s2-binding site

A monoclonal antibody (SB-4) to human C1q was prepared. The equilibrium constant of the antibody for C1q was found to be greater than 10(10) M-1. It has been shown that the antibody binds to the A-B chain dimer, probably via the B chain of C1q. Pepsin digestion of C1q at pH 4.5, which fragments the globular regions but leaves the collagenous region intact, allowed the demonstration that the antigenic site is located in the collagenous region of the molecule. The effect of the antibody on haemolytic activity has shown that it is capable of inhibiting the formation of EAC1 cells from EAC1q cells plus C1r and C1s but is incapable of inhibiting the C1 activity of performed EAC1 cells. This indicates that the binding of the antibody to the collagenous portion of the B chain of C1q probably prevents interaction between C1q and the C1r2-C1s2 complex.     

Characterization of functional properties of C4-binding protein by monoclonal antibodies

We prepared mouse monoclonal antibodies to human C4-binding protein (C4-bp) by fusing spleen cells from mice immunized with purified C4-bp to the mouse myeloma line P3U1. Of four monoclonal antibodies that reacted with intact C4-bp, two were specific for a 48K fragment, one of the chymotryptic cleavage products of C4-bp, and one was specific for another fragment (160K). The fourth monoclonal antibody did not react with either fragment. One of the monoclonals that reacted with the 48K fragment blocked the binding of C4-bp to cell-bound C4b. This monoclonal antibody (TK3) also inhibited two other functions of C4-bp, serving as an essential cofactor for C3b/C4b inactivator (I) in the cleavage of fluid-phase C4b and accelerating the decay of C2a from the C4b,2a complex. The other monoclonals had little or no effect on these activities of C4-bp. In addition, we found that the 48K fragment lost the binding affinity for C4b. However, it can function as a cofactor for I and as a decay-accelerator, although its activities were about 200 times weaker than intact C4-bp on a molar basis. The monoclonal antibody TK3 completely inhibited these activities of the 48K fragment. On the basis of these findings, we conclude that the functionally active site of C4-bp is located on the 48K fragment. Probably, the cofactor and decay-accelerating activities of C4-bp result from the binding of C4-bp to C4b.     

Platelet C1q receptor interactions with collagen- and C1q-coated surfaces

We recently described specific binding sites for C1q on human blood platelets. Structural similarities between the amino-terminal of C1q and collagen have suggested that receptors for both molecules on platelets might be the same. The present study thus compared the interaction of purified C1q receptors (C1qR) and whole platelets with collagen- and C1q-coated polystyrene surfaces. Surfaces coated with BSA or gelatin served as controls. Purified 125I-labeled C1qR recognized both C1q- and collagen-coated surfaces in a divalent, cation-independent manner. This adhesion was inhibited by polyclonal or monoclonal (II1/D1) anti-C1qR antibodies. Although C1qR adhered preferentially to C1q-coated surfaces, adhesion to bovine and human type I collagen, as well as to human type III and V collagen, was also noted. In parallel studies, 51Cr-labeled platelets bound equally well to collagen- or C1q-coated surfaces, albeit in a magnesium-dependent manner. Partial inhibition of platelet adhesion was observed in the presence of RGDS, despite the inability of RGDS to modify C1qR interaction with C1q or collagen. Moreover, anti C1qR antibodies selectively inhibited platelet adhesion to C1q-coated surfaces, whereas antibodies specific for the GPIa/IIa collagen receptor (6F1) preferentially inhibited platelet collagen interactions. These data support the presence of distinct platelet membrane C1qR, which may cross-react with collagen, and suggest that C1qR are necessary but not sufficient for platelet adhesion to C1q-coated surfaces. Additional divalent cation and/or RGD-sensitive binding sites may participate.     

Measurement of macromolecular interactions between complement subcomponents C1q, C1r, C1s, and immunoglobulin IgM by sedimentation analysis using the analytical ultracentrifuge

The interactions between the complement components and with immunoglobulins are greatly enhanced by lowering the ionic strength and become readily measurable by physical techniques. Thus, the binding between C1q and IgM was previously shown to be appreciable (k = 1 x 10(6) M-1) at 0.084 M ionic strength (Poon, P.H., Phillips, M.L., and Schumaker, V.N. (1985) J. Biol. Chem. 260, 9357-9365). We have now found that, at 0.128 M ionic strength, the binding between human C1- (the activated first component of complement) and IgM was strong at physiological concentrations (k = 1 x 10(7) M-1), while under the same conditions binding between C1q and IgM was not observed. To explore the nature of the interactions responsible for this enhanced binding by C1- over C1q, mixtures of the various subcomponents of C1- were studied alone and with IgM. C1r2 did not bind to C1q, even when the ionic strength was reduced to 0.098 M, nor did the presence of C1r2 enhance the binding of C1q to IgM. In contrast, two C1s2 independently bound to C1q (k = 1 x 10(6) M-1), and caused a marked increase in its association with IgM (k = 5 x 10(6) M-1) at 0.098 M ionic strength. No detectable interaction was found between C1s2 and/or C1r2 and IgM in the absence of C1q. Moreover, there was no detectable interaction between the C1(-)-like complex formed between C1r2C1s2 and the collagenous C1q stalks (pepsin-digested C1q) and IgM. These data suggest that the binding of C1s2 to C1q, either alone or together with C1r2, induces a conformational change in C1q which results in additional C1q heads binding to complementary sites on IgM.     

C1q binding and C1 activation by various isolated cellular membranes

Cellular and subcellular membranes obtained from heart, liver, and brain tissue from human, baboon, bovine, rabbit, and rat bound highly purified, radioiodinated human C1q with a high affinity (Ka = 10(8) to 10(10) M-1). The majority of these membrane preparations were able to activate fully assembled C1 as evidenced by the conversion of 125I-C1s, incorporated into C1 complexes, to 125I-C1s. C1 activation by baboon heart mitochondrial membranes required an intact C1 complex and appeared to be mediated by the binding of the C1q subcomponent in that excess C1q completely blocked C1 activation. Several experiments suggested that the heart mitochondrial membrane binding site for C1q is an integral component of the mitochondrial membrane and that C1q interacted with the membrane binding site through its globular head regions. It is suggested that the binding of C1q and the activation of C1 by cellular and subcellular membranes may be involved in the initiation and/or enhancement of the inflammatory process after acute tissue damage.     

Activation of the first component of human complement, C1, by monoclonal antibodies directed against different domains of subcomponent C1q

Two monoclonal antibodies directed against C1q, and their (Fab)2 and Fab fragments, were used to study the mechanism of C1 activation. Monoclonal antibody 2A10, an IgG2a, was digested by pepsin to yield fully immunoreactive (Fab')2. Monoclonal antibody 1H11, an IgG1, was digested by papain to yield fully immunoreactive, bivalent (Fab)2. Previously 1H11 had been shown to bind to the C1q "heads," whereas 2A10 bound to stalks. Activation of C1 was followed by the cleavage of 125I-C1s in the presence of C1 inhibitor (C1-Inh) at 37 degrees C. Spontaneous activation was minimal at inhibitor concentrations above 0.4 micron (1.3 X physiologic inhibitor concentration); all results were corrected for the spontaneous activation background. Heat-aggregated IgG activated completely in this system and was taken as 100% activation. Monoclonal antibody 2A10 caused precipitation of C1 and slow activation; neither the (Fab')2 nor the Fab' derived from 2A10-caused activation. Probably, aggregates of intact 2A10 and C1 were serving as immune complexes to activate other molecules of C1. In contrast, both 1H11 and its (Fab)2 activated completely and stoichiometrically; that is, maximal activation was achieved at a ratio of one C1q head to one antibody combining site. The monovalent Fab derived from 1H11 bound well to C1q, but no activation of C1 was observed. Thus, bivalent binding of this head-binding monoclonal is required for C1 activation, but not the presence of the antibody Fc portion. Neither 1H11 nor its (Fab)2 fragments caused C1 precipitation; however, the 1H11 did form complexes composed of two C1q cross-linked by multiple 1H11, which were visualized by electron microscopy. The presence of these dimeric complexes correlated well with activation. A model for C1 activation is proposed in which two C1q subcomponents are held together by multiple (Fab)2 bridging C1q heads. The model is roughly analogous to touching opposing pairs of fingers and thumb tips, the two hands representing the two C1q, forming a cage. C1-Inh, which probably binds to C1r through the open end of the C1 cone, is too long asymmetric to be included within the cage. Thus, according to this model, the dimers of C1 are released from the inhibitory action of C1-Inh, and activation proceeds spontaneously and rapidly at 37 degrees C.     

Fibronectin binding to complement subcomponent C1q. Localization of their respective binding sites.

The interaction of purified human plasma fibronectin with the C1q subcomponent of complement was investigated by using a solid-phase radiobinding assay. 125I-fibronectin binding to native C1q, purified collagen domain (C1q-c) or globular domain (C1q-g) was compared. When the purified domains were insolubilized by binding to plastic, the C1q-c exhibited 59% of the binding demonstrated with intact C1q, whereas the C1q-g exhibited 35% of the binding. N-Terminal sequencing of the globular domain showed that a sequence of seven collagen-like amino acids was retained on each chain of the C1q-g fragment. 125I-fibronectin binding to C1q could be inhibited equally well by fluid-phase C1q and C1q-c, but not by fluid-phase C1q-g, implying that the collagen-like region retained on the C1q-g is masked in the fluid phase. In addition, studies were performed to determine which subunit(s) of C1q bind(s) fibronectin. The percentages of fibronectin bound by the A, B, and C chain of C1q were found to be 38, 21 and 41% respectively. Inhibition studies with purified 200-180 kDa, 50 kDa or 29 kDa fragments of fibronectin show that the binding site on fibronectin for C1q is the 50 kDa gelatin-binding domain.     

Production and characterization of a murine monoclonal IgM antibody to human C1q receptor (C1qR)

A hybridoma cell line that produces a monoclonal antibody (MAb) to cell surface C1q receptor (C1qR) has been produced by fusion of the P3 X 63-Ag8.653 mouse myeloma cell line with the spleen cells of a CD-1 mouse that had been hyperimmunized with viable Raji cell suspensions (5 X 10(7) cells/inoculum). This MAb, designated II1/D1, is an IgM antibody with lambda-light chain specificity. Radiolabeled or unlabeled, highly purified II1/D1 was used to determine that: this antibody competes for C1q binding sites on C1qR-bearing cells; the molecule recognized by this MAb is the C1qR; and cells that are known to bind C1q also bind II1/D1 in a specific manner. Western blot analysis of solubilized Raji, or U937 cell membranes, showed that the 125I-MAb detected a major protein band of approximately 85,000 m.w. in its unreduced state, indicating that the C1qR is similar, if not identical, in both types of cells. Analyses of 125I-II1/D1 binding experiments revealed that the antibody bound to Raji cells or U937 cells in a specific manner. Uptake of the antibody was saturable, with equilibrium virtually attained within 35 min. Scatchard analysis of the binding data using the intact MAb suggests that the affinity constant KD is 2.9 X 10(-10) M, and at apparent saturation, 24.6 ng of the antibody were bound per 2 X 10(6) cells, giving an estimated 7.8 X 10(3) antibody molecules bound per cell. That the II1/D1 antibody is specifically directed to the C1q was further evidenced by an ELISA in which the ability of C1qR-bearing cells to bind the MAb was abrogated by c-C1q in a specific and dose-dependent manner. These results indicate that the II1/D1 is a specific antibody directed against the C1q and can be a useful tool in studying the biologic interaction of human C1q with its receptors on a variety of cells.     

Monoclonal antibodies to human protein C: effects on the biological activity of activated protein C and the thrombin-catalyzed activation of protein C1

Thirteen monoclonal antibodies designated as MFC-1 to MFC-13 were obtained from hybridoma cells cloned after the fusion of mouse myeloma cells with spleen cells of mice immunized with purified human protein C. Studies were made to determine where the antibodies bound to the molecule of protein C and whether they affected the biological actions of protein C. By using the immunoblotting technique, six of these antibodies were shown to bind to the light chain of protein C, and five to the heavy chain of protein C and also activated protein C. The remaining two antibodies bound to neither the light chain nor the heavy chain, though both antibodies bound to the intact protein C. Antibodies specific for the light chain did not bind to the gamma-carboxyglutamic acid-domain. Two of the antibodies specific for the heavy chain (MFC-13 and -1) inhibited the amidolytic activity of activated protein C. The MFC-13 also inhibited the activity of bovine activated protein C, but not that of human Factor IXa, Factor Xa, or thrombin. In addition to these two antibodies, another one for the heavy chain (MFC-10) and two antibodies for the light chain (MFC-9 and -11) inhibited the inactivation of Factor Va by human activated protein C. One of the antibodies which inhibited the enzyme activity (MFC-1) blocked the inhibition of activated protein C by protein C inhibitor. Another one for the heavy chain (MFC-5) inhibited the activation of protein C by thrombin regardless of the presence or absence of thrombomodulin. Based on these results, we have established the positions of some monoclonal antibody-binding sites on the protein C molecule.     

Isolation and function of a human endothelial cell C1q receptor

It has been shown previously that cultured human venous and arterial endothelial cells (EC) bind C1q in a time- and dose-dependent manner. Cultured human endothelial cells express an average number of 5.2 x 10(5) binding sites/cell. In the present study the putative receptor for C1q (C1qR) was isolated from the membranes of 1-5 x 10(9) human umbilical cord EC by affinity chromatography on C1q-Sepharose. During isolation, C1qR was detected by its capacity to inhibit the lysis of EAC1q in C1q-deficient serum. The eluate from C1q-Sepharose was concentrated, dialysed and subjected to QAE-A50 chromatography and subsequently to gel filtration on HPLC-TSK 3000. C1qR filtered at an apparent molecular weight of 60 kDa. Purified C1qR exhibited an apparent molecular weight of 55-62 kDa in the unreduced state and a molecular weight of 64-68 kDa in reduced form. Two IgM monoclonal antibodies (mAb) D3 and D5 were raised following immunization of mice with purified receptor preparations. Both monoclonal antibodies increased the binding of (125)I-C1q to endothelial cells but F(ab')(2) anti-C1qR mAb inhibited the binding of a(125)I-C1q to EC in a dosedependent manner. The D3 mAb recognized a band of 54-60 kDa in Western blots of membranes of human EC and polymorphonuclear leukocytes. Previously, the authors showed that C1q induces the binding of IgM-containing immune complexes to EC. Therefore, it was hypothesized that during a primary immune response generation of IgM-IC may occur, resulting in binding and activation of C1, dissociation of activated C1 by C1 inhibitor and subsequent interaction of IgM-IC bearing C1q with EC-C1qR.     

Production and characterization of monoclonal antibodies against the two subunits proteins B1 and B2 of Escherichia coli ribonucleotide reductase

Ribonucleotide reductase from Escherichia coli consists of two nonidentical subunits, named protein B1 (170 000) and protein B2 (87 000). We purified and characterized five monoclonal antibodies against B1 and three against B2 from hybridomas obtained by fusion of spleen cells from immunized mice and the myeloma cell line P3-X63Ag8. All are of the IgG1 class with a high affinity for the antigen with dissociation constants in the nanomolar range. Four of the anti-B1 monoclonals and all three anti-B2 monoclonals neutralize reductase activity while one anti-B1 monoclonal binds tightly to B1 without affecting its activity. Fab fragments prepared from three anti-B1 monoclonals had similar dissociation constants. The anti-B1 monoclonals interacted with separate epitopes while two of the anti-B2 monoclonals appeared to react with the same epitope. In the case of B1, various allosteric states of the protein induced by binding of effectors had no apparent effect on the interaction with monoclonals, nor did their binding prevent subsequent binding of effectors. With B2, binding of monoclonals did not affect the typical electron paramagnetic resonance spectrum of the protein and thus did not involve either the tyrosyl free radical or the iron center of B2. All neutralizing antibodies interfered with the interaction between the two subunits, explaining their effect on enzyme activity, since active ribonucleotide reductase consists of a B1-B2 complex.     

Interaction between complement subcomponent C1q and bacterial lipopolysaccharides.

The heptose-less mutant of Escherichia coli, D31m4, bound complement subcomponent C1q and its collagen-like fragments (C1qCLF) with Ka values of 1.4 x 10(8) and 2.0 x 10(8) M-1 respectively. This binding was suppressed by chemical modification of C1q and C1qCLF using diethyl pyrocarbonate (DEPC). To investigate the role of lipopolysaccharides (LPS) in this binding, biosynthetically labelled [14C]LPS were purified from E. coli D31m4 and incorporated into liposomes prepared from phosphatidylcholine (PC) and phosphatidylethanolamine (PE) [PC/PE/LPS, 2:2:1, by wt.]. Binding of C1q or its collagen-like fragments to the liposomes was estimated via a flotation test. These liposomes bound C1q and C1qCLF with Ka values of 8.0 x 10(7) and 2.0 x 10(7) M-1; this binding was totally inhibited after chemical modification of C1q and C1qCLF by DEPC. Liposomes containing LPS purified from the wild-strain E. coli K-12 S also bound C1q and C1qCLF, whereas direct binding of C1q or C1qCLF to the bacteria was negligible. Diamines at concentrations which dissociate C1 into C1q and (C1r, C1s)2, strongly inhibited the interaction of C1q or C1qCLF with LPS. Removal of 3-deoxy-D-manno-octulosonic acid (2-keto-3-deoxyoctonic acid; KDO) from E. coli D31m4 LPS decreases the binding of C1qCLF to the bacteria by 65%. When this purified and modified LPS was incorporated into liposomes, the C1qCLF binding was completely abolished. These results show: (i) the essential role of the collagen-like moiety and probably its histidine residues in the interaction between C1q and the mutant D31m4; (ii) the contribution of LPS, particularly the anionic charges of KDO, to this interaction.     

Binding and complement activation by C-reactive protein via the collagen-like region of C1q and inhibition of these reactions by monoclonal antibodies to C-reactive protein and C1q

Ligand-complexed C-reactive protein (CRP), like aggregated or complexed IgG, can react with C1q and activate the classical C pathway. Whereas IgG is known to bind to the globular region and not to the collagen-like region (CLR) of C1q, the site of interaction of C1q with CRP has not been defined. CRP-trimers were prepared by cross-linking and found to bind to C1q and to activate the C system. Heat-aggregated IgG (Agg-IgG) did not block the binding of CRP-trimers to C1q, nor did CRP-trimers block binding of Agg-IgG to C1q, suggesting that CRP and IgG bind at different sites. ELISA and Western blot analysis showed that CRP-trimers bound to the CLR, whereas Agg-IgG bound only to the globular region; similarly, anti-CLR mAb inhibited binding of CRP-trimers to C1q whereas anti-globular region mAb did not. Reactivity with CRP-trimers as well as with Agg-IgG was retained after reduction/alkylation and SDS treatment of C1q. A group of 22 anti-CRP mAb directed against at least six distinct native-CRP epitopes and eight distinct neo-CRP epitopes was tested for ability to inhibit the CRP-CLR interaction; one mAb, anti-native CRP mAb 8D8, with strong inhibitory activity was identified. Fab' of 8D8 blocked binding of CRP-trimers to intact C1q as well as CLR, and also inhibited CRP (CRP-trimers and CRP-protamine complexes) induced C activation, but had no effect on C1q binding or C activation by Agg-IgG. These results indicate that a conformation-determined region on CRP binds to a sequence-determined region on the CLR of C1q in an interaction which leads to C activation. Anti-CRP and anti-C1q mAb that specifically inhibit this interaction are described.     

C1q Protein Binds to the Apoptotic Nucleolus and Causes C1 Protease Degradation of Nucleolar Proteins

In infection, complement C1q recognizes pathogen-congregated antibodies and elicits complement activation. Among endogenous ligands, C1q binds to DNA and apoptotic cells, but whether C1q binds to nuclear DNA in apoptotic cells remains to be investigated. With UV irradiation-induced apoptosis, C1q initially bound to peripheral cellular regions in early apoptotic cells. By 6 h, binding concentrated in the nuclei to the nucleolus but not the chromatins. When nucleoli were isolated from non-apoptotic cells, C1q also bound to these structures. In vivo, C1q exists as the C1 complex (C1qC1r₂C1s₂), and C1q binding to ligands activates the C1r/C1s proteases. Incubation of nucleoli with C1 caused degradation of the nucleolar proteins nucleolin and nucleophosmin 1. This was inhibited by the C1 inhibitor. The nucleoli are abundant with autoantigens. C1q binding and C1r/C1s degradation of nucleolar antigens during cell apoptosis potentially reduces autoimmunity. These findings help us to understand why genetic C1q and C1r/C1s deficiencies cause systemic lupus erythematosus.     

Characterization of two monoclonal antibodies reactive with the external domain of the platelet-derived growth factor receptor

Two monoclonal antibodies against the receptor for platelet-derived growth factor (PDGF) were obtained by immunizing mice with pure PDGF receptor preparations derived from porcine uterus. The antibodies, denoted PDGFR-B1 and PDGFR-B2, both bound to the external domain of the receptor, as demonstrated by indirect immunofluorescence and binding of 125I-labeled antibodies to intact human fibroblasts. Both antibodies precipitated pure 175-kDa 32P-labeled autophosphorylated porcine PDGF receptor as well as a Mr 175,000 glycoprotein from metabolically labeled cells. The monoclonal antibodies did not inhibit binding of 125I-PDGF to human fibroblasts and did not stimulate these cells to undergo mitosis. Both antibodies induced clustering and down-regulation of their antigen. However, this resulted in only a partial loss of cell surface binding sites for PDGF itself, consistent with the conclusion that the monoclonals recognized only one of two or several receptors for PDGF. Clustering and down-regulation were not seen when the cells were incubated with monovalent Fab' fragments of the PDGFR-B2 antibody. The antibodies also stimulated autophosphorylation of pure PDGF receptor, and PDGFR-B2 was shown to stimulate phosphorylation of phosphofructokinase, an exogenous substrate for the PDGF receptor kinase. High concentrations of PDGFR-B2 antibody, or Fab' fragments thereof, failed to enhance the PDGF receptor kinase activity, compatible with the possibility that dimerization was of importance in the antibody-stimulated kinase activity of purified PDGF receptors.     

IgG subclass specificity to C1q determined by surface plasmon resonance using Protein L capture technique

Recombinant monoclonal antibodies (mAbs) have become an important category of biological therapeutics. mAbs share the same structures and biological functions as endogenous IgG molecules. One function is complement-dependent cytotoxicity (CDC) initiation by binding of C1q. Traditionally, ELISA methods have been utilized to measure C1q binding. A new robust capture method was established in this study to measure the binding affinity of C1q to antibodies by surface plasmon resonance (SPR). The utility of this method was demonstrated by determination of the difference in IgG subclass specificity of C1q binding.     

Conformational changes in C1q after binding to immune complexes: detection of neoantigens with monoclonal antibodies

The formation of neoantigens within the C1q molecule after the binding of C1r and C1s to C1q and the binding of C1q to immune complexes is described. The neoantigens were detected by different monoclonal anti-C1q antibodies. This immunochemical study supports the hypothesis drawn from functional studies that the activation of the classical C pathway results from conformational changes within the C1q molecule leading to the activation of C1r and subsequently C1s.     

Monoclonal antibodies specific to porin of Haemophilus influenzae type b: localization of their cognate epitopes and tests of their biological activities

The major outer membrane protein of Haemophilus influenzae type b (Hib) is porin (Mr 38,000, 341 amino acids). To identify antigenic determinants on Hib porin that might be exposed at the bacterial cell surface, seven mouse monoclonal anti-Hib porin antibodies were generated. The monoclonal antibodies were tested for their binding to intact cells by flow cytometry; all but one bound to the cell surface. Digestions of Hib porin with cyanogen bromide, hydroxylamine or trypsin generated fragments, the identities of which were confirmed by microsequencing of the amino termini. Following electrophoresis and immunoblotting of the fragments, the specificities of the monoclonal antibodies for their cognate sequences were determined. The porin gene ompP2 was expressed in the baculovirus expression vector system; the recombinant porin was recognized by all of the monoclonal antibodies. Deletions were created by omega mutagenesis of ompP2, generating proteins truncated after amino acids 139, 174, 182, and 264. These deletion proteins were tested for reactivities with the monoclonal antibodies, thereby establishing the boundaries of three antigenic determinants that were recognized by the monoclonals: domain (i), amino acids 104-139; domain (ii) amino acids 162-174; and domain (iii), amino acids 267-341. The biological activities of monoclonal antibodies that were representative of these three classes were tested for their bactericidal activity in complement-mediated lysis of whole cells. The monoclonal antibodies were also tested for their immunoprotective properties in the infant rat model of bacteraemia. Although the monoclonal antibodies were surface-binding, they were neither bactericidal nor protective.     

Identification and partial characterization of human platelet C1q binding sites

We recently showed that human blood platelets bind the complement component, C1q, and mAb directed against lymphoblastoid C1q receptors in a specific and saturable manner. To identify and further characterize platelet C1q binding sites, human platelets were washed, solubilized in Triton X-100 and either subjected to SDS-PAGE and Western blotting by using monoclonal (II1/D1) and polyclonal antibodies recognizing C1qR on lymphoblastoid cells, or applied to a C1q-Sepharose affinity column under low ionic strength conditions (20 mM NaCl). Adherent proteins were eluted with buffer containing 300 mM NaCl. Western blotting with monoclonal and polyclonal antibodies directed against C1qR showed exclusive reactivity with a 67,000 m.w. protein possessing intrachain disulfide bonds. SDS-PAGE of C1q-Sepharose eluates also revealed the presence of a 67,000 protein which was accompanied to varying degrees by a 94,000 constituent. Because similar m.w., 125I-labeled proteins were recovered from C1q-Sepharose columns to which lysed, surface-labeled platelets had been applied, both 94,000 and 67,000 components appear to be platelet membrane constituents. The 94,000 and 67,000 species, however, appear to be antigenically distinct. The 94,000 protein was immunoprecipitated by polyclonal antibodies against platelet membrane glycoprotein IIIa but not polyclonal antibodies against C1qR, whereas the 67,000 protein was immunoprecipitated exclusively by the polyclonal anti-C1qR antibody. The 67,000 protein thus appears to represent platelet C1q binding sites resembling C1qR on lymphoblastoid cells.