The effects of iodine and thiol-blocking reagents on complement component C2 and on the assembly of the classical-pathway C3 convertase

I2 can react with complement component C2 in a two-stage process. In the first stage, a form of C2 with enhanced haemolytic activity is produced. This form of C2 is cleaved to C2a and C2b by C1s at the same rate as native C2. The enhanced C2 haemolytic activity correlates with the ability to form a stable fluid-phase C3 convertase on addition of the C2 to C4b and C1s. It reflects an increased affinity for C4b of C2a formed from I2-treated C2, although the affinity for C4b of I2-treated C2 itself is not markedly increased. The specific activity of C3 convertase formed from I2-treated C2 is the same as that formed from native C2. The second stage of the reaction with I2, which is favoured at high pH or in the presence of excess I2, inactivates C2 on production of a species that cannot be cleaved by C1s. The presence of a single free thiol group in C2, which is the site of modification by I2, was confirmed by titration with p-chloromercuribenzoate, iodoacetamide and 5,5'-dithiobis-(2-nitrobenzoic acid). A single thiol group is also present in Factor B, and the cysteine residue, like that in C2, requires denaturation of the protein before reaction with iodoacetamide and 5,5'-dithiobis-(2-nitrobenzoic acid) but not p-chloro- mercuribenzoate .     

Analysis of C3-receptor activity on human B-lymphocytes and isolation of the complement receptor type 2 (CR2).

The rosetting of defined C3-fragment-coated sheep erythrocytes to B-cell-enriched tonsil lymphocytes was measured. The rosetting lymphocytes were homogeneous with respect to expression of C3b, iC3b and C3d receptors. Isolation of receptors for C3 fragments from surface-radioiodinated lymphocytes by affinity chromatography on immobilized C3u, iC3b and C3d,g produced two proteins with partially overlapping specificities. A protein of 240 000 Mr, recognized by the monoclonal antibody To5 and identified as CR1 (complement receptor type 1), had affinity for C3u and iC3b. A protein of 145 000 Mr, recognized by the monoclonal antibody B2, had affinity for all three C3 fragments. Inhibition of rosetting by antibodies to these proteins indicates that CR1 is responsible for C3b-mediated rosetting and that the 145000-Mr receptor (CR2) is responsible for C3d-mediated rosetting. Partial inhibition by both anti-CR1 and anti-CR2 antibodies of iC3b-mediated rosetting indicates that both receptors are involved in iC3b-mediated rosetting. No other protein appears to be involved in tonsil B-cell rosetting to C3-fragment-coated cells. A method for preparing CR2 from tonsil lymphocytes based on affinity chromatography on C3d,g-Sepharose has been developed. Forty tonsil pairs (2 X 10(10) B-cells) yield about 40 micrograms of pure protein equivalent to a purification of 6500-fold from a detergent extract.     

Eosinophil granule major basic protein regulates generation of classical and alternative-amplification pathway C3 convertases in vitro

Eosinophil major basic protein (MBP), a highly charged polycation, forms the core of the eosinophil granule and mediates tissue damage in allergic disease. Purified MBP was studied for capacity to regulate the generation of classical and alternative-amplification pathway C3 convertases because previous studies have shown that other polycations (protamine, poly-L-lysine) and polyanions (heparin) may play important roles in regulating C activation. MBP inhibited the generation of EAC1,4b,2a and EAC4b,3b,Bb,P but appeared to inhibit the generation of classical pathway convertase more than the alternative amplification pathway convertase at a given dose. Dose-response curves with MBP were steeper than curves seen with polyanion (heparin). MBP did not lyse cellular intermediates at concentrations that caused almost total inhibition of convertase generation. One mechanism of inhibition of convertase generation may have been through an action on C3b, because preincubation of MBP with an EAC4b,3b cellular intermediate interfered with the ability of this cellular intermediate to be lysed. Furthermore, MBP prevented consumption of B in a reaction mixture that contained factors B, D, and C3b, also suggesting an action on C3b. Reduced and alkylated MBP (A-MBP) was compared with native MBP, which possesses two reactive sulfhydryl groups, to determine whether charge alone is responsible for blocking convertase generation; native MBP rapidly associates and is relatively insoluble at neutral and alkaline pH whereas A-MBP remains soluble. A-MBP impaired convertase generation, did not appear to remain bound to cellular intermediates and did not suppress B consumption in the fluid phase assay. This suggests that the ability of MBP to regulate C activation is complex and not entirely through its net charge. Finally, although heparin or MBP alone may prevent C activation, when these substances were present at the same time there was no effect on C activation suggesting that charge neutralization may abrogate the effects of these charged substances on C activation. Taken together, these studies suggest that MBP at physiologic concentrations may regulate in vivo C activation at the tissue level.     

Native C3 does not bind to the C3b receptor (CR1) of human blood B lymphocytes or alter immunoglobulin synthesis

Complement receptors on lymphocytes were first described more than 12 yr ago (1-3) and have come to be used as a common marker for the identification of B cells (4). The function of these receptors on the lymphocyte and their possible role in induction and/or regulation of the immune response remain unclear. In particular, there continues to be controversy as to whether native C3 can bind to the C3b receptor of these cells without cleavage to C3b (5-10). The resolution of this question is critical in order to clarify the expected state of availability of the receptor in vivo, because in plasma, the C3 concentration is relatively high (1.1 to 1.5 mg/ml), whereas there is little or no circulating C3b due to efficient degradation by factor H and the C3-inactivator (11). With the recent development of an improved method for the isolation of C3 from human plasma, it has been possible to obtain biochemically and functionally pure C3 that has not undergone structural or conformational alteration during processing and fully retains the specific hemolytic activity of C3 in fresh serum (12). Berger et al. (13) were able to demonstrate that C3 prepared in this way failed to bind to the C3b receptor of human polymorphonuclear leukocytes or erythrocytes. Similar observations were made by Schreiber et al. (14), also with phagocytic cells and erythrocytes, and by Dixit et al. (15) with an isolated membrane receptor preparation from rabbit macrophages. In the present communication, we extend these observations to human peripheral blood B lymphocytes. Purified C3 in its native state fails to block B lymphocyte-EA (IgM) C4b3b rosettes, whereas C3b causes 50% inhibition at 5 to 6 micrograms/ml. Furthermore, C3 failed to alter polyclonal immunoglobulin (Ig) production by human B cells, whereas C3b inhibited this B cell function. These data suggest that native C3 does not bind to the C3b receptors of B lymphocytes, and thus they are not occupied under normal conditions in vivo.     

C3b receptor activity on transfected cells expressing glycoprotein C of herpes simplex virus types 1 and 2.

Glycoprotein C from herpes simplex virus type 1 (gC-1 from HSV-1) acts as a receptor for the C3b fragment of the third component of complement on HSV-1-infected cell surfaces. Direct binding assays with purified gC-1 and C3b demonstrate that other viral and cellular proteins are not required for this interaction. Although C3b receptor activity is not expressed on HSV-2-infected cell surfaces, purified gC-2 specifically binds C3b in direct binding assays, suggesting that gC-1 and gC-2 are functionally similar. Here, we used a transient transfection system to further characterize the role of gC-1 and gC-2 as C3b receptors and to localize the site(s) on gC involved in C3b binding. The genes for gC-1 and gC-2 were each cloned into a eucaryotic expression vector containing the Rous sarcoma virus long terminal repeat as the promoter and transfected into NIH 3T3 cells. The expressed proteins were similar in molecular size, extent of carbohydrate processing, and antigenic properties to gC-1 and gC-2 purified from infected cells. Using a double-label immunofluorescence assay, we found that both gC-1 and gC-2 were expressed on the surfaces of transfected cells and bound C3b. These results suggest that other proteins expressed during HSV-2 infection prevent receptor activity. We constructed three in-frame deletion mutants of gC-2 to identify domains on the protein important for C3b receptor activity. These mutants lacked amino acids 26 to 73, 219 to 244, or 318 to 346. The mutant protein lacking residues 26 to 73 was reactive with two monoclonal antibodies recognizing distinct epitopes, showed a wild-type pattern of carbohydrate processing, and bound C3b on the transfected cell surface. These results suggest that residues 26 to 73 are not involved in C3b binding. The other two mutant proteins were present on the cell surface, but did not bind C3b. In addition, these mutant proteins showed altered patterns of carbohydrate processing, formed aggregates, and were no longer recognized by the monoclonal antibodies. These properties indicate that removal of residues 219 to 244 or 318 to 346 disrupted the native conformation of gC-2, possibly owing to an alteration in the spacing between critical cysteine residues.     

Synthesis of protein kinase Cδ C1b domain by native chemical ligation methodology and characterization of its folding and ligand binding

The C1b domain of protein kinase Cδ (PKCδ), a potent receptor for ligands such as diacylglycerol and phorbol esters, was synthesized by utilizing native chemical ligation. With this synthetic strategy, the domain was efficiently constructed and shown to have high affinity ligand binding and correct folding. The C1b domain has been utilized for the development of novel ligands for the control of phosphorylation by PKC family members. This strategy will pave the way for the efficient construction of C1b domains modified with fluorescent dyes, biotin, etc. Copyright © 2009 European Peptide Society and John Wiley & Sons, Ltd.     

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.     

Chimeric receptors of the human C3a receptor and C5a receptor (CD88)

Chimeras were generated between the human anaphylatoxin C3a and C5a receptors (C3aR and C5aR, respectively) to define the structural requirements for ligand binding and discrimination. Chimeric receptors were generated by systematically exchanging between the two receptors four receptor modules (the N terminus, transmembrane regions 1 to 4, the second extracellular loop, and transmembrane region 5 to the C terminus). The mutants were transiently expressed in HEK-293 cells (with or without Galpha-16) and analyzed for cell surface expression, binding of C3a and C5a, and functional responsiveness (calcium mobilization) toward C3a, C5a, and a C3a as well as a C5a analogue peptide. The data indicate that in both anaphylatoxin receptors the transmembrane regions and the second extracellular loop act as a functional unit that is disrupted by any reciprocal exchange. N-terminal substitution confirmed the two-binding site model for the human C5aR, in which the receptor N terminus is required for high affinity binding of the native ligand but not a C5a analogue peptide. In contrast, the human C3a receptor did not require the original N terminus for high affinity binding of and activation by C3a, a result that was confirmed by N-terminal deletion mutants. This indicates a completely different binding mode of the anaphylatoxins to their corresponding receptors. The C5a analogue peptide, but not C5a, was an agonist of the C3aR. Replacement of the C3aR N terminus by the C5aR sequence, however, lead to the generation of a true hybrid C3a/C5a receptor, which bound and functionally responded to both ligands, C3a and C5a.     

Analogous antigenic alterations elicited in C3 by physiologic binding and by denaturation in the presence of sodium dodecylsulfate

The expression of three antigenic subsets of C3--the C3(S), the C3(N), and the C3(D) antigens--by soluble and target-bound forms of C3 was studied. The C3(S) subset is stable and is expressed by native as well as denatured C3 (exposure to sodium dodecyl sulphate (SDS) M greater than or equal to 10(-3)). The C3(N) and C3(D) subsets are labile and are expressed by native and denatured C3, respectively. Antisera to native C3, anti-C3(S-N), react with the C3(S) as well as the C3(N) subset. Antisera to isolated C3 subunits react exclusively with the C3(D) subset. A separation of anti-C3(S) and anti-C3(N) antibodies was accomplished by adsorbing the anti-C3(S-N) antiserum with insolubilized, denatured C3, anti-C3(N) antibodies remained unadsorbed. Anti-C3(S) antibodies were adsorbed and subsequently eluted from the denatured C3. Agglutination studies with EAC1423b cells showed significant agglutination with anti-C3(S) and anti-C3(D) antisera but reduced agglutination with anti-C3(N) antisera. Agglutination by anti-C3(D) antisera was unaffected in the presence of EDTA serum containing converted or unconverted C3. These data suggest an antigenic modification of C3b-b' upon binding that mirrors the antigenic transition associated with SDS denaturation of C3.     

Charge reversal at the P3' position in protein C optimally enhances thrombin affinity and activation rate.

We have examined the properties of several human protein C (HPC) derivatives with substitutions for acidic residues near the thrombin cleavage site, including changing the P3' Asp to Asn (D172N), Gly (D172G), Ala (D172A), or Lys (D172K). The rate of thrombin-catalyzed activation of D172N, D172G, and D172A was increased 4-9-fold compared to wild-type HPC, primarily due to a reduction in the inhibitory effect of calcium and a resulting increase in affinity for free alpha-thrombin. There was no significant increase in activation rate or affinity with these 3 derivatives in the absence of calcium, confirming that P3' Asp affects calcium dependency in the native protein C molecule. With charge reversal at P3' (D172K), there was a 30-fold increase in activation rate in the presence of calcium, but unlike the other derivatives, there was a substantial effect (5-fold) on the activation rate and affinity for free alpha-thrombin in the absence of calcium. Thus, protein C affinity for thrombin appears to be influenced by a combination of calcium-dependent and -independent effects of the acidic P3' residue.     

Promotion of the GTP-liganded state of the Go alpha protein by deletion of the C terminus.

G proteins are active as long as GTP is bound to the alpha subunit. Activation ends when GTP is cleaved to GDP that then stays bound to the active site. Agonist-liganded receptors allow formation of the active state by decreasing the affinity of alpha subunits for GDP allowing exchange of GDP for GTP. Since receptors interact with the C terminus of the alpha subunits, we tested whether deletion of the C terminus could mimic activation by receptors. Three deletions and one point mutation at the C terminus of alpha o were engineered in alpha o cDNA by the polymerase chain reaction, transcribed into RNA, and translated in a rabbit reticulocyte lysate. The ability of in vitro synthesized protein to bind guanine nucleotide was inferred from analysis of native tryptic cleavage patterns, while the ability of the proteins to associate with beta gamma was measured by sucrose density gradient centrifugation. Deletion of 14 amino acids, alpha oD[341], from the C terminus causes a large decrease in GDP affinity, with little or no change in guanosine 5'-3-O-(thio)triphosphate affinity. When GTP is present, alpha oD[341] remains in the activated conformation because exchange of GTP for GDP is rapid. Deletion of 10 amino acids, alpha oD[345], lowers GDP affinity, but less dramatically than in alpha oD[341]. Deletion of 5 amino acids, alpha oD[350], or mutation of Arg-349 to proline alpha oR[349P] has no detectable effects on GDP affinity. Deletion of up to 10 amino acids from the C terminus does not prevent formation of alpha beta gamma heterotrimers. We propose that the C terminus of the alpha subunit is a mobile region that blocks dissociation of GDP. Agonist-liganded receptors may move it aside to allow release of GDP, exchange for GTP, and activation of the alpha subunit.     

Induction of granulocyte histaminase release by particle-bound complement C3 cleavage products (C3b, C3bi) and IgG

The interaction of opsonized particles with human granulocytes promotes a number of important biologic functions, including phagocytosis, superoxide generation, and release of a variety of enzymes, including histaminase. We have previously determined that histaminase release occurs via a C3-dependent process. Although fluid-phase C3b dimers can mediate release, the relative effects of particle-bound C3b and C3bi and of IgG have not been examined. In this report we demonstrate that particle-bound C3 deposited on activators of the alternative C pathway effected histaminase release in the absence of IgG. Particle-bound C3bi and C3b were both effective as mediators of histaminase release. The extent of release varied as a function of the activating surface on which C3 was deposited (zymosan C3b was considerably more potent than C3b bound to rabbit erythrocytes, which was slightly more potent than C3b bound to neuraminidase-treated sheep erythrocytes). In contrast, C3b or C3bi deposited on nonactivating surfaces (such as sheep erythrocytes) at inputs of up to 2,000,000 molecules per granulocyte failed to induce histaminase release unless IgG was also present. The ability of C3b bound to particles that serve as activators of the alternative pathway to induce histaminase release is apparently not the result of decreased susceptibility of C3b to proteolysis or to an increased binding affinity to the C3b receptor, but may relate to the interaction of other surface structures on activating particles with the PMN membrane.     

Binding of activated C3b component with complement effector

Various nucleophilic agents (acceptors) react with thiolester group of nascent activated fragment (C3b) of the third complement component. The C3b-acceptors binding prevents transformation of C3 convertase to C5 convertase and results in inhibition of the cell-target lysis. A convenient method of monitoring the EAC142 to EAC1423 transformation was elaborated. Character of the inhibition suggests that the covalent binding follows a stage of the reversible C3b-acceptor complex formation. The method allows to determine the maximum of inhibition of the C5 convertase formation and the dissociation constant of the reversible C3b-acceptor complex, which reflects the C3b affinity to this acceptor.     

Muscarinic receptors transform NIH 3T3 cells through a Ras-dependent signalling pathway inhibited by the Ras-GTPase-activating protein SH3 domain.

Expression of certain subtypes of human muscarinic receptors in NIH 3T3 cells provides an agonist-dependent model of cellular transformation by formation of foci in response to carbachol. Although focus formation correlates with the ability of the muscarinic receptors to activate phospholipase C, the actual mitogenic signal transduction pathway is unknown. Through cotransfection experiments and measurement of the activation state of native and epitope-tagged Ras proteins, the contributions of Ras and Ras GTPase-activating protein (Ras-GAP) to muscarinic receptor-dependent transformation were defined. Transforming muscarinic receptors were able to activate Ras, and such activation was required for transformation because focus formation was inhibited by coexpression of either Ras with a dominant-negative mutation or constructs of Ras-GAP that include the catalytic domain. Coexpression of the N-terminal region of GAP or of its isolated SH3 (Src homology 3) domain, but not its SH2 domain, was also sufficient to suppress muscarinic receptor-dependent focus formation. Point mutations at conserved residues in the Ras-GAP SH3 domain reversed its action, leading to an increase in carbachol-dependent transformation. The inhibitory effect of expression of the Ras-GAP SH3 domain occurs proximal to Ras activation and is selective for the mitogenic pathway activated by carbachol, as cellular transformation by either v-Ras or trkA/nerve growth factor is unaffected.     

Interaction of guanylyl cyclase C with SH3 domain of Src tyrosine kinase. Yet another mechanism for desensitization

Protein-protein interactions mediated by the Src homology 3 (SH3) domain have been implicated in the regulation of receptor functions for subcellular localization of proteins and the reorganization of cytoskeleton. The experiments described in this article begin to identify the interaction of the SH3 domain of Src tyrosine kinase with the guanylyl cyclase C receptor after activation with Escherichia coli heat-stable enterotoxin (ST). Only one of two post-translationally modified forms of guanylyl cyclase C from T84 colonic carcinoma cells bind to GST-SH3 fusion protein of Src and Hck tyrosine kinases. Interestingly, the GST-Src-SH3 fusion protein showed 2-fold more affinity to native guanylyl cyclase C in solution than the GST-Hck-SH3 fusion protein. The affinity of the GST-Src-SH3 fusion protein to guanylyl cyclase C increased on desensitization of receptor in vivo. An in vitro cyclase assay in the presence of GST-Src-SH3 fusion protein indicated inhibition of the catalytic activity of guanylyl cyclase C. The catalytic domain recombinant protein (GST-GCD) of guanylyl cyclase C could pull-down a 60-kDa protein that reacted with Src tyrosine antibody and also showed autophosphorylation. These data suggest that SH3 domain-mediated protein-protein interaction with the catalytic domain of guanylyl cyclase C inhibited the cyclase activity and that such an interaction, possibly mediated by Src tyrosine kinase or additional proteins, might be pivotal for the desensitization phenomenon of the guanylyl cyclase C receptor.     

Spontaneous reformation of the intramolecular thioester in complement protein C3 and low temperature capture of a conformational intermediate capable of reformation.

Three human plasma proteins contain intramolecular thioester bonds: complement components C3 and C4 and alpha 2-macroglobulin. Their thioesters form when glutamine and cysteine residues react in the newly translated proteins and ammonia is released. We have reversed this reaction by treating C3 with ammonia to cleave the thioester and reform the original Gln and Cys. Thioester scission initiates a multistep conformational transition. One intermediate was sufficiently stable to be isolated by high performance liquid chromatography. It lacked native C3 functions and was shown to contain one free sulfhydryl group. Incubation of this ammonia-inactivated C3 intermediate in the absence of ammonia resulted in refolding to a native C3 conformation and recovery of thioester-dependent functions, as evidenced by: 1) return of hemolytic function, 2) return of autolytic cleavage of the alpha-chain, and 3) return of the ability to attach to surfaces during complement activation. Refolding and thioester reformation were dependent on a free SH group and were inhibited by HgCl2 and other thiol-specific reagents. Incubation of ammonia-inactivated C3 at 25 degrees C at pH 7.4 resulted in recovery of 70% of the original C3 function. Refolding and thioester reformation exhibited a Gibbs free energy of +5.2 kcal/mol and were favored over unfolding to the final inactive form. During reformation of native C3 from 14CH3NH2-treated C3, return of the native conformation was accompanied by release of radiolabel from the protein and return of hemolytic complement function. These results suggest that folding of C3 provides both the energy and environment necessary to react the Gln and Cys residues, release ammonia, and form the thioester bond.     

Isolation of C4-binding protein from guinea pig plasma and demonstration of its function as a control protein of the classical complement pathway C3 convertase

A decay-accelerating factor of the classical complement pathway C3 convertase, C4b,2a, has been purified to homogeneity from guinea pig plasma by a 5-step procedure that includes 5% polyethyleneglycol-4000 (PEG-4000) precipitation, Sepharose 6B gel filtration, heparin-Sepharose chromatography, DE-52 anion exchange chromatography, and Sepharose-C4gp affinity chromatography. The protein elicited a monospecific antiserum in a rabbit and was found with the Mancini technique in both normal and C4-deficient guinea pig plasma at a concentration of 60 microgram/ml. The purified protein gave a single stained band of 550,000 m.w. on SDS-PAGE under nonreducing conditions and a single band of 72,000 m.w. with reduction and alkylation. On the basis of its m.w. and subunit structure, ability to bind to a C4 affinity column, and ability to regulate the classical C system by accelerating the decay of the classical C3 convertase this protein represents the guinea pig analog of the human C4-binding protein.     

Identification of C3b-binding regions on herpes simplex virus type 2 glycoprotein C.

Glycoprotein C from herpes simplex viruses types 1 and 2 (gC-1 and gC-2) acts as a receptor for the C3b fragment of the third component of complement. Our goal is to identify domains on gC involved in C3b receptor activity. Here, we used in-frame linker-insertion mutagenesis of the cloned gene for gC-2 to identify regions of the protein involved in C3b binding. We constructed 41 mutants of gC-2, each having a single, double, or triple insertion of four amino acids at sites spread across the protein. A transient transfection assay was used to characterize the expressed mutant proteins. All of the proteins were expressed on the transfected cell surface, exhibited processing of N-linked oligosaccharides, and bound one or more monoclonal antibodies recognizing distinct antigenic sites on native gC-2. This suggested that each of the mutant proteins was folded into a native structure and that a loss of C3b binding by any of the mutants could be attributed to the disruption of a specific functional domain. When the panel of insertion mutants was assayed for C3b receptor activity, we identified three distinct regions that are important for C3b binding, since an insertion within those regions abolished C3b receptor activity. Region I was located between amino acids 102 and 107, region II was located between residues 222 and 279, and region III was located between residues 307 and 379. In addition, region III has some structural features similar to a conserved motif found in complement receptor 1, the human C3b receptor. Finally, blocking experiments indicated that gC-1 and gC-2 bind to similar locations on the C3b molecule.     

Differences between the binding sites of the complement regulatory proteins DAF, CR1, and factor H on C3 convertases

Binding studies using purified decay-accelerating factor (DAF), CR1, and Factor H indicate that the primary interaction of DAF with C3 convertases is with the Bb or C2a subunits, whereas CR1 and Factor H interact primarily with the C3b or C4b subunits. The ability of soluble DAF, CR1, or Factor H to decay C3b,Bb bound to zymosan was inhibited by various concentrations of fluid-phase competitors (C3b, Bb, C3b,Bb, C3b,B, C4b, or C4b,C2a) in 0.1% NP-40 at 22 degrees C. The apparent association constants (appKa) for DAF were 0.045, 0.067, 0.91, 0.71, 0.00045, and 0.53 microM-1, respectively. The appKa for CR1 were 0.50, 0.0040, 1, 1, 1, and 1.1 microM-1, respectively. The appKa for Factor H were 4.3, 0.0005, 2.9, 6.3, 0.27, and 0.29 microM-1, respectively. Thus, C3b binds to DAF with a 10-fold lower affinity than to CR1 and a 100-fold lower affinity than to Factor H. The appKa of C3b,Bb for the three proteins were more similar: DAF (0.91 microM-1), CR1 (1 microM-1), and Factor H (2.9 microM-1). DAF binds to Bb with a 50% higher affinity than to C3b, and to C4b,C2a with a 1000-fold higher affinity than to C4b alone. In contrast, CR1 and Factor H bind almost equally well to the C3 convertases and to their noncatalytic subunits. The affinity of DAF for CVF,Bb was similar to its affinity for Bb alone, suggesting that DAF does not recognize conformational determinants unique to Bb in C3 convertases.     

C3 receptors on human lymphocyte subsets and recruitment of ADCC effector cells by C3 fragments

The presence of C3 receptors on human peripheral blood lymphocytes (PBL) and on the ADCC-exhibiting subset (K cells) thereof was analyzed by rosetting with bovine erythrocytes (Eb) or chicken erythrocytes (Ec) carrying human C3b, C3bi, or C3d. The indicator cells were coated with 20,000 to 100,000 C3 fragments, obtained by C3 activation with purified proteins of the alternative pathway and trypsin treatment. ADCC was studied at the cellular level by means of a plaque assay, with complement-free or complement-carrying indicator cells as targets. Of the total lymphocytes, 12 to 14% bound EC3b; 6 to 8%, EC3bi; and approximately 2%, EC3d. Surface marker analysis indicated that approximately 75% of the C3b-binding lymphocytes in PBL were either B or null cells and approximately 60% of the C3bi-binding cells were T cells, as characterized by the monoclonal antibodies OKT3 and OKT4 or by presence of receptors for Helix pomatia hemagglutinin. Of the K cells, which constituted from 5 to 10% of the total lymphocytes, approximately 20% bound C3b; 30 to 35%, C3bi; and 7 to 8%, C3d. Here the majority of the C3b binders were null cells, and the majority of the C3bi and C3d binders were T cells. Only one-third of the C3b-binding K cells and one-fifth of the C3bi-binding K cells bound both fragments. The nature of these double binding cells is unknown. In contrast, all C3d-binding K cells bound C3bi as well. C3 fragment-carrying target cells did not induce K cell-mediated lysis in the absence of anti-target antibodies but strongly enhanced ADCC in the presence of sublytic concentrations of such antibodies. The rank order for C3 fragment-induced enhancement was C3bi greater than C3d greater than C3b. It reflected the relative proportions of effector cells binding the different fragments. Enhancement was the expression of effector cell recruitment rather than of increased cytolytic activity of individual K cells. This recruitment was selective in that C3b-carrying target cells primarily recruited effector cells of null type, binding C3b, while C3bi- or C3d-carrying targets primarily recruited C3bi and/or C3d-binding K cells of T gamma type. Thus, these experiments show directly at the effector cell level that cell-bound C3 fragments constitute important recognition structures, which strongly amplify ADCC both by recruiting the proper effector cells into the cytolytic reaction and by very significantly decreasing the antibody concentration needed for its induction.