Protein S multimers and monomers each have direct anticoagulant activity.

BACKGROUND AND OBJECTIVES: Plasma protein S (PS) is an essential anticoagulant that has activated protein C-independent, direct anticoagulant activity (PS-direct). It was reported that monomeric purified PS has poor PS-direct and that a subpopulation of multimeric purified PS has high PS-direct and high affinity for phospholipids. We independently examined the relative PS-direct and affinity for phospholipids of monomeric and multimeric PS and we obtained contrasting results. METHODS AND RESULTS: Unpurified recombinant protein S (rPS) was monomeric and had PS-direct potency similar to that of both PS in plasma and multimeric affinity-purified PS, as measured in plasma assays for PS-direct and in thrombin-generation assays. Multimers of unpurified rPS were not induced by ethylenediaminetetraacetic acid (EDTA), pH 2.5, NaSCN, or barium adsorption/elution. Multimers were induced by chromatography in the presence of EDTA and thus may be concentration-dependent. In contrast to a different report, monomers, dimers, trimers, and higher-order PS forms were clearly separated in sedimentation velocity experiments and multimers were not dissociated by adding Ca(2+). Active plasma-derived and recombinant immunoaffinity-purified PS were fractionated into monomers and multimers. On a mass basis, monomers and multimers had similar specific PS-direct and ability to compete with prothrombinase components (factors Xa/Va) for limiting phospholipids. FXa ligand blotted to both monomers and multimers. CONCLUSIONS: Plasma PS-direct is similar to that of affinity-purified PS and unpurified rPS. Under our conditions, monomeric and multimeric PS have similar PS-direct and ability to compete for phospholipids. Discordant earlier findings are likely due to loss of PS-direct during conventional purification procedures.

Plasma contains protein S monomers and multimers with similar direct anticoagulant activity.

BACKGROUND: Protein S (PS) has activated protein C-independent, direct anticoagulant activity (PS-direct). We reported that both multimers and monomers of affinity-purified PS have PS-direct similar to that in plasma, in contrast to another report. OBJECTIVE: We extended our studies to establish the molecular forms and activity of plasma PS. METHODS: Novel ELISAs were developed that could detect only multimeric, not monomeric, PS because they employed the same monoclonal antibody for capture and detection. PS forms were also examined on native PAGE immunoblots. A new activity assay for PS-direct was applied to plasma and gel-filtered plasma fractions. RESULTS: Plasma PS multimers were clearly demonstrated using the ELISAs; 30-60% of free plasma PS appeared to be multimeric, a proportion similar to that of affinity-purified PS. On immunoblots, plasma PS multimers were more easily detected after gel filtration; plasma PS monomers and several apparent multimers comigrated with respective forms of affinity-purified PS. Antigen elution profiles after gel filtration of plasma revealed at least one major peak of apparent PS multimers (40-55% of free PS appeared multimeric). Biotin-factor Xa could bind to both plasma PS monomers and multimers. Strong plasma PS-direct was demonstrated, and plasma PS monomers, multimers, and PS-C4b-binding protein complexes each reconstituted PS-depleted plasma to similar levels of PS-direct. CONCLUSION: Our data are in disagreement with a report that monomeric purified PS has little PS-direct and that only monomeric PS exists in plasma. We find that both affinity-purified and plasma PS exist as monomers and multimers with similar PS-direct.

Nonenzymatic anticoagulant activity of the mutant serine protease Ser360Ala-activated protein C mediated by factor Va.

The human plasma serine protease, activated protein C (APC), primarily exerts its anticoagulant function by proteolytic inactivation of the blood coagulation cofactors Va and VIIIa. A recombinant active site Ser 360 to Ala mutation of protein C was prepared, and the mutant protein was expressed in human 293 kidney cells and purified. The activation peptide of the mutant protein C zymogen was cleaved by a snake venom activator, Protac C, but the "activated" S360A APC did not have amidolytic activity. However, it did exhibit significant anticoagulant activity both in clotting assays and in a purified protein assay system that measured prothrombinase activity. The S360A APC was compared to plasma-derived and wild-type recombinant APC. The anticoagulant activity of the mutant, but not native APC, was resistant to diisopropyl fluorophosphate, whereas all APCs were inhibited by monoclonal antibodies against APC. In contrast to native APC, S360A APC was not inactivated by serine protease inhibitors in plasma and did not bind to the highly reactive mutant protease inhibitor M358R alpha 1 antitrypsin. Since plasma serpins provide the major mechanism for inactivating APC in vivo, this suggests that S360A APC would have a long half-life in vivo, with potential therapeutic advantages. S360A APC rapidly inhibited factor Va in a nonenzymatic manner since it apparently did not proteolyze factor Va. These data suggest that native APC may exhibit rapid nonenzymatic anticoagulant activity followed by enzymatic irreversible proteolysis of factor Va. The results of clotting assays and prothrombinase assays showed that S360A APC could not inhibit the variant Gln 506-FVa compared with normal Arg 506-FVa, suggesting that the active site of S360A APC binds to FVa at or near Arg 506.

Binding sites for blood coagulation factor Xa and protein S involving residues 493-506 in factor Va.

Inactivation due to cleavage of Factor Va (FVa) at Arg 506 by activated protein C (APC) helps to downregulate blood coagulation. To identify potential functional roles of amino acids near Arg 506, synthetic overlapping pentadecapeptides comprising FVa heavy chain residues 481-525 were tested for their ability to inhibit prothrombin activation by prothrombinase complexes [Factor Xa (FXa):FVa:phospholipids:Ca2+]. The most potent inhibition was observed for peptide VP493 (residues 493-506), with 50% inhibition at 2.5 microM. VP493 also inhibited FXa in plasma in FXa-1-stage clotting assays by 50% at 3 microM. When the C-terminal carboxamide group of VP493 was replaced by a carboxyl group, most prothrombinase inhibitory activity was lost. VP493 preincubated with FXa inhibited prothrombinase with a pattern of mixed inhibition. Homologous peptides from Factor VIII sequences did not inhibit prothrombinase. Affinity-purified antibodies to VP493 inhibited prothrombinase activity and prolonged FXa-1-stage clotting times. VP493 also blocked the ability of protein S to inhibit prothrombinase independently of APC. Immobilized VP493 bound specifically with similar affinity to both FXa and protein S (Kd approximately 40 nM), but did not measurably bind prothrombin or APC. These studies suggest that FVa residues 493-506 contribute to binding sites for both FXa and protein S, providing a rationale for the ability of protein S to negate the protective effect of FXa toward APC cleavage of FVa. Possible loss of this FVa binding site for FXa due to cleavage at Arg 506 by APC may help explain why this cleavage causes 40% decrease in FVa activity and facilitates inactivation of FVa.

Interactions and inhibition of blood coagulation factor Va involving residues 311-325 of activated protein C.

Activated protein C (APC) exerts its physiologic anticoagulant role by proteolytic inactivation of the blood coagulation cofactors Va and VIIIa. The synthetic peptide-(311-325) (KRNRTFVLNFIKIPV), derived from the heavy chain sequence of APC, potently inhibited APC anticoagulant activity in activated partial thromboplastin time (APTT) and Xa-1-stage coagulation assays in normal and in protein S-depleted plasma with 50% inhibition at 13 microM peptide. In a system using purified clotting factors, peptide-(311-325) inhibited APC-catalyzed inactivation of factor Va in the presence or absence of phospholipids with 50% inhibition at 6 microM peptide. However, peptide-(311-325) had no effect on APC amidolytic activity or on the reaction of APC with the serpin, recombinant [Arg358]alpha 1-antitrypsin. Peptide-(311-325) surprisingly inhibited factor Xa clotting activity in normal plasma, and in a purified system it inhibited prothrombinase activity in the presence but not in the absence of factor Va with 50% inhibition at 8 microM peptide. The peptide had no significant effect on factor Xa or thrombin amidolytic activity and no effect on the clotting of purified fibrinogen by thrombin, suggesting it does not directly inhibit these enzymes. Factor Va bound in a dose-dependent manner to immobilized peptide-(311-325). Peptide-(311-315) inhibited the binding of factor Va to immobilized APC or factor Xa.(ABSTRACT TRUNCATED AT 250 WORDS)

Direct anticoagulant activity of protein S-C4b binding protein complex in Heerlen heterozygotes and normals.

BACKGROUND: Plasma protein S normally circulates free (40%) or complexed with C4b-binding protein (PS-C4BP); only free protein S is a cofactor for activated protein C during factor (F) Va inactivation. Protein S-Heerlen lacks a carbohydrate group, leading to low plasma free protein S levels, but normal levels of PS-C4BP. OBJECTIVES: Because protein S-Heerlen is not associated with thrombosis, we investigated whether PS-C4BP is directly anticoagulant in plasma and whether PS-Heerlen-C4BP has enhanced direct anticoagulant activity. METHODS: An assay for protein S direct activity was applied to Heerlen-heterozygous plasmas. Free and complexed protein S were repeatedly isolated from normal and Heerlen-heterozygous plasmas and tested for direct anticoagulant activity in prothrombinase assays and in plasma. RESULTS: Heerlen-heterozygous plasmas were deficient in free and total protein S antigen but had normal to high protein S direct anticoagulant activity. Purified Heerlen-heterozygous PS-C4BP was 7-fold more potent than normal PS-C4BP in inhibiting full prothrombinase activity, and 22-fold more potent in inhibiting prothrombin activation in the absence of FVa; it also specifically prolonged plasma clotting times 14-fold more than normal PS-C4BP. Heerlen-heterozygous PS-C4BP did not compete for limiting phospholipids any better than normal PS-C4BP. However, ligand blots and surface plasmon resonance studies showed that Heerlen-heterozygous PS-C4BP bound more avidly to FXa than did normal PS-C4BP (apparent Kd = 4.3 nm vs. 82 nm). CONCLUSIONS: Plasma-derived PS-C4BP has direct anticoagulant activity in plasma and in purified systems. Enhanced direct activity of PS-Heerlen-C4BP may compensate for low free protein S levels and low cofactor activity in individuals with protein S-Heerlen.

Quantitative immunoblotting of plasma and platelet protein S.

Protein S, the activated protein C cofactor, was measured in plasma and in platelets by a quantitative immunoblotting assay using a double antibody technique. Either whole plasma or platelet lysates were electrophoresed on sodium dodecyl sulfate polyacrylamide gels and transferred to nitrocellulose membranes by electroblotting. Based on the demonstration of proportional transfer of protein S from the gel to the nitrocellulose membrane, a reproducible and sensitive quantitative assay for protein S antigen (approximately 70,000 MW) was developed that correlated well with the Laurell rocket assay for plasma protein S. Pooled normal plasma contains 22 micrograms/ml protein S. Total platelet protein S antigen at approximately 70,000 MW was determined in gel filtered platelets of ten healthy adults (mean, 163 ng per 10(8) platelets). In the supernatants of thrombin-stimulated platelets, 63% of the total platelet protein S antigen was measured. Thus, quantitative immunoblotting is a useful method to detect low levels of protein S in platelets or in plasma with the advantage of giving qualitative information, i.e. apparent MW, of protein S.

Detection and quantitation of cleaved and uncleaved high molecular weight kininogen in plasma by ligand blotting with radiolabeled plasma prekallikrein or factor XI.

A method for the quantitative assay of native single chain and kallikrein cleaved two-chain high molecular weight (HMW)-kininogen in plasma is described. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) of whole plasma is followed by electrotransfer of the electropherogram to nitrocellulose membranes and detection of the blotted HMW-kininogen with its physiologic ligands, radiolabeled plasma prekallikrein or radiolabeled factor XI. Using unreduced SDS-PAGE cleaved two-chain HMW-kininogen (Mr approximately 107,000 and 95,000), is electrophoretically separated from uncleaved single chain HMW-kininogen (Mr approximately 150,000). Counting the radioactivity of the nitrocellulose pieces corresponding to cleaved HMW-kininogen permits its quantitative measurement by comparison with standards consisting of decreasing amounts of fully dextran sulfate activated normal human plasma. Single chain HMW-kininogen is similarly assayed using reduced SDS-PAGE and unactivated normal human plasma standards. This technique is highly specific and sensitive to about 50 ng of either cleaved or uncleaved HMW-kininogen. Varying amounts of cleaved HMW-kininogen were found in a small series of plasmas from patients suffering from various inflammatory conditions. Higher levels of in vivo cleaved HMW-kininogen were observed during acute attacks of hereditary angioedema due to Cl-inhibitor deficiency. This technique may be useful for the assessment of the degree of in vitro or in vivo activation of the contact system.

Activated protein C resistance: molecular mechanisms.

Activated protein C (APC) resistance is usually associated with a single DNA mutation predicting replacement of Arg506 by Gln in factor V (FV). Studies using synthetic peptides suggest that FV residues 493-506 provide factor Xa (FXa) and protein S binding sites. Biochemical studies were performed to test the hypothesis that the Arg506Gln FV mutation causes APC resistance and to define the nature of the resistance of Gln506-FVa to APC. Purified Gln506-FV conveyed APC resistance to FV-deficient plasma in APTT and FXa-1-stage assays. Purified Gln506-FVa, generated either by thrombin or by FXa, was resistant to APC. Nonetheless, Gln506-FVa was not completely resistant to APC since it was inactivated by APC approximately 10-fold slower than normal Arg506-FVa, probably due to cleavage at Arg306. This reduced but significant susceptibility of Gln506-FVa to APC inactivation may help explain why APC resistance, especially for heterozygotes, is a relatively moderate risk factor for venous thrombosis. Cardiolipin promotes APC anticoagulant activity better than FXa coagulant activity, and antibodies from some antiphospholipid antibody syndrome patients downregulate APC activity. Thus, acquired APC resistance may contribute to pathogenesis of thrombosis in the antiphospholipid antibody syndrome.

Gas6, a ligand for the receptor protein-tyrosine kinase Tyro-3, is widely expressed in the central nervous system.

Gas6 (growth arrest specific gene-6) is a ligand for members of the Axl subfamily of receptor protein-tyrosine kinases. One of these receptors, Tyro-3, is widely expressed in the central nervous system. We have used biochemical and histological techniques, including in situ hybridization, to determine the expression patterns of Gas6 mRNA and protein during development. Gas6 is widely expressed in the rat central nervous system (CNS) beginning at late embryonic stages and its levels remain high in the adult. Gas6 is detected as a single 85 kDa protein, which is encoded by a single 2.5 kb mRNA species. At embryonic day 14 it is detected in the heart, blood vessels, testes, choroid plexus, and in the ventral spinal cord. In the adult, Gas6 is expressed in the cerebral cortex, (predominantly in layer V), the piriform cortex, and the hippocampus (areas CA1, CA3 and the dentate gyrus). It is also expressed in thalamic and hypothalamic structures, the midbrain, and in a subset of motor and trigeminal nuclei. In the cerebellum, it is expressed in Purkinje neurons and deep cerebellar nuclei. Protein S, a protein related to Gas6, is only detected at low levels in the CNS. The spatial and temporal profiles of Gas6 expression suggest that it could potentially serve as the physiologically relevant ligand for Tyro-3 in the postnatal rat nervous system.

Immunoblotting studies of the molecular forms of protein C in plasma.

Anti-plasma protein C monoclonal antibodies were prepared and characterized, and quantitative immunoblotting techniques were developed to determine the molecular forms of protein C in whole plasma. Two antibodies reacted with the heavy chain of protein C, four reacted with the light chain, and two reacted only with nonreduced protein C. A doublet of protein C (MW = 63-66K) was seen on nonreduced immunoblots of normal plasma and 30 heterozygous protein C deficient plasmas (2-77% protein C antigen). In reduced plasma, approximately 75% of protein C presented as doublet heavy chains (MW = 39-42K) and doublet light chains (MW = 22-25K), and approximately 25% was single chain (MW = 64K). The immunoblotting technique was quantitative, specific, sensitive, and correlated with electroimmunoassay results. It also provided visual qualitative information not obtainable with other methods of quantitation.

Quantitative immunoblotting assay of blood coagulation factor XII.

The immunoblotting technique was applied to the study of Factor XII (F.XII) in plasma. Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) of whole plasma followed by electroblotting of the electropherograms to nitrocellulose (NC) membranes and immunologic detection by a double antibody technique was used. 125I-F.XII was transferred to the NC membrane in amounts proportional to the amount applied to the gel provided that a constant amount of carrier protein was present. Based on this, a quantitative assay was developed using either normal plasma or F.XII dilutions in F.XII-deficient plasma as standards. The measurement of F.XII antigen by immunoblotting was reproducible and gave values similar to those obtained by radial immunodiffusion. Two normal plasma pools contained 26 and 29 micrograms/ml of F.XII according to the immunoblotting assay. Compared to other immunoassays, immunoblotting has the advantage of directly estimating the apparent molecular weight (MW) of the protein of interest. Thus, we could confirm the normal apparent MW (80,000) of a F.XII-like molecule previously isolated from a cross reacting material (CRM)-positive F.XII-deficient plasma. None of eight CRM-negative F.XII-deficient plasmas showed an 80,000 MW immunoreactive molecule. However, five of these eight plasmas had a faint autoradiographic band at 115,000 MW that was similarly seen in only three out of 43 individual normal plasmas. The nature of this 115,000 MW band remains to be defined.

Antithrombotic activity of protein S infused without activated protein C in a baboon thrombosis model.

Protein S (ProS) is an essential plasma protein that enhances the anticoagulant activity of activated protein C (APC). In vitro , purified native human Zn2+-containing ProS also exerts direct anticoagulant activity by inhibiting prothrombinase and extrinsic FXase activities independently of APC. We investigated antithrombotic effects of ProS infused without APC in a baboon shunt model of thrombogenesis that employs a device consisting of arterial and venous shear flow segments. In in vitro experiments, the Zn2+-containing human ProS used for the studies displayed >10-fold higher prothrombinase inhibitory activity and anticoagulant activity in tissue factor-stimulated plasma, and four-fold higher inhibition of the intrinsic pathway than the Zn2+-deficient ProS used. In the thrombosis model, ProS (33 µg/minute for 1 hour) or saline was infused locally; platelet and fibrin deposition in the shunt were measured over 2 hours. During experiments performed at 50 ml/minute blood flow, Zn2+-containing ProS inhibited platelet deposition 73-96% in arterial-type flow segments and 90-99% in venous-type flow segments; Zn2+-deficient ProS inhibited platelet deposition 52% in arterial-type flow segments and 65-73% in venous-type flow segments. At 100 ml/min blood flow rate, Zn2+-containing ProS inhibited platelet deposition by 39% and 73% in the respective segments; Zn2+-deficient ProS inhibited platelet deposition by 5% and 0% in the respective segments. Zn2+-containing ProS suppressed fibrin deposition by 67-90%. Systemic APC-independent ProS activity was significantly increased and thrombin-antithrombin complex levels were significantly decreased after infusion of ProS. Thus, infused human Zn2+-containing ProS is antithrombotic in primates, and may have therapeutic potential even in protein C-deficient human patients.

Zn²(+) -containing protein S inhibits extrinsic factor X-activating complex independently of tissue factor pathway inhibitor.

BACKGROUND: Protein S (PS) has direct anticoagulant activity, independently of activated protein C (APC). The mechanisms underlying this activity remain unclear, because PS preparations differ in activity, giving rise to conflicting results. Some purification procedures result in loss of intramolecular Zn²(+) , which is essential for inhibition of prothrombinase. OBJECTIVE: To investigate the inhibition of extrinsic factor (F)Xase by Zn²(+) -containing PS. METHODS: Purified component extrinsic FXase assays were used to determine FXa generation in the presence and absence of PS and/or tissue factor pathway inhibitor (TFPI). Binding assays, immunoblots and thrombin generation assays in plasma supported the FXase data. RESULTS: Zn²(+) -containing PS potently inhibited extrinsic FXase in the presence of saturating phospholipids, independently of TFPI, whereas inhibition of extrinsic FXase by Zn²(+) -deficient PS required TFPI. Immunoblots for FXa and functional assays showed that Zn²(+) -containing PS inhibited primarily the quantity of FXa formed by tissue factor (TF)-FVIIa, rather than FXa amidolytic activity. Zn²(+) -containing PS, but not Zn²(+) -deficient PS, bound to TF with high affinity (K(dapp) = 41 nm) and targeted TF function. Binding of PS to FVIIa was negligible, whereas PS showed appreciable binding to FX. Increasing FX concentrations 10-fold reduced PS inhibition five-fold, suggesting that PS inhibition of FXase is FX-dependent. PS also exhibited TFPI-independent and APC-independent anticoagulant activity during TF-initiated thrombin generation in plasma. CONCLUSIONS: PS that retains native Zn²(+) also retains anticoagulant functions independently of APC and TFPI. Inhibition of extrinsic FXase by PS at saturating levels of phospholipids depends on PS retention of intramolecular Zn²(+) , interaction with FX, and, particularly, interaction with TF.

Physiologic inhibition of human activated protein C by alpha 1-antitrypsin.

The plasma antithrombotic enzyme activated protein C (APC) has two major plasma inhibitors. One is heparin-dependent, has been characterized, and is known as protein C inhibitor. The second inhibitor was isolated based on its heparin-independent ability to inhibit and complex with APC. The purified inhibitor had the amino acid composition and NH2 terminus of alpha 1-antitrypsin and reacted with monoclonal antibodies to alpha 1-antitrypsin. The inhibitor was greater than 95% pure alpha 1-antitrypsin as judged by electroimmunoassay, inactivation of trypsin, and electrophoresis in two gel systems. To identify the second major plasma inhibitor of APC, immunoblot studies of enzyme-inhibitor complexes were made to compare APC addition to normal plasma and to plasma deficient in protein C inhibitor or alpha 1-antitrypsin. The results showed that alpha 1-antitrypsin is the second major plasma APC inhibitor. Given the association rate constant of alpha 1-antitrypsin for APC of 10 M-1 s-1 and its plasma concentration of approximately 40 microM, it accounts for approximately half of the heparin-independent APC inhibitory activity of plasma. Based on immunoblot analysis plasmas of 15 patients with intravascular coagulation contained APC-alpha 1-antitrypsin complexes suggesting that this inhibition reaction occurs in vivo. Thus, alpha 1-antitrypsin is a major physiologic inhibitor of APC.

alpha2-macroglobulin and C1-inactivator are plasma inhibitors of human glandular kallikrein.

Human glandular kallikrein (hK2) is a possible new marker for prostate cancer that is homologous to prostate specific antigen. Purified hK2 added to serum or plasma reacted with endogenous protease inhibitors to form complexes of >350, 135, and 80 kDa, and some hK2 remained free, as judged by immunoblotting. The former two complexes could be removed by specific antibodies to alpha2-macroglobulin and to C1- inactivator, respectively, and they comigrated on SDS-PAGE with complexes formed between hK2 and purified alpha2-macroglobulin or C1-inactivator. hK2 complexes of 80 kDa could not be completely removed with any anti-serpin antibody used. Thus, these may consist of more than one type of hK2 complex. In contrast, essentially all hK2 complexes were removed from seminal plasma by antibody to protein C inhibitor, demonstrating that protein C inhibitor is the only significant inhibitor of hK2 in semen. hK2 reacted more rapidly with alpha2-macroglobulin than with any other inhibitor in plasma or serum. Divalent metal ions and heparin did not appreciably affect the rate of formation of any of the hK2 complexes in serum or plasma or with purified alpha2-macroglobulin or C1-inactivator. Measurement of one or more of the hK2 forms identified here may have diagnostic or prognostic potential for prostate cancer.

Activation and complexation of protein C and cleavage and decrease of protein S in plasma of patients with intravascular coagulation.

Activated protein C (APC) is inhibited by two major plasma inhibitors (PCIs). To find evidence for in vivo complexation of APC, immunoblotting studies were performed on plasmas of 85 patients with suspected disseminated intravascular coagulation (DIC). Samples from 62 of these patients contained 5% to 35% of protein C antigen in APC:inhibitor complexes, indicating that protein C activation and inhibition had occurred. In 24 normal plasmas, no detectable APC:PCI complexes were observed (less than 5%). Patients with higher levels of complexes had more abnormal coagulation test data for DIC. The major band of APC complexes detected by anti-protein C antibodies did not react with antibodies to the heparin-dependent protein C inhibitor (PCI-1) previously described. Rather, APC was complexed with another recently described plasma protein C inhibitor, PCI-2. Immunoblotting studies for protein S, the cofactor for APC, revealed that the majority of the DIC patient plasmas contained a higher than normal proportion of protein S in cleaved form, suggesting that protein S may have been proteolytically inactivated. Protein S total antigen levels were also found to be low in DIC patients, excluding those with malignancy. These studies support the hypothesis that the protein C pathway is activated during DIC.

Factors affecting binding of galacto ligands to Actinomyces viscosus lectin.

The specificity requirements for the binding of Actinomyces viscosus T14V were examined by testing simple sugars, oligopeptides, and glycoproteins as inhibitors of the aggregation of glycoprotein-coated latex beads and washed A. viscosus cells. Lactose was the most inhibitory simple sugar; D-fucose and D-galactose were equally inhibitory, methyl-alpha-D-fucoside was slightly less inhibitory, and L-fucose and raffinose were not inhibitory. The concentration of galactose residues required for 50% inhibition of aggregation was 15 times higher in the form of lactose than in the form of asialoglycoprotein, suggesting an enhancement of lectin binding when galactose residues are clustered. However, when the inhibitory power of bi-, tri-, and tetraantennary asialooligopeptides of alpha 1-acid glycoprotein was compared with that of equivalent concentrations of galactose in the form of lactose, the biantennary form was slightly less effective than lactose, the triantennary form was approximately as effective as lactose, and the tetraantennary form was slightly more effective than lactose. Steric interference may prevent this type of clustering from enhancing lectin binding. The O-linked asialooligopeptides of asialofetuin were 10 times more inhibitory than an equivalent concentration of galactose in the form of N-linked asialooligopeptides. Thus, galactose beta-1----3 linked to N-acetylgalactosamine exhibits greater specificity for the A. viscosus lectin than does galactose beta-1----4 linked to N-acetylglucosamine. These results, taken together with previously reported data, are consistent with a lectin of low affinity, binding enhanced by multivalency, and specificity for beta-linked galactose.