Antithrombotic Effect of a Protein-Type I Class Snake Venom Metalloproteinase, Kistomin, Is Mediated by Affecting Glycoprotein Ib-von Willebrand Factor Interaction

Chun-Chieh Hsu, Wen-Bin Wu, Ya-Hui Chang, Heng-Lan Kuo, and Tur-Fu Huang

Department of Pharmacology, College of Medicine, National Taiwan University, Taipei, Taiwan (C.-C.H., Y.-H.C., H.-L.K., T.-F.H); and School of Medicine, Fu-Jen Catholic University, Taipei County, Taiwan (W.-B.W.)

Received May 10, 2007; accepted July 3, 2007

Abstract

Top
Abstract
Materials and Methods
Results
Discussion
References

Binding of von Willebrand factor (vWF) to platelet glycoprotein(GP) Ib-IX-V mediates platelet activation in the early stageof thrombus formation. Kistomin, a snake venom metalloproteinase(SVMP) purified from venom of Calloselasma rhodostoma, has beenshown to inhibit vWF-induced platelet aggregation. However,its action mechanism, structure-function relationship, and invivo antithrombotic effects are still largely unknown. In thepresent study, cDNA encoding kistomin precursor was cloned andrevealed that kistomin is a P-I class SVMP with only a proteinasedomain. Further analysis indicated that kistomin specificallyinhibited vWF-induced platelet aggregation through binding andcleavage of platelet GPIb ${alpha}$ and vWF. Cleavage of platelet GPIb ${alpha}$ by kistomin resulted in release of 45- and 130-kDa soluble fragments,indicating that kistomin cleaves GPIb ${alpha}$ at two distinct sites.In parallel, cleavage of vWF by kistomin also resulted in theformation of low-molecular-mass multimers of vWF. In ex vivoand in vivo studies, kistomin cleaved platelet GPIb ${alpha}$ in wholeblood. Moreover, GPIb ${alpha}$ agonist-induced platelet aggregation exvivo was inhibited, and tail-bleeding time was prolonged inmice administered kistomin intravenously. Kistomin's in vivoantithrombotic effect was also evidenced by prolonging the occlusiontime in mesenteric microvessels of mice. In conclusion, kistomin,a P-I class metalloproteinase, has a relative specificity forGPIb ${alpha}$ and vWF and its proteolytic activity on GPIb ${alpha}$ -vWF is responsiblefor its antithrombotic activity both in vitro and in vivo. Kistomincan be useful as a tool for studying metalloproteinase-substrateinteractions and has a potential being developed as an antithromboticagent.

Platelets play a key role in hemostasis and thrombosis. Exposureof subendothelial von Willebrand factor (vWF) is the first stepto form thrombi to arrest blood loss at the sites of trauma,but abnormal embolism may also cause ischemia in pathogeniccondition (Andrews and Berndt, 2004

). The glycoprotein (GP)Ib complex (one of the major adhesive receptors expressed onplatelets) that interacts with vWF is composed of GPIb ${alpha}$ , GPIbβ,GPIX, and GPV. GPIb ${alpha}$ consists of N-terminal flank, leucine-richrepeat, anionic sulfated tyrosine sequence, macroglycopeptidedomain, transmembrane region, and cytoplasmic tail (Andrewset al., 2003

). Plasma vWF circulates primarily as the dimerform, and the multimeric forms of vWF are existed in the subendothelialmatrix (Canobbio et al., 2004

). It has been reported that Bernard-Souliersyndrome and platelet-type von Willebrand disease are inheritedbleeding disorders caused by mutations in GPIb complex and vWFgene, respectively, suggesting that GPIb-vWF interaction isvery important for hemostasis. Therefore, modulation of theGPIb ${alpha}$ -vWF interactions during thrombotic complications couldbe beneficial (Bonnefoy et al., 2003

). However, in contrastto extensive application of ${alpha}$ IIbβ3 antagonists during acutecoronary diseases, no GPIb ${alpha}$ -vWF axis inhibitor is commerciallyavailable, although some GPIb ${alpha}$ or vWF antagonists are being developed.

Snake venom proteases are invaluable tools for studying coagulationand hemostasis (Marsh, 2001). For examples, fibrinogen and antithrombinIII can be assayed by using snake venom thrombin-like enzymes.Among these snake-derived proteases, snake venom metalloproteinases(SVMPs), which are abundant in venoms from Viperidae and Crotalinae,are key enzymes responsible for local hemorrhage and are metalion-dependent for their full function (Matsui et al., 2000;Kamiguti, 2005). The protein structural classification of SVMPsis presented as protein-type I (P-I; having only metalloproteinasedomain), P-II (having metalloproteinase and disintegrin domain),P-III (having metalloproteinase, disintegrin-like and cysteine-richdomain), and P-IV (having P-III structure plus lectin-like domainsconnected by disulfide bonds) (Fox and Serrano, 2005). It hasbeen suggested that the additional disintegrin-like and thecysteine-rich regions domains may direct SVMP to its targets(Fox and Serrano, 2005). However, its structure-activity relationshipremains unclear.

Kistomin, a 25-kDa SVMP purified from Calloselasma rhodostomavenom in our laboratory, has been shown to degrade fibrinogenand inhibit ristocetin-induced platelet agglutination, suggestingthat it is a GPIb-cleaving protease (Huang et al., 1993). However,its action mechanism, structure-function relationship, and invivo antithrombotic effects are still largely unknown. In thisstudy, cDNA-encoding kistomin was cloned and kistomin's cleavingand binding specificities for vWF and GP Ib ${alpha}$ were demonstrated.More importantly, kistomin's antithromblotic effect was examinedin an in vivo animal model.

Materials and Methods

Top
Abstract
Materials and Methods
Results
Discussion
References

Materials. Anti-GPIb ${alpha}$ mAb M45 and SZ2, directed to the sulfatedtyrosine residues of GPIb ${alpha}$ and inhibited ristocetin-dependentbinding of vWF to GPIb ${alpha}$ , were obtained from CLB Immunoreagentia(Amsterdam, The Netherlands) and Immunotech (Marseilles, France),respectively. The murine mAb against ${alpha}$ 2β1, 6F1, was kindlyprovided by Dr. Barry S. Coller (Mount Sinai School of Medicine,New York, NY). FITC-conjugated goat anti-mouse IgG was fromSanta Cruz Biotechnology, Inc. (Santa Cruz, CA). Heparin wasfrom Thermo Fisher Scientific (Waltham, MA). Human purifiedvWF and fibrinogen were from Calbiochem (San Diego, CA). Enhancedchemiluminescence (ECL) Western blotting system was from PerkinElmerLife and Analytical Sciences (Waltham, MA). Other chemicalswere purchased from Sigma Chemicals, Co. (St Louis, Mo).

Venoms of C. rhodostoma, Crotalus atrox, and Trimeresurus flavoviridiswere from Latoxan (Rosans, France). Kistomin was purified fromcrude venom of C. rhodostoma as described previously (Huanget al., 1993), migrating as a single band at 25 kDa on SDS-polyacrylamidegel electrophoresis assay. Crotalin (Wu et al., 2001b) and triflamp(Tseng et al., 2004a) were purified from C. atrox and T. flavoviridis,respectively.

Protein Sequencing of the Fragmented Kistomin and cDNA Cloningof Kistomin Precursor. Protein sequencing of the fragmentedkistomin was performed as described previously (Wu et al., 2001a).In brief, fragmented kistomin was obtained by alkylation withvinylpyridine and followed by incubation with CNBr. The fragmentswere applied to high-performance liquid chromatography, andthe major fraction was subjected to protein sequencing. Forsequencing of the autoproteolytic fragment of kistomin, kistominwas auto-proteolyted in 1% SDS and 0.5 M Tris-HCl solution,transblotted onto PVDF membrane, and then analyzed by sequencing.

Total RNA was isolated from C. rhodostoma venom glands witha BlueExtract kit (LTK BioLaboratories Co., Ltd, Linko, Taipei,Taiwan). cDNA was synthesized from 1.5 mg of the total RNA andused to construct a cDNA library in the Uni-ZAP XR vector (Stratagene,La Jolla, CA).

To obtain cDNA of putative SVMP, recombinant ${lambda}$ DNA species wereprepared from the cDNA library and used as templates in PCR.Primers for the first screening of cDNA library were 5'-TCCATCGAAGTC(G/A)TTGTT(G/A)AA-3'and 5'-TCAGGTTGG(C/T)TTGAAAGCAGG-3'. Amplification was performedby using Taq DNA polymerse (Ab Peptides, St. Louis, MO) andthe primers with a hot start at 94°C for 10 min and 30 cyclesof denaturation (1 min, at 94°C), annealing (1 min, at 50°C),and extension (2 min, at 72°C). Primers for the second amplificationof the 3'-end of the precursor cDNA of kistomin were 5'-GCGGATAAAAGCATGGTTGA-3'and M13 forward primer. PCR was performed under the same conditions,except that the primer-annealing temperature was set at 45°C.The final PCR products were analyzed by 1% (w/v) agarose-gelelectrophoresis and purified by electroelution. The purifiedDNA fragments were ligated to pcRII-TOPO vector with a Thermusaquaticus cloning kit (Invitrogen, Carlsbad, CA), and sequenceanalysis was performed. The specificity of the second amplificationwas confirmed from the overlapping sequences that were distinguishablefrom the other SVMPs. Sequences were assembled with the GCGprogram (Wisconsin Package version 10.1; Genetics Computer Group).

Platelet Aggregation. Blood was collected from healthy humanvolunteers and anticoagulated with 3.8% sodium citrate [9:1(v/v)]. Citrated blood was immediately centrifuged for 10 minat 120g and 25°C, and the supernatant [platelet-rich plasma(PRP)] was obtained. Human washed platelet suspension (PS) wasprepared as described previously (Liu et al., 1996) and adjustedto approximately 3.8 x 10⁸ platelets/ml. Platelet aggregationwas monitored by light transmission in a Lumi-Aggregometer (Chrono-Log,Havertown, PA) with continuous stirring at 900 rpm at 37°Cas described previously (Liu et al., 1996).

For ex vivo assay of mouse platelet aggregation, male ICR mice(12–15 g) were intravenously injected with different dosageof kistomin. After 20 min, mouse was anesthetized with sodiumpentobarbital (50 µg/g, ip), and blood was collected bycardiac puncture. PRP was obtained by centrifugation at 200gfor 4 min at room temperature. After washing twice with Tyrode'ssolution, platelet suspension was adjusted to approximately5 x 10⁸ platelets/ml, and aggregation was measured turbidimetrically.

Flow Cytometric Analysis of Platelet Receptor Expression. Washedhuman platelets were prepared as described above. PS (3.8 x10⁸ platelets/ml) containing 2 µM PGE₁ was incubated withkistomin 20 µg/ml at 37°C for 10 min. After an extensivewash, platelets were labeled with mAb against GPIb ${alpha}$ (SZ2), ${alpha}$ IIbβ3(7E3), or ${alpha}$ 2β1 integrin (6F1) at room temperature (RT) for30 min. Labeled cells were washed with Tyrode's solution andthen incubated with secondary FITC-conjugated goat antimouseIgG (CALTAG Lab, Burlingame, CA) RT for 30 min with a continuousshaking. After incubation, cells were washed, resuspended inphosphate-buffered saline (PBS), and analyzed immediately byFACSCalibur (BD Biosciences, San Jose, CA).

Western Blot Analysis of Platelet GPIb ${alpha}$ . Platelet suspensionwas centrifuged at 200g for 5 min. After removing the supernatant,pellets were lysed by 1% Triton X-100 buffer (in PBS). Aliquotsof cell lysates and supernatants were resolved on 10% SDS-PAGEunder reducing conditions and electrotransferred to Immobilon-PVDFmembrane (Millipore). After blocking in a 0.5% BSA in Tri-bufferedsaline 1 h at 4°C, the blots were probed with anti-GPIb ${alpha}$ mAb (1:1000) for overnight at 4°C and followed by the horseradishperoxidase-goat anti-mouse IgG. The protein was visualized byadding enhanced chemiluminescence (ECL) solution (Pierce, Rockford,IL).

Determination of Kistomin Binding to Platelet GPIb ${alpha}$ . For determinationof the interaction between kistomin and GPIb ${alpha}$ , flow cytometricand Western blot analysis were performed. For flow cytometry,platelets were incubated with or without kistomin at 4°Cand followed by probing with FITC-conjugated anti-GPIb ${alpha}$ mAb,M45. Cells were analyzed immediately by FACS Calibur (BD Biosciences).For Western blot analysis, kistomin (20 µg) and agglucetin(15 µg) were applied to 15% SDS-PAGE and transferred ontoa PVDF membrane. Platelets lysate was obtained by lysis of plateletpellet in lysis buffer (10 mM HEPES buffer containing 10% SDS,10 mM N-ethylmaleimide, 20 mM Na₃VO₄, 20 mM EDTA, and 10 mMphenylmethylsulfonyl fluoride). The membrane was blocked with1% bovine serum albumin and then incubated with platelet lysatefor 1 h at RT. After a brief wash, the membrane was probed withanti-GPIb ${alpha}$ SZ2 mAb and developed by ECL.

Cleavage of vWF by Kistomin. Purified human vWF (1.5 µg)incubated with or without kistomin were analyzed as describedpreviously (Wu et al., 2001b) with a minor modification. Inbrief, aliquots of the mixture were analyzed by SDS-1% agarosegel electrophoresis ( $~$ 2 mm) in a Mupid-2 Mini-Gel system (CosmoBio Co., Ltd, Tokyo, Japan) and electroblotted onto PVDF membrane.Immunoblots were developed with peroxidase-conjugated antihumanvWF antibody (DAKOpatts, Glostrup, Denmark).

Fluorescent Dye-induced Platelet Thrombus Formation in MesentericMicrovessels of Mice. Fluorescent dye-induced platelet thrombusformation in mesenteric microvessels of mice was performed asdescribed previously (Chang and Huang, 1994) with some modifications.In brief, after male ICR mice (12–15 g) were anesthetizedwith sodium pentobarbital (50 µg/g, i.p.), fluoresceinsodium (12.5 µg/g) was i.v. injected. A segment of smallintestine attached to its mesentery was loosely exteriorizedfor microscopic observation. Venules with diameters of 30 to40 µm were selected to produce a microthrombus. In theepi-illumination system, the area of irradiation (wavelengthabove 520 nm) was approximately 50 µm in diameter on thefocal plane. After the operation (15 min), the mouse was intravenouslyinjected with PBS (control, 30 µl), aspirin, or kistominthrough another lateral tail vein of the mouse. Five minutesafter administration of these drugs, the irradiation by filteredlight and the occlusion time was recorded.

Tail Bleeding Time. After anesthesia with sodium pentobarbital(50 µg/g, ip), male ICR mice (12–15 g) were intravenouslyinjected with PBS (vehicle, 30 µl), aspirin, or kistominthrough a lateral tail vein. After 5 min, the mouse was placedin a tube holder with its tail protruding, and then a cut 2mm from the tail tip was made. The tail was immediately immersedvertically in normal saline at 37°C. Bleeding time was recordedfrom the time bleeding started until it completely stopped.

Results

Top
Abstract
Materials and Methods
Results
Discussion
References

Protein Sequencing and cDNA Cloning of Kistomin. To have aninsight on kistomin's primary structure, protein sequencingwas performed. A 14-kDa autoproteolytic fragment from kistominwas sequenced, and its N-terminal was revealed as LSKRKPHNDAQFLTNKDFDG(fragment 1). Moreover, two peptide sequences, VDKHNGNIKKIE(fragment 2) and APEVNNNPTKKFSDC (fragment 3), were obtainedfrom CNBr digestion of kistomin.

To further determine the cDNA sequence of kistomin precursor,cDNA cloning was performed. Two primers in accordance with theconserved PKMCGV sequence of SVMP and the autoproteolytic fragmentwere used in the first amplification of kistomin cDNA. Afterscreening of the C. rhodostoma cDNA library, a clone with approximately $~$ 900 bp was obtained, representing the kistomin precursor presequencecontaining the partial metalloproteinase domain of kistomin(data not shown). To obtain the remaining cDNA sequence of kistomin,a pair of primers according to the sequences from kistomin-CNBr-digestedfragment (VDKHNGNIKKIE) and vector was used. Figure 1 showedthe assembled cDNA sequence and the deduced amino acid sequenceof the kistomin precursor. Three partial sequences obtainedfrom direct protein sequencing were found in the deduced aminoacid sequence with 100% identity (Fig. 1, underlined sequences),indicting that it is a kistomin precursor. The precursor, designatedprokistomin, consists of a presequence, prosequence, and a metalloproteinasedomain and belongs to a P-I SVMP. A putative start site wasindicated, and mature kistomin predicted from this site was227 residues (Fig. 1), which was estimated to be 25.7 kDa. Thededuced amino acid sequence of prokistomin contains the characteristiczinc-chelating sequence HEIGHNLGMEHD (Fig. 1, catalytic site),which is similar to that of other SVMPs, such as fibrolase (Randolphet al., 1992) and jararhagin (Paine et al., 1992).

View larger version (62K):
[in this window]
[in a new window]

Fig. 1. cDNA sequence and deduced amino acid sequence of the putative protein precursor of kistomin. The sequence shown begins with the presequence, and the translation stop codon is indicated by an asterisk (*). Three fragments from CNBr-digested and autoproteolytic kistomin are indicated by underlines.

Kistomin Inhibited Ristocetin-Induced Platelet Agglutinationand Aggregation. To re-examine kistomin's activity in inhibitingplatelet function, PS agglutination and PRP aggregation wereperformed. As shown in Fig. 2, kistomin concentration-dependentlyinhibited ristocetin-induced platelet agglutination and aggregationwith a half-maximal inhibition concentration (IC₅₀) at 2.04µg/ml (0.079 µM) and 8.25 µg/ml (0.321 µM),respectively. However, this inhibition was abolished by thetreatment of kistomin with EDTA or o-phenanthrolene (data notshown), indicating the involvement of an enzymatic reaction.

View larger version (18K):
[in this window]
[in a new window]

Fig. 2. Effect of kistomin on ristocetin-induced platelet agglutination and aggregation. Washed PS (A) and PRP (B) were pretreated with various concentrations of kistomin before the addition of ristocetin (1 mg/ml, arrow). Platelet agglutination and aggregation were monitored by turbidimetry in aggregometer. C and D, quantitative analysis of the data from A and B and similar experiments were performed. Data are presented as percentage of control and are mean ± S.E.M. (n $≥$ 3).

Kistomin Cleaved Platelet GPIb ${alpha}$ . To further elucidate the possibleaction mechanism of kistomin in inhibiting ristocetin-inducedplatelet aggregation, GPIb ${alpha}$ expression on platelets was analyzedby flow cytometry and Western blotting. As depicted in immunofluorescencestaining with anti-GPIb ${alpha}$ mAb SZ2, kistomin treatment rapidlyreduced the level of GPIb ${alpha}$ expression on platelets, whereas theexpression of the other two important platelet receptors, namely ${alpha}$ IIbβ3 and ${alpha}$ 2β1 integrins, was not affected (Fig. 3A).

View larger version (36K):
[in this window]
[in a new window]

Fig. 3. Effect of kistomin on platelet GPIb ${alpha}$ . A, flow cytometric analysis of GPIb ${alpha}$ expression on platelets. Washed platelets treated with PBS (gray area) or kistomin (5 µg/ml, open area) at 37°C for 10 min were incubated with anti-GPIb ${alpha}$ (SZ2), anti- ${alpha}$ IIbβ3 (7E3) or anti- ${alpha}$ 2β1 (6F1) mAbs and subjected to be analyzed by flow cytometry. B and C, Western blot analysis of GPIb ${alpha}$ expression on platelets. Washed platelets were treated with kistomin (20 µg/ml) at 37°C for (B) different duration as indicated or (C) for 30 min in the absence or presence of EDTA. Total cell lysates, cells pellets (P), and supernatant (S) were obtained as described under Materials and Methods and analyzed by Western blotting. An arrowhead indicates an intact GPIb ${alpha}$ expression on platelet. Note that 130-kDa (open arrowheads) and 45-kDa fragments (arrows) were observed in total cell lysates (B) and in the supernatant (C) of kistomin-treated platelets. This experiment is representative of at least three similar experiments.

To characterize the proteolytic properties of kistomin on plateletGPIb ${alpha}$ , Western blotting was performed. It was found that plateletintact GPIb ${alpha}$ ( $~$ 140 kDa) was cleaved by kistomin in a time-dependentmanner, which could be abolished by EDTA (Fig. 3B). One intactGPIb ${alpha}$ and two fragments migrated at molecular masses of $~$ 140, $~$ 130, and $~$ 45 kDa, respectively, were detected by anti-GPIb ${alpha}$ SZ2mAb in total platelet lysate (arrows). We were surprised tofind that only two fragments ( $~$ 130 and $~$ 45 kDa) were detectedin supernatant (Fig. 3C), indicating that kistomin cleaves plateletGPIb ${alpha}$ at two distinct sites to generate two soluble fragments,which can be recognized by the SZ2 mAb.

Binding of Kistomin to GPIb ${alpha}$ . Because platelet GPIb ${alpha}$ was cleavedby kistomin, we next investigated whether kistomin bound toGPIb ${alpha}$ . To stop kistomin's enzymatic activity, the experimentwas performed at 4°C. Under this condition, kistomin boundto GPIb ${alpha}$ and replaced anti-GPIb ${alpha}$ M45 mAb binding to plateletsin a concentration-dependent manner (Fig. 4A). Binding of kistominto GPIb ${alpha}$ concentration-dependently increased and reached saturationat the concentrations more than 20 µg/ml (Fig. 4B). Thisresult was confirmed by the observation that immobilized kistomindirectly interacted with GPIb ${alpha}$ in platelet lysate. It is noteworthythat this binding was not affected in the presence of EDTA (Fig. 4C),suggesting that bivalent cations are not required in this interaction.A similar binding ability was also found in immobilized agglucetin,a tetrameric GPIb ${alpha}$ -binding protein from A. acutus (Wang and Huang,2001), in which it migrated as two distinct bands at 16.2 and14.5 kDa (Fig. 4, lane 3). In contrast, rhodostomin, an RGD-containingdisintegrin purified from C. rhodostoma venom (Huang et al.,1987), failed to bind platelet GPIb ${alpha}$ (data not shown).

View larger version (35K):
[in this window]
[in a new window]

Fig. 4. Kistomin binds to platelet GP Ib ${alpha}$ . A, kistomin competitively replaced anti-GPIb ${alpha}$ mAb binding to platelets. Human washed platelets were incubated with PBS (gray area) or various concentrations of kistomin (open areas, 15, 30, and 60 µg/ml) at 4°C for 30 min, followed by incubation with FITC-conjugated anti-GPIb ${alpha}$ mAb, M45, and then analyzed by flow cytometry. The histogram was representative from three similar experiments. B, quantitative analysis of binding assay data from A and similar experiments were performed. Data were expressed as mean fluorescence and were mean ± S.E. (n = 3) C, platelet GPIb ${alpha}$ bound to immobilized kistomin. Kistomin (Kis, 20 µg) pretreated with vehicle or EDTA (10 mM) and agglucetin (agg, 15 µg) were applied to SDS-PAGE and transferred to PVDF membrane. The membrane was incubated with platelet total lysate and followed by Western blot analysis using anti-GPIb ${alpha}$ mAb, SZ2. This experiment is a representative one of at least three similar experiments.

Effect of Kistomin on the Multimeric Structure of vWF. We haveshown that kistomin could bind and cleave platelet GPIb ${alpha}$ (Fig.3 and 4). To further examine whether kistomin affected multimericstructure of vWF, human vWF preincubated with or without kistominwas added to platelet suspension and ristocetin-induced plateletagglutination was measured. Figure 5A showed that ristocetin-inducedagglutination was time-dependently reduced under this conditionbut almost fully restored by re-adding a new intact vWF. Furtheranalysis revealed that high-molecular-mass multimers of vWFobviously decreased and the low-molecular-mass multimers concomitantlyincreased in the presence of kistomin (Fig. 5B, lanes 1 and2). Again, the cleavage of vWF by kistomin was abolished inthe presence of EDTA or o-phenanthrolene (Fig. 5B, lanes 3 and4). Taken together, our results indicate that kistomin can bindand cleave platelet GPIb ${alpha}$ and vWF and subsequently inhibits vWF-inducedplatelet agglutination and aggregation.

View larger version (31K):
[in this window]
[in a new window]

Fig. 5. Effect of kistomin on the multimeric structure of vWF. A, pretreatment of vWF with kistomin compromised vWF-induced platelet aggregation. Washed human platelets was incubated with kistomin (3 µg/ml)-pretreated vWF (10 µg/ml) at 37°C for the indicated times and ristocetin (ris, 1 mg/ml) was added to induce platelet aggregation. In the case of prior coincubation of vWF and kistomin for 20 min, intact vWF (10 µg/ml, arrow) was readded 3 min after addition of ristocetin. B, kistomin cleaved the mulitmeric structure of vWF. Human vWF (0.5 µg) was incubated at 37°C for 30 min with PBS (lane 1), kistomin (15 µg/ml, lane 2), EDTA (10 mM)-treated kistomin (lane 3), or o-phenanthrolene (10 mM)-treated kistomin (lane 4). Aliquots of each reaction mixture were subjected to SDS-1% agarose electrophoresis and vWF multimer were detected by peroxidase-conjugated anti-vWF antibody after blotting to a PVDF membrane. This experiment is representative of at least three similar experiments.

Kistomin Affected Thrombosis and Hemostasis in Vivo. We nextinvestigated whether kistomin exerted antithrombotic effectin vivo. It was shown that kistomin potently decreased antibodybinding to platelet GPIb ${alpha}$ in human whole blood, whereas crotalinand triflamp, two P-I SVMPs purified from venom of C. atrox(Wu et al., 2001b) and T. flavoviridis (Tseng et al., 2004a),respectively, were less effective at the same concentrationin cleaving GPIb ${alpha}$ (Fig. 6). We therefore hypothesized that kistomincould be an active protease in both in vitro and in vivo conditions.To confirm this hypothesis, we measured ex vivo platelet aggregationin PRP or PS prepared from kistomin-pretreated mouse. Becauseristocetin is ineffective in causing platelet aggregation inmouse PRP, a snake venom-derived GPIb ${alpha}$ agonist, gramicetin, wasused in this assay (Wu et al., 2001a). As shown in Fig. 7A,gramicetin-induced platelet agglutination was inhibited by theGPIb ${alpha}$ antagonist, agkistin, suggesting that a GPIb ${alpha}$ -mediated pathwaywas involved in this agglutination. The agglutination was suppressedin PRP prepared from mouse treated with kistomin (Fig. 7B);however, collagen-, ADP-, convulxin- and thrombin-induced plateletaggregation was not significantly affected (Fig. 7, C–F).Thus, kistomin impaired mouse platelet function specificallythrough affecting GPIb ${alpha}$ in vivo.

View larger version (28K):
[in this window]
[in a new window]

Fig. 6. Kistomin cleaves GPIb ${alpha}$ in whole blood. Human whole blood was pretreated with PBS (gray area) and the indicated SVMPs (open areas, 100 µg/ml for each) at 37°C for 15 min. Samples were probed by FITC-conjugated anti-GPIb ${alpha}$ M45 antibody and immediately analyzed by flow cytometry. This experiment is representative of at least three similar experiments.

View larger version (15K):
[in this window]
[in a new window]

Fig. 7. Ex vivo test regarding the effects of kistomin on mouse platelets. A, GP Ib ${alpha}$ antagonist inhibited gramicetin-induced platelet agglutination. Mouse PRP was treated with PBS or agkistin (5 µg/ml) and platelet agglutination was induced by adding gramicetin (1 µg/ml, solid arrow). B, PRP was prepared from mice treated with vehicle or the indicated doses of kistomin and gramicetin-induced platelet agglutination was measured by aggregometry. PRP (C–E) or PS (F) was prepared from mice treated with vehicle or kistomin (kis; 7 µg/g). Induction of platelet aggregation was done by adding collagen (10 µg/ml), ADP (20 µM), convulxin (cvx; 1.5 µg/ml), and thrombin (0.1 U) and was measured by aggregometry. This experiment is representative of at least three similar experiments.

We then determined kistomin's antithrombotic effects in vivo.In fluorescent dye-treated mice, thrombus formation was observedin irradiated mesenteric venules of mice. The occlusion timeof irradiated vessels was 134.3 ± 6.2 s in control mice(n = 12) but was prolonged to 173.2 ± 26.7 s (n = 13)and 301.9 ± 43.5 s (n = 10) by aspirin at doses of 150and 250 µg/g, respectively. We were surprised to findthat compared with aspirin, kistomin also exerted potent antithromboticeffect in vivo, prolonging the occlusion time to 194.9 ±12.5 s (n = 10) and 273.2 ± 16.2 s (n = 10) at dosesof 1.5 and 7 µg/g, respectively (Table 1). Kistomin wasapproximately 4000-fold more potent than aspirin in prolongingmicrovessel occlusion time on a molar basis. In parallel, thetail bleeding time of mice (control, 90.8 ± 5.0 s, n= 17) was prolonged to 172.1 ± 26.3 s and more than 1800s by kistomin at the given doses of 1.5 and 7 µg/g, respectively.In contrast, aspirin at 150 and 250 µg/g also increasedbleeding time to 559 ± 48.9 s (n = 13) and more than1800 s (n = 10), respectively (Table 2).

View this table:
[in this window]
[in a new window]

TABLE 1 Effect of kistomin on fluorescent dye-induced platelet-rich thrombus formation in mesenteric venules of mice Values are presented as means ± S.E.M. of experimental number (n) indicated

View this table:
[in this window]
[in a new window]

TABLE 2 Effect of kistomin on the tail bleeding time of mice Values are presented as means ± S.E.M. of experimental number (n) indicated.

Discussion

Top
Abstract
Materials and Methods
Results
Discussion
References

Platelet GPIb ${alpha}$ -vWF interaction has been identified as an importanttarget for therapeutics to prevent ischemic cardiovascular events(Jackson and Schoenwaelder, 2003). We have found that kistomininhibited ristocetin-induced platelet agglutination in plateletsuspension (Huang et al., 1993); however, its action mechanism,antithrombotic activity, and structure-activity relationshipare still largely unknown. In this study, we demonstrated thatkistomin is capable of binding to platelet GPIb ${alpha}$ and cleavesGPIb ${alpha}$ and vWF, exhibiting potent antiplatelet and antithromboticactivities in vitro and in vivo. More importantly, cDNA encodingkistomin precursor was cloned and revealed that mature kistominis a P-I SVMP with only a metalloproteinase domain. The sequenceof kistomin is shown with 51% identity to the P-I SVMP fibrolase,a fibrinolytic enzyme from Agkistrodon contortrix contortrixvenom (Randolph et al., 1992), and with 40% identity to theP-III SVMP jararhagin, an ${alpha}$ 2β1- and vWF-cleavage proteasefrom Bothrops jararaca venom (Paine et al., 1992). Moreover,kistomin shares 29% identity with the proteinase domain of humanADAMTS13 (a disintegrin and metalloproteinase with thrombospondinmotifs 13), an endogenous metalloproteinase specifically cleavingbetween Tyr842 and Met843 in the A2 domain of vWF to regulateits physiological hemostatic activity (Levy et al., 2001). Beinga P-I SVMP without an additional disintegrin/cysteine-rich domain,kistomin still has a relative strong selectivity toward plateletGPIb ${alpha}$ and vWF, suggesting that the additional domain(s) is notnecessarily required for the substrate recognition. From theprotein chemistry and evolutionary viewpoint, it is an interestingissue to know why these SMVPs and matrix metalloproteniaseshave a similar specificity for GPIb ${alpha}$ and/or vWF.

Kistomin inhibits vWF-induced platelet agglutination and aggregationthrough acting on platelet GPIb ${alpha}$ and vWF. Several lines of evidenceindicate that the platelet GPIb ${alpha}$ and vWF were cleaved by kistominduring their coincubation. First, a significantly reduced bindingsignal in flow cytometry was observed after platelets were treatedwith kistomin (Fig. 3A). Second, the outer membrane portionof GPIb ${alpha}$ was cleaved from platelet membrane into supernatantin the presence of kistomin and generated two soluble fragments,which migrated at the molecular masses of 45 and 130 kDa (Fig. 3, B and C).Third, kistomin competitively inhibited anti-GPIb ${alpha}$ mAb interactionwith platelet and directly bound to platelet GPIb ${alpha}$ , as determinedby flow cytometry and Western blotting (Fig. 4). Fourth, vWF-inducedplatelet agglutination was compromised by a preincubation ofvWF with kistomin but reversed by adding an intact vWF (Fig. 5A).Fifth, upon kistomin incubation, high molecular mass multimersof vWF generated low molecular mass multimers (Fig. 5B). Last,EDTA pretreatment can abolish these activities of kistomin (Figs.3, 5, and data not shown), indicating that kistomin is a typicalSVMP, mediating antiplatelet activities through cleaving GPIb ${alpha}$ and vWF.

Regarding specificity, the surface marker analysis showed thatkistomin failed to affect the binding of anti- ${alpha}$ 2β1 (6F1)and ${alpha}$ IIbβ3 (7E3) mAbs to platelets. In contrast, kistominspecifically inhibited the binding of anti-GPIb ${alpha}$ mAbs to platelets,including AP1, 6D1, and SZ2 (Fig. 3A and data not shown). Moreover,platelets prepared from kistomin-treated mice were unable toagglutinate in response to GPIb ${alpha}$ -agonist induction but were ableto aggregate in response to other agonists (Fig. 7), suggestingits relative specificity toward GPIb ${alpha}$ both in vitro and in vivo.The GPIb ${alpha}$ -binding epitopes for 6D1 and AP1 have been demonstratedto be located at the amino acid residues 104 to 128 and 201to 268, respectively (Coller et al., 1983). SZ2 mAb has beenshown to recognize anionic sulfated tyrosine residues 269 to282 of GPIb ${alpha}$ (Ward et al., 1996). Therefore, failed binding ofthese Abs to platelet in the presence of kistomin indicatesthat kistomin may cleave GPIb ${alpha}$ , downstreaming the anionic tyrosinesulfated region. In Fig. 3, we found that outer membrane portionof GPIb ${alpha}$ was cleaved by kistomin to generate a $~$ 130-kDa solublefragment. Because it was a soluble fragment found in total celllysate and in the supernatant (Fig. 3C), the possibility ofcleavage of GPIb ${alpha}$ at the site near N terminus was excluded. Therefore,the first cleavage site was hypothesized to be located nearC terminus of GP Ib ${alpha}$ . The cytoplasmic tail of GPIb ${alpha}$ contains 96amino acid residues (Berndt et al., 2001) and is estimated tohave a molecular mass of approximately 10 kDa. Therefore, thefirst cleavage site on GPIb ${alpha}$ may be located near the outer membraneof platelet. Second, a $~$ 45-kDa soluble fragment increased graduallyaccompanying with a decrease of the $~$ 130-kDa fragment (Fig. 3),suggesting that kistomin's second cleavage site is located withinthe $~$ 130 kDa GPIb ${alpha}$ fragment. This is evidenced by the observationsthat inactivated kistomin competitively replaced the bindingof anti-GPIb ${alpha}$ M45 mAb, which recognizes anionic sulfated tyrosineresidues of GPIb ${alpha}$ (Fig. 4). Kistomin seems to act like mocarhagin,a P-III SVMP, by cleaving GPIb ${alpha}$ at a single site between Glu282and Asp283 to generate a $~$ 40-kDa fragment. However, this $~$ 45-kDafragment could be recognized by SZ2 on Western blotting analysis(Fig. 3, B and C), indicating that the binding epitope of SZ2,anionic sulfated tyrosine residues of GPIb ${alpha}$ , still remained onthe fragment. According to the size of the second fragment ( $~$ 45kDa)and the binding epitopes of anti-GPIb ${alpha}$ mAbs (SZ2 and M45), wepostulated that the second kistomin-cleavage site on GPIb ${alpha}$ isnear downstream of the anionic sulfated tyrosine region. Takentogether, we suggest that kistomin cleaves GPIb ${alpha}$ at two distinctsites, one of which is located at the region near the outermembrane and another locates near anionic sulfated tyrosine.Kistomin's exact cleavage sites on GPIb ${alpha}$ are still under investigationin our laboratory.

Our study also demonstrated that kistomin potently cleaved plateletGPIb ${alpha}$ in human whole blood, compared with crotalin and triflamp,two P-I SVMPs (Fig. 6). It has been shown that human ${alpha}$ 2-macroglobulinand mouse macroglobulin are abundant in serum and capable ofinhibiting and neutralizing the proteolytic activity of mostproteinases, including some SVMPs (Tseng et al., 2004b). However,in this report, kistomin was demonstrated to elicit its antiplateletand antithrombotic in vivo (Fig. 7 and Tables 1 and 2). Thesesuggest that kistomin is less susceptible to be neutralizedby globulins in serum and possibly can be developed as an antithromboticagent. This is supported by the data shown in Tables 1 and 2,in which aspirin (150 µg/g) and kistomin both delayedthe irradiation-induced occlusion time to a similar degree,but kistomin seems to be safer at a lower dose (1.5 µg/g)than aspirin in causing bleeding.

In conclusion, in this report we demonstrated that a P-I SVMP,kistomin, blocked vWF-induced platelet activation by specificallycleaving platelet GPIb ${alpha}$ and vWF, suggesting that a metalloproteinasewithout an additional disintegrin/cysteine-rich domain has arelative specificity for GPIb ${alpha}$ and vWF. More importantly, kistominexerted an antithrombotic effect in vivo with certain propertiesquite different from those of P-I SVMPs derived from other snakevenoms. Therefore, kistomin may be useful as a tool for studyingthe function of vWF-GPIb ${alpha}$ , providing an alternative approachfor the designing of antithrombotic agents.

Acknowledgements

We appreciate the generous supply of mAbs from Dr. B. S. Coller(7E3, 6D1, and 6F1) and Dr. R. R. Montgomery (AP1). We alsothank Dr. L.P. Chow for protein sequencing.

Footnotes

This work was financially supported by National Science Councilgrant NSC95-2320-B002-045, Taiwan.

Article, publication date, and citation information can be foundat http://molpharm.aspetjournals.org.

doi:10.1124/mol.107.038018.

ABBREVIATIONS: vWF, von Willebrand factor; GP, glycoprotein;SVMP, snake venom metalloproteinase; mAb, monoclonal antibody;FITC, fluorescein isothiocyanate; PVDF, polyvinylidene difluoride;PCR, polymerase chain reaction; PRP, platelet-rich plasma; PS,platelet suspension; RT, room temperature; PBS, phosphate-bufferedsaline; P-I–IV, protein-types I–IV.

Address correspondence to: Tur-Fu Huang, Department of Pharmacology, College of Medicine, National Taiwan University, No1, Sec1, Jen-Ai Rd, Taipei, Taiwan. E-mail: turfu{at}ntu.edu.tw

References

Top
Abstract
Materials and Methods
Results
Discussion
References

Andrews RK and Berndt MC (2004) Platelet physiology and thrombosis. Thromb Res 114: 447-453.[CrossRef][Medline]

Andrews RK, Gardiner EE, Shen Y, Whisstock JC, and Berndt MC (2003) Glycoprotein Ib-IX-V. Int J Biochem Cell Biol 35: 1170-1174.[CrossRef][Medline]

Berndt MC, Shen Y, Dopheide SM, Gardiner EE, and Andrews RK (2001) The vascular biology of the glycoprotein Ib-IX-V complex. Thromb Haemost 86: 178-188.[Medline]

Bonnefoy A, Vermylen J, and Hoylaerts MF (2003) Inhibition of von Willebrand factor-GPIb/IX/V interactions as a strategy to prevent arterial thrombosis. Expert Rev Cardiovasc Ther 1: 257-269.[CrossRef][Medline]

Canobbio I, Balduini C, and Torti M (2004) Signalling through the platelet glycoprotein Ib-V-IX complex. Cell Signal 16: 1329-1344.[CrossRef][Medline]

Chang MC and Huang TF (1994) In vivo effect of a thrombin-like enzyme on platelet plug formation induced in mesenteric microvessels of mice. Thromb Res 73: 31-38.[CrossRef][Medline]

Coller BS, Peerschke EI, Scudder LE, and Sullivan CA (1983) Studies with a murine monoclonal antibody that abolishes ristocetin-induced binding of von Willebrand factor to platelets: additional evidence in support of GPIb as a platelet receptor for von Willebrand factor. Blood 61: 99-110.[Abstract/Free Full Text]

Fox JW and Serrano SMT (2005) Structural considerations of the snake venom metalloproteinases, key members of the M12 reprolysin family of metalloproteinases. Toxicon 45: 969-985.[Medline]

Huang TF, Chang MC, and Teng CM (1993) Antiplatelet protease, kistomin, selectively cleaves human platelet glycoprotein Ib. Biochim Biophys Acta 1158: 293-299.[Medline]

Huang TF, Wu WJ, and Ouyang C (1987) Characterization of a potent platelet aggregation inhibitor for Agkistrodon rhodostoma snake venom. Biochim Biophys Acta 925: 248-257.[Medline]

Jackson SP and Schoenwaelder SM (2003) Antiplatelet therapy: in search of the `magic bullet'. Nat Rev Drug Discov 2: 775-789.[CrossRef][Medline]

Kamiguti AS (2005) Platelets as targets of snake venom metalloproteinases. Toxicon 45: 1041-1049.[Medline]

Levy GG, Nichols WC, Lian EC, Foroud T, McClintick JN, McGee BM, Yang AY, Siemieniak DR, Stark KR, Gruppo R, et al. (2001) Mutations in a member of the ADAMTS gene family cause thrombotic thrombocytopenic purpura. Nature 413: 488-494.[CrossRef][Medline]

Liu CZ, Hur BT, and Huang TF (1996) Measurement of glycoprotein IIb/IIIa blockade by flow cytometry with fluorescein isothiocyanate-conjugated crotavirin, a member of disintegrins. Thromb Haemost 76: 585-591.[Medline]

Marsh NA (2001) Diagnostic uses of snake venom. Haemostasis 31: 211-217.[CrossRef][Medline]

Matsui T, Fujimura Y, and Titani K (2000) Snake venom proteases affecting hemostasis and thrombosis. Biochim Biophys Acta 1477: 146-156.[CrossRef][Medline]

Paine MJ, Desmond HP, Theakston RD, and Crampton JM (1992) Purification, cloning, and molecular characterization of a high molecular weight hemorrhagic metalloprotease, jararhagin, from Bothrops jararaca venom. Insights into the disintegrin gene family. J Biol Chem 267: 22869-22876.[Abstract/Free Full Text]

Randolph A, Chamberlain SH, Chu HLC, Retzios AD, Markland FS Jr and Masiarz FR (1992) Amino acid sequence of fibrolase, a direct-acting fibrinolytic enzyme from Agkistrodon contortrix contortrix venom. Protein Sci 1: 590-600.[Medline]

Tseng YL, Lee CJ, and Huang TF (2004a) Effects of a snake venom metalloproteinase, triflamp, on platelet aggregation, platelet-neutrophil and neutrophil-neutrophil interactions: involvement of platelet GPIbalpha and neutrophil PSGL-1. Thromb Haemost 91: 315-324.[Medline]

Tseng YL, Wu WB, Hsu CC, Peng HC, and Huang TF (2004b) Inhibitory effects of human alpha2-macroglobulin and mouse serum on the PSGL-1 and glycoprotein Ib proteolysis by a snake venom metalloproteinase, triflamp. Toxicon 43: 769-777.[Medline]

Wang WJ and Huang TF (2001) A novel tetrameric venom protein, agglucetin from Agkistrodon acutus, acts as a glycoprotein Ib agonist. Thromb Haemost 86: 1077-1086.[Medline]

Ward CM, Andrews RK, Smith AI, and Berndt MC (1996) Mocarhagin, a novel cobra venom metalloproteinase, cleaves the platelet von Willebrand factor receptor glycoprotein Ibalpha. Identification of the sulfated tyrosine/anionic sequence Tyr-276-Glu-282 of glycoprotein Ibalpha as a binding site for von Willebrand factor and alpha-thrombin. Biochemistry 35: 4929-4938.[CrossRef][Medline]

Wu WB, Chang SC, Liau MY, and Huang TF (2001a) Purification, molecular cloning and mechanism of action of graminelysin I, a snake-venom-derived metalloproteinase that induces apoptosis of human endothelial cells. Biochem J 357: 719-728.[CrossRef][Medline]

Wu WB, Peng HC, and Huang TF (2001b) Crotalin, a vWF and GPIb cleaving metalloproteinase from venom of Crotalus atrox. Thromb Haemost 86: 1501-1511.[Medline]