Identification of Domains Responsible for von Willebrand Factor Type VI Collagen Interaction Mediating Platelet Adhesion under High Flow*

Mario MazzucatoDagger , Paola Spessotto§, Adriana MasottiDagger , Leandro De AppolloniaDagger , Maria Rita CozziDagger , Akira Yoshioka, Roberto Perris§parallel , Alfonso Colombatti§**, and Luigi De MarcoDagger Dagger Dagger

From the Dagger  Servizio Immunotrasfusionale e Analisi Cliniche and § Divisione di Oncologia Sperimentale 2, Centro di Riferimento Oncologico, Instituto Nazionale Tumori Centroeuropeo, Aviano (PN) 33081 Italy,  Department of Pediatrics Nara Medical University, 840 Shijo-cho, Kashihara City Nara 634 Japan, ** Dipartimento di Scienze e Tecnologie Biomediche University of Udine, Udine 33100 Italy, and parallel  Department of Evolutionary and Functional Biology, University of Parma, Parma, 43100 Italy

    ABSTRACT
Top
Abstract
Introduction
References

We have identified type VI collagen (Col VI) as a primary subendothelial extracellular matrix component responsible for von Willebrand factor (vWF)-dependent platelet adhesion and aggregation under high tensile strength. Intact tetrameric Col VI was the form of the collagen found to be capable of promoting vWF-mediated platelet adhesion/aggregation under this shear condition, whereas removal of the predominant portion of the terminal globules by pepsin treatment abrogated its activity. The inability of the pepsin-digested Col VI to support any platelet interaction at high flow was because of the failure of the A3(vWF) domain to bind to this form of collagen, suggesting a stringent requirement of a tridimensional conformation or of intactness of its macromolecular structure. In contrast, the A1(vWF) domain bound to both intact and pepsin-digested Col VI tetramers but, in accordance with the cooperating function of the two vWF domains, failed to support platelet adhesion/aggregation under high shear onto Col VI by itself. The putative A1(vWF) binding site resided within the A7(VI) module (residues 413-613) of the globular amino-terminal portion of the alpha 3(VI) chain. Soluble recombinant A7(VI) polypeptide strongly perturbed the vWF-mediated platelet adhesion to Col VI under high shear rates, without affecting the binding of the vWF platelet receptor glycoprotein Ibalpha to its cognate ligand A1(vWF). The findings provide evidence for a concerted action of the A1(vWF) and A3(vWF) domains in inducing platelet arrest on Col VI. This is accomplished via an interaction of the A1(vWF) domain with a site contained in the alpha 3 chain A7(VI) domain and via a conformation-dependent interaction of the A3(vWF) domain with the intact tetrameric collagen. The data further emphasize that Col VI microfilaments linking the subendothelial basement membrane to the interstitial collagenous network may play a pivotal role in the hemostatic process triggered upon damage of the blood vessel wall.

    INTRODUCTION
Top
Abstract
Introduction
References

Platelet adhesion to the exposed vascular subendothelial matrix proteins at the injury site is a crucial step in initiating the hemostatic and thrombotic processes. Hemodynamic forces play a significant role in the process of thrombus formation. There is a high shear stress opposing platelets adhesion, and they are forced toward the vascular lining surface and adhere at sites of vascular damage. Rapid formation of the initial platelet layer involves bridging between collagens and maybe other components (1-8) of the subendothelium on one side and platelet membrane receptors on the other side (GPIbalpha and alpha IIbbeta 3). A pivotal role in this hemodynamic process is played by von Willebrand factor (vWF)1, which is the major adhesive protein mediating the bridging interaction as a function of shear forces. vWF, recognized by the platelet surface glycoprotein GPIbalpha , is particularly efficient in capturing platelets under high flow rates (9), and the participation of vWF in hemostasis is fundamental for thrombus formation under high shear stress conditions such as those present in small arteries or in pathological vessel affections such as stenosed arteries in artheriosclerosis. As extracellular matrix-assembled vWF of the subendothelium may not always be freely accessible to platelets in areas of rapid flow (10), the circulating vWF pool may be rather important in initiating platelet cohesion (11). Consistent with this idea is the observation that soluble plasma vWF binds rapidly and tightly to an underlying extracellular matrix, even when this latter is produced by fibroblasts (12). Moreover, high blood flow rates have been suggested to modulate the vWF release from the endothelium such as to provide additional available vWF for platelet interaction (13). High shear forces also induce a conformational transition in vWF, which converts it from a globular state to an extended chain structure. This structural transition is believed to result in the exposure of the intramolecular domains and in a reorientation of the polymers in the direction of the stress field (14).

The prevailing importance assigned to collagens in the initial steps of the vWF-mediated thrombogenic events has led to the pinpointing of two collagen binding sites in vWF: one located in the Al(vWF) and one in the A3(vWF) domains (15-17).2 However, the binding site contained within the A3(vWF) domain, rather than that of the A1(vWF) domain, has been proposed to be the predominant collagen binding site, at least for collagen type III (15, 18, 19). Possibly, this is a consequence of the fact that the A1(vWF) domain may also be engaged in the binding to the GPIbalpha , glycosaminoglycans, and sulfatides (16, 20). On the other hand, the Al(vWF) domain has been recently proposed to mediate vWF interaction with Col VI (21). Accordingly, in addition to the main fibrillar collagens types I, III, and V, previous studies have suggested that the microfibrillar Col VI could similarly be effective in stimulating a vWF-dependent platelet aggregation at low but not at high shear rates (6, 22, 23).

Our results are consistent with a pivotal role of Col VI in mediating vWF-dependent platelet cohesion at high shear forces and shed light on the complex mechanisms of Col VI-vWF-platelet interaction by unraveling the occurrence of a cooperative binding of the Al(vWF) and A3(vWF) domains of vWF to multiple sites of Col VI. Among these, one located within the A7(VI) vWFA module at the amino-terminal portion of the alpha 3(VI) chain (amino acids 413-613) was found to be a critical A1(vWF) binding site required for optimal platelet adhesion/aggregation at high shear rates.

    EXPERIMENTAL PROCEDURES

Antibodies-- Specificities of the mouse monoclonal antibodies (mAbs) used in this study were as follows. mAbs LJ-Ib1 (24) and LJ-Ibl0 (25) are directed against the platelet GPIbalpha ; mAbs LJ-CP8 (26) and LJ-P5 (27) are against the alpha IIbbeta 3 integrin complex. mAb LJ-Ibl blocks binding of GPIbalpha to vWF, whereas mAb LJ-Ibl0 displays only a minimal inhibitory effect on the binding of GPIbalpha to vWF but completely obliterates the alpha -thrombin binding to the same receptor. mAb LJ-CP8 blocks the binding of the alpha IIbbeta 3 integrin to both vWF and fibrinogen, whereas mAb LJ-P5 selectively inhibits the binding of the alpha IIbbeta 3 integrin to soluble vWF but not to fibrinogen. mAbs NMC-4 and MR5 (kindly provided by Dr. L. W. Hoyer, Holland Laboratory, American Red Cross, Rockville, MD) react with the Al(vWF) domain (28) and the A3(vWF) domain (29, 30), respectively. mAb LJ-C3 is directed against the amino-terminal portion of vWF corresponding to residues 1-272 of the mature subunit, and it is known to inhibit the interaction of vWF with coagulation factor VIII (31). Purified IgG and F(ab')2 were prepared as described previously (27). All mAbs were used at saturating concentrations determined in pilot dose-dependent experiments.

Purification of Col VI and Other Extracellular Matrix Molecules-- Intact tetramers of Col VI were purified from embryonic chick gizzard, human placenta, and adult bovine aorta by extraction in Tris-HCI, pH 7.6, with 6 M urea and protease inhibitors and separated by gel filtration chromatography on Sepharose CL-4B columns as described previously (32, 33). These Col VI preparations were analyzed by SDS-agarose gel electrophoresis and were found to be composed mainly of tetramers, with an estimated Mr of >2,000 kDa. Chick Col VI tetramers deprived of their amino-terminal globular domains and the predominant portion of the carboxyl-terminal domains were produced by treatment of the purified intact Col VI with 1% (w/v) pepsin as described previously (34-36). Intact and pepsin-digested tetramers purified from human placenta following extraction with M guanidine HCl (GuHCl) (34, 35) were kindly received from Huey-Ju Kuo (The Shriners Hospital for Crippled Children, Portland, OR). Human vWF was purified from plasma obtained from healthy donors after informed consent by gel filtration chromatography on Sepharose CL-4B columns (Amersham Pharmacia Biotech) as described previously (37). The ristocetin cofactor activity in this purified vWF was determined to be 155 units/mg (38).

Preparation of Recombinant Bacterial Polypeptides-- Bacterial recombinant polypeptides corresponding to selected vWFA modules of the alpha 3(VI) chain were generated from original chick alpha 3(VI) chain cDNA clones (39) by 6× His-tagging and purification on nickel nitrilotriacetic acid resins (Diagen GmbH) as described (33). Recombinant polypeptides corresponding to the single human Col VI modules A6(VI), A7(VI), A8(VI), and A9(VI) were produced from reverse transcription-polymerase chain reaction amplificates according to the same protocol. Polypeptide pB10 was derived from the corresponding 3.3-kilobase pair-long cDNA and embodies the A8-4 modules and a substantial portion of the A3 module (39). A recombinant polypeptide encompassing the GPIbalpha binding domain of vWF residing within the Al(vWF) domain (rvWF(445-733)) (40) was kindly provided by Dr. Z. M. Ruggeri (The Scripps Research Institute, La Jolla, CA). The recombinant polypeptides were more than 90% pure as judged by SDS-polyacrylamide gel electrophoresis.

Solid-phase Binding Assays-- 96-well plates (Costar) were coated with 100 µl (0.25-30 µg/ml, final concentration) of human, bovine, or chick Col VI in 0.05 M bicarbonate buffer, pH 9.6, for 24 h at room temperature, washed twice in imidazole buffer (0.12 M NaCl, 0.02 M imidazole, 0.005 M citric acid, pH 7.3, 0.1% BSA), and then saturated with 5% BSA for l h at room temperature in imidazole buffer. After removal of excess BSA, plates were incubated with a final concentration of 1-40 µg/ml purified vWF in imidazole buffer, pH 7.3, containing 1% BSA. After a 2-h incubation at room temperature, plates were extensively washed and incubated with a rabbit polyclonal anti-human vWF antiserum (DAKO) at 1:1,000 dilution for 30 min at room temperature, followed by horseradish peroxidase-conjugated secondary goat anti-rabbit antibodies (Bio-Rad) at 1:3,000 dilution for 30 min at room temperature. Plates were then extensively washed and further incubated with 0.4 mg/ml o-phenylenediamine (SIGMA) in 0.02 M Na3C6H5O7, 0.05 M NaH2PO4, pH 5.0, and 0.02% H202, and the absorbance was read at 492 nm in an Autoreader III (Ortho Diagnostic System). Intact Col VI tetramers from the three different species/tissues yielded comparable dose-dependent bindings. The affinities of the interaction between vWF and Col VI were the following: intact Col VI/vWF (EC50 approx  2 nM); pepsin Col VI/vWF (EC50 approx  3 nM)

Preparation of Col VI and vWF Substrates and Flow Chamber Assembly-- Intact and pepsin-digested Col VI tetramers were dissolved in 0.05 M bicarbonate buffer, pH 9.6, to 5-100 µg/ml and coated onto a central area of glass coverslip (24 × 50 mm, 100 µl of Col VI solution/coverslip), that was delimited by a 15-mm silicon ring (Flexiperm-Disc Heraeus Instruments). The amount of immobilized collagen (either chick or human) was estimated by independent coating with 125I-labeled Col VI and was determined to range between 0.15 and 4.36 µg/cm2 for the coating concentrations used. In experiments in which vWF was used in immobilized form, coverslips were coated with 100 µl of vWF at 100 µg/ml in 0.04 M phosphate buffer, pH 7.4, containing 0.15 M NaCl. Coated coverslips were placed in a humid chamber at 4 °C overnight, followed by washings in phosphate-buffered saline and saturation with 1% BSA in 20 mM Tris-HCI, pH 7.4, with 0.15 M NaCl for 60 min at room temperature. Saturated coverslips were then assembled in a parallel-plate flow chamber (modified Richardson's flow chamber) (11), which was then filled with isotonic saline. A syringe pump (Harvard Apparatus, Boston, MA) was used to aspirate the fluid through the chamber at a constant flow rate for 1-10 min before being perfused with platelet-containing solutions. Flow rates utilized were 0.13, 0.26, 0.53, 2.66, 5.33, 7.99, and 10.66 ml/min, which produced 25, 50, 100, 500, 1,000, 1,500, and 2,000 s-1 wall shear rates, respectively. Before being tested, blood samples were incubated at 37 °C for 30 min so as to re-equilibrate the system to physiological temperature.

Blood Sampling-- Blood from healthy volunteers and from a patient affected by a severe form of vWD (less than 1% of ristocetin cofactor and undetectable or barely visible vWF multimers after SDS-polyacrylamide gel electrophoresis) was obtained after informed consent. All donors denied ingestion of drugs known to interfere with platelet function for a period of at least 2 weeks before blood sampling. Blood was collected from the antecubital vein through a 18-gauge needle into syringes containing 400 units/ml (final concentration) thrombin inhibitor hirudin (Iketon, Italy) as anticoagulant.

Preparation of Platelets-- Platelets were prepared by a modification of a previously described method (41). To prevent unwanted platelet activation, apyrase III (Sigma), an ADP scavenger, was added to the blood samples at a final concentration of 10 units/ml. Blood samples were divided into 5-ml aliquots and centrifuged at 800 × g for 14 min, the plasma was removed, and the sedimented cells, including platelets and leukocytes residing at the top of the erythrocyte cushion, were resuspended in divalent cation-free HEPES-Tyrode buffer (10 mM HEPES, 140 mM NaCl, 2.7 mM KCl, 0.4 mM NaH2PO4, 10 mM NaHCO3, and 5 mM dextrose), pH 6.5, containing 5 units/ml apyrase (final concentration) and recentrifuged at 800 g for additional 14 min. This procedure was repeated four times, and after the last centrifugation cycle, the pellet was resuspended in HEPES-Tyrode buffer containing 2 mM CaCl2, 2 mM MgCl2, and 1% BSA (BSA buffer). In some experiments, 10 µM PGE1 (Sigma) was added to the platelet suspension to prevent platelet activation. Platelets and leukocytes counts ranged from 1-1.5 × 108/ml and from 4-6 × 106/ml, respectively, and the hematocrit ranged from 44-48%.

Platelet Aggregation Assay-- Platelet-rich plasma from whole blood, obtained from healthy donors after informed consent, was prepared by dilution 1:6 (v/v) into citric acid/citrate/dextrose, pH 4.5, and differential centrifugation. Platelets were washed free of plasma constituents using a previously described modification of the albumin density gradient protocol and employed at a final count of 2.5 × 108/ml in Tyrode buffer containing 2% BSA. Platelet aliquots of 350 µl were placed in glass cuvettes and stirred with a Teflon-coated magnetic bar at 37 °C and 1,200 rpm in an aggregometer (Chrono-Log Corp.). Purified vWF was added to the platelet suspension at a final concentration of 5 µg/ml, with and without prior incubation (15 min at 37 °C) with 100 µg/ml recombinant A7(VI) polypeptide. Immediately after, 1 mg/ml of ristocetin (Chrono-Log) was added to the platelet suspension, and the extent of platelet aggregation was assessed by changes in light transmittance (37).

Perfusion Experiments-- The flow chamber was mounted on an inverted microscope equipped with epifluorescent illumination (Diaphot-TMD; Nikon) and an intensified CCD video camera (C-2400-87, Hamamatsu Photonics). To allow visualization, platelets were labeled by direct incubation with 5-8 µM fluorescent dye mepacrine (Sigma). To prevent platelet photoactivation by the irradiating UV light, the neutral blocking filters ND32 and ND8 were used simultaneously. The total area of one optical field corresponded to about 0.037 mm2. To assure flowing of comparable blood volumes and hence, a comparable number of platelets to be perfused for each shear rate, the assessment of platelet surface coverage was normalized to 1 min of flow at a shear rate of 1,000 s-1. Each time point corresponds to a single frame of video tape recording with a time resolution of 0.04 s/frame. Images were captured by a personal computer equipped with a TARGA-2000 PLUS board (Truevision), either in real time during perfusion or from stored video frames that had been recorded at a sampling rate of 25 frames/s during the experiment. To classify and estimate the number of attached particles, to determine their coordinates on the analyzed substrate area, and to assess the size of the surface area covered, images of predefined optical fields were elaborated using the Microimage (image-processing software; CASTI Imaging, Venice, Italy). The final size of the formed platelet aggregates was estimated assuming an average platelet diameter of 2.4 µm (1.6-4-µm range), and the observed particles were arbitrarily classified as: single platelets, 2-13 µm2; micro-aggregates, 14-50 mm2; small aggregates, 51-200 µm2; and large aggregates > 200 µm2.

    RESULTS

Shear Rate-dependent Platelet Interaction with Intact Col VI Tetramers-- In pilot experiments we noticed that intact Col VI tetramers extracted with 6 M GuHCl (34-36) were not capable of promoting platelet adhesion at high shear rates although being fully active in stimulating adhesion and migration of a number of cell types (Refs. 36, 42, 43 and data not shown). In contrast, urea-extracted Col VI from late embryonic chick gizzard, bovine aorta, and human placenta efficiently promoted platelet adhesion (see below).

Immobilized intact Col VI tetramers efficiently and dose-dependently supported platelet adhesion at a shear rate of 1,000 s-1, which is accepted to exceed the threshold rate at which platelet adhesion/aggregation may exclusively occur via vWF. These experiments also established the optimal quantity of Col VI to be immobilized onto the substrate to promote maximal surface coverage by the flowing platelets in our system. Extrapolation of the 50% surface platelet coverage observed after 1 min of flow was reached at 0.44 µg/cm2 immobilized Col VI (Fig. 1A). In a time course analysis of platelet adhesion and aggregation at two different shear rates, it was found that a plateau of surface coverage was attained very rapidly (i.e. maximal coverage within the optical field analyzed was reached after 30 s at 2,000 s-1 and after 60 s at 1,000 s-1) (Fig. 1B). Platelets adhered to the same extent onto tetrameric Col VI of either chick, bovine, or human origin, whereas almost no binding was detected on the pepsin form (Fig. 1C).


View larger version (17K):
[in this window]
[in a new window]
 
Fig. 1.   Platelet adhesion to intact Col VI tetramers. A, dose-dependent platelet adhesion to intact tetramers of Col VI in flow conditions. Whole blood containing recombinant hirudin as anticoagulant and treated with the fluorescent dye mepacrine to label flowing platelets was perfused through a parallel flow chamber at 37 °C under the indicated shear rates. Data points report the percentages of surface coverage by platelets in an area of 0.037 mm2 after 1 min of perfusion in a representative case. B, effect of wall shear rate on platelet adhesion to intact Col VI. Percentage of surface coverage as a function of perfusion time is shown at 1,000 s-1 (gray circles) and 2,000 s-1 (black squares) shear rates. These data are representative of three separate experiments that gave similar results and were obtained with the same blood sample employed for experiments described in A. C, real time observation of platelet adhesion and aggregation onto Col VI tetramers: effect of large globular domain destruction. Representative single-frame images showing direct comparisons of platelet adhesion and aggregation onto intact and pepsin-digested tetramers of Col VI under conditions of high and low shear rate and when perfused in whole blood.

Platelet Receptors Responsible for the Interaction with Col VI at High Shear Rates-- Under conditions of high shear rate, functional inhibition of the platelet alpha IIbbeta 3 integrin receptor by the mAbs LJ-P5 (not shown) and LJ-CP8 (Figs. 2A) caused a substantial abrogation of platelet arrest and the subsequent tethering and aggregation. However, interference with alpha IIbbeta 3 activity did not impede the vWF-induced transient contact of platelets with the substrate, which was noticed to be of variable duration. Thus, at each given time point of analysis, a certain coverage of the substrate area under consideration was observed. In accordance with the prerequisite of a platelet GPIbalpha -vWF interaction to bring through thrombus formation under high tensile strength (9, 11, 44), platelet adhesion/aggregation was completely blocked by mAb LJ-Ibl (Fig. 2A), known to perturb the GPIbalpha binding to vWF. mAb LJ-Ib10 specifically interfering with the GPIbalpha binding to alpha -thrombin did not have any effect, ascertaining the specificity of the GPIbalpha interaction with vWF in the system. In analogy, no platelet adhesion was observed with vWF-deficient blood from a patient with severe vWD (Fig. 2A) or when GPIbalpha function was inhibited with 5 µM rvWF(445-733) polypeptide, a recombinant containing A1(vWF) domain responsible for GPIbalpha binding site of vWF (Fig. 2A).


View larger version (19K):
[in this window]
[in a new window]
 
Fig. 2.   Inhibition of platelet adhesion to intact Col VI tetramers. A, inhibition of platelet adhesion to intact Col VI under conditions of high shear rate by the addition of 100 µg/ml (final concentration) F(ab')2 of antibodies to GPIbalpha (mAb LJ-Ib1), alpha IIbbeta 3 (mAb LJ-CP8), the recombinant A1(vWF) polypeptide rvWF(445-733) (5 µM, final concentration) to whole healthy blood, and lack of adhesion of platelets perfused in whole blood obtained from an individual afflicted by the severe form of vWF disease vWD. The data represent the mean of six experiments performed with blood from different donors and are reported as the total surface covered by platelets (left y axis) and relative surface coverage of the optical field in percentage +S.E. (right y axis). B, shear rate-dependent inhibition of platelet adhesion to intact Col VI in the presence of optimal amounts of mAb LJ-Ib1. Antibody LJ-Ib10, known to interfere only with the alpha -thrombin binding to GPIbalpha , was used at an equivalent concentration as reference.

To further define the shear rate-related involvement of soluble vWF in cases when flowing platelets were confronted with an underlying Col VI substrate, platelets were perfused at different shear forces, ranging from those found in larger veins (e.g 25 s-1) to those found in small arterioles (e.g. 1,500-2,000 s-1), in the presence or absence of the anti-GPIbalpha antibody LJ-Ibl. These experiments demonstrated that, contrary to what was previously reported for collagen type I (and possibly also type III), Col VI supported vWF-dependent platelet adhesion/aggregation down to a shear force of about 100 s-1 (Fig. 2B). Shear rates of 50 s-1 or lower still promoted some platelet adhesion and aggregation, which, however, was independent of the participation of vWF (Fig. 2B).

Because there was no significant change in the surface coverage above 1,000 s-1, all subsequent high shear rate experiments were carried out under these conditions. The results obtained after blockage of the vWF-GPIbalpha interaction underscored that vWF was an active component in the system but did not rule out a possible cooperation between vWF and other blood factors. We therefore perfused washed platelets in a BSA-containing Tyrode buffer suspension of red and white cells in which increasing amounts of purified vWF were added. In these cases, a substantial platelet adhesion and aggregation on Col VI was noted in a manner that was both dose-dependent and saturable (Fig. 3). Depending upon the amount of vWF added, microaggregates, small and large aggregates (see "Experimental Procedures") could be observed, with the formation of the large aggregates starting at a vWF concentration of 2.5 µg/ml (Fig. 3). Apart from promoting platelet tethering to a molecular or cellular substrate, vWF has also been suggested to mediate the subsequent platelet-platelet interaction leading to alpha IIbbeta 3 integrin-dependent aggregate formation. To establish whether this was the case also on a Col VI substrate, washed platelets were similarly perfused in the presence of mAb LJ-P5, known to inhibit only the alpha IIbbeta 3 integrin binding to vWF. In such conditions, single platelets could still be detected on the Col VI substrate, but no aggregates formed (not shown).


View larger version (61K):
[in this window]
[in a new window]
 
Fig. 3.   Real time observation of platelet adhesion to intact Col VI tetramers at high shear rate; effect of vWF concentration. Representative single-frame images (derived from three independent experiments) of platelet adhesion to intact Col VI captured under flowing at high shear rates in the presence of increasing concentrations of soluble vWF (0-20 µg/ml, final concentration). Washed platelets were resuspended together with red cells and white cells in a Tyrode buffer containing BSA and divalent cations, mixed with the increasing concentrations of purified vWF, and perfused. Top panels show single-frame images taken after 1 min of perfusion for each vWF concentration. Bottom panels show the corresponding percentage frequency (relative surface distribution) of single platelets (A), microaggregates (B), small aggregates (C), and large aggregates (D; see "Experimental Procedures").

Identification of the vWF Domains Responsible for Platelets Interaction with Col VI and of the vWF Binding Sites on Col VI-- To identify the vWF domains responsible for platelet adhesion and aggregation on Col VI and to determine their relative importance, we utilized mAbs directed against the vWF domains Al(vWF), i.e. mAb NMC-4, and A3(vWF), i.e. mAb MR5. In solid-phase binding assays (i.e. static conditions) with no platelets, mAbs NMC-4 and MR5 inhibited the molecular interaction of vWF to intact Col VI tetramers to about 75 and 60%, respectively, whereas when added together, the inhibitory action was complete (Fig. 4A). Conversely, the addition of the anti-Al(vWF) and anti-A3(vWF) mAbs to platelets perfused at high shear rates abrogated adhesion, irrespectively of the mAb added, whereas addition of the functionally unrelated mAb LJ-C3 did not disturb platelet adhesion (Fig. 4B). These findings indicated that binding of both A1(vWF) and A3(vWF) to Col VI was a prerequisite for optimal vWF-mediated platelet-Col VI interaction at high shear rates. Because mAb NMC-4 also interferes with the GPIbalpha binding to the Al(vWF) domain, the complete blockage of platelet adhesion/aggregation observed after addition of this mAb could be attributed to a dual blockade of the Col VI and GPIbalpha receptor binding to the Al(vWF). Thus, these observations indicated that the vWF-dependent platelet interaction with Col VI at high shear rates required integrity of its terminal globular domains. Intriguingly, however, when the molecular interaction of vWF with pepsin-digested Col VI tetramers was examined in solid-phase binding assays under the inhibitory influence of the anti-A(vWF) domain antibodies, it was found that only the anti-A1(vWF) mAb NMC-4 was capable of abolishing the interaction (Fig. 4A). This finding demonstrated that despite the reported ability of the A3(vWF) domain to interact with interstitial collagens, this domain failed to contribute to binding of vWF to the triple-helical region of Col VI.


View larger version (18K):
[in this window]
[in a new window]
 
Fig. 4.   Inhibitory effect of anti-A1(vWF) and anti-A3(vWF) mAbs. A, solid-phase binding assays showing the interaction of vWF with intact (black bars) and pepsin-digested tetramers (gray bars) in the presence or absence of anti-A1(vWF) and anti-A3(vWF) antibodies used at their maximal inhibitory concentration of 50 µg/ml (final concentration). mAb LJ-C3 against the amino-terminal region of vWF (factor VIII binding domain) was used as a control antibody. The percentage bound vWF was calculated on the basis of vWF to either form of the Col VI in the absence of antibody. Data represent the mean +S.E. of five different experiments. B, platelet adhesion and aggregation onto intact Col VI substrates in the presence of the same antibodies as in A, when perfused at the indicated shear rate in whole blood. Data represent mean +S.E. from three independent experiments.

To identify the vWF binding sites within the globular regions of Col VI, which could account for the binding activity exceeding that given by the collagenous region, we employed amino-terminal alpha 3(VI) chain recombinant polypeptides (Fig. 5A) both in static and dynamic phase. In static phase, about 70% of the maximal vWF binding activity displayed by the intact tetramers was detected for the recombinant Col VI polypeptide pB10, encompassing almost the entire amino-terminal portion of the alpha 3(VI) chain, i.e. the A8-A3(VI) modules. The prevailing binding activity of polypeptide pB10 could further be pinpointed to the A7(VI) module, as determined by direct binding of purified vWF to the polypeptide and the ability of this polypeptide, but not other A(VI) polypeptides, to compete for the binding of vWF to intact Col VI tetramers (Fig. 5B). The competition ability of soluble A7(VI) was dose-dependent, and the residual binding could be completely abrogated by simultaneous addition of the anti-A3(vWF) mAb MR5 (Fig. 5C). Further evidence for a specific role of A(vWF) domain(s) in binding to the amino-terminal globular domain of Col VI was provided by the elected ability of the anti-A1(vWF) mAb NMC-4 to block the binding of vWF to pB10 and A7(VI) (Fig. 5D). In contrast to the A1(vWF) domain, the A3(vWF) failed to interact with the isolated region of the alpha 3(VI) chain, as demonstrated by the lack of inhibition of the vWF binding to alpha 3 recombinant polypeptides in the presence of anti-A3(vWF) antibodies (Fig. 5D). This finding suggested that the interaction site(s) of the A3(vWF) domain within the Col VI globular region was conformation-dependent and most likely required intactness of the quaternary structure of the fully assembled tetramer.


View larger version (34K):
[in this window]
[in a new window]
 
Fig. 5.   vWF binding to Col VI recombinant polypeptides of alpha 3(VI) chain. A, schematic diagram illustrating the module organization of the alpha 3(VI) chain, adopting the nomenclature of gene chick polypeptide (39), and the relative extension of the recombinant polypeptides produced from the corresponding human cDNAs. B, binding of vWF to immobilized recombinant Col VI polypeptides (vWF bound), when assessed as the percentage of bound protein in comparison to the amount bound to intact Col VI tetramers and binding of vWF to immobilized intact tetramers in the presence of soluble recombinant Col VI polypeptides (vWF displaced). In this latter case, values refer to percentage inhibition of vWF binding to Col VI by the various soluble competitors. Fibrinogen was used in both immobilized and soluble phase as a control protein. C, dose-dependent inhibition of vWF binding to immobilized intact tetramers by soluble A7(VI) recombinant polypeptide. At saturation of inhibition, further addition of the anti-A3(vWF) antibody MR5 completely abrogated the residual binding. D, binding of vWF to immobilized recombinant Col VI polypeptides in the presence of antibodies as in Fig. 4. Data represent mean +S.E. from three independent experiments.

Functional Identification of the vWF Binding Sites on Col VI-- The complete blocking effect exerted either by the anti-A1(vWF) or anti-A3(vWF) antibodies on the vWF-dependent platelet adhesion to intact Col VI tetramers at high shear rates suggested that both vWF domains could be equally important in mediating the molecular interaction (Fig. 4B). However, the bivalency of the blocking effect caused by the anti-A1(vWF) mAb NMC-4, which affects both the binding to GPIbalpha and to Col VI, precluded the possibility of determining the reciprocal role of the two vWF domains in these experiments. We therefore analyzed the ability of the soluble A7(VI) polypeptide to prevent platelet adhesion to intact Col VI tetramers under high shear rates in the presence of soluble or immobilized vWF. In experiments in which washed platelets were perfused over intact Col VI tetramers at high shear rate in the presence of soluble vWF, the time-dependent platelet adhesion to the collagen substrate was markedly perturbed by the additional presence of competing soluble A7(VI), whereas the A6(VI) polypeptide had only a marginal effect (Fig. 6A). However, soluble A7(VI) polypeptide did not affect the ristocetin-induced platelet agglutination-aggregation in the simultaneous presence of soluble vWF (Fig. 6B). In another set of analogous experiments in which washed platelets were similarly perfused at high shear rates on substrates of intact tetramers in the presence of soluble vWF or on substrates of immobilized vWF in the absence of soluble vWF, we examined the effect of anti-vWF antibodies and competing recombinant polypeptides on the extent of platelet adhesion at a given time point. In both experimental situations, the prostaglandin PGE1 was included to prevent platelet activation. Platelets perfused over Col VI substrates in the presence of soluble vWF adhered well to the collagen substrate in the simultaneous presence of the control antibody against the factor VIII binding domain of vWF (mAb LJ-C3) or the recombinant A6(VI) polypeptide (Fig. 7). In contrast, the addition of either of the anti-A1(vWF) and anti-A3(vWF) antibodies (mAbs NMC-4 and MR5, respectively) or the A7(VI) recombinant polypeptide strongly perturbed platelet adhesion to Col VI (Fig. 7). In the experimental situation in which platelets were perfused over immobilized vWF, solely the anti-A1(vWF) antibody NMC-4 was capable of blocking the platelet-vWF interaction. This finding indicated that neither the anti-A3(vWF) antibody nor the A7(VI) interfered with the GPIbalpha -A1(vWF) interaction, and hence the inhibitory effect was exerted exclusively on vWF-Col VI interaction.


View larger version (21K):
[in this window]
[in a new window]
 
Fig. 6.   Inhibitory effect of the A7(VI) recombinant polypeptide. A, time course of platelet adhesion and aggregation onto intact Col VI tetramers, perfused under high shear rate conditions (1,000 s-1) in Tyrode buffer in the presence of 5 µg/ml (final concentration) of vWF and the presence or absence of soluble recombinant Col VI polypeptides (100 µg/ml, final concentration). Circles, control; squares, A6(VI); triangles, A7(VI). B, aggregation of washed platelets in the presence of vWF (5 µg/ml, final concentration) with or without 100 µg/ml (final concentration) of A7(VI) polypeptide, as induced by ristocetin (1 mg/ml, final concentration).


View larger version (52K):
[in this window]
[in a new window]
 
Fig. 7.   Real time observation of platelet adhesion onto Col VI tetramers and vWF at high shear rate; effect of anti-A1(vWF) and anti-A3(vWF) inhibitors. Representative single-frame images showing representative platelet adhesions to either immobilized intact Col VI tetramers and soluble vWF (5 µg/ml, final concentration) or immobilized vWF in the presence of anti-A(vWF) antibodies or soluble recombinant Col VI polypeptides (added at their maximal inhibitory concentration). Washed platelets were perfused at high shear rate in Tyrode buffer containing divalent cations and 10 µM PGE1, final concentration.


    DISCUSSION

In this study we provide definite evidence that Col VI may be a primary subendothelial ligand for vWF mediating the high shear rate-induced platelet adhesion and aggregation at sites of vascular injury. Binding of both the A1(vWF) and A3(vWF) domains to immobilized urea-extracted Col VI tetramers is essential for initiating the platelet adhesion/aggregation cascade, implying that none of the individual domains alone is capable of supporting platelet tethering and aggregation under high tensile strength. Although the A3(vWF) domain solely binds to the Col VI tetramers in which the terminal globular domains have been retained intact, the A1(vWF) domain interacts with both the triple-helical region and the amino terminus of the alpha 3(VI) chain, and its binding is independent of the quaternary structure of the collagen (Fig. 8). A primary binding site of the A1(vWF) domain could be identified within the constitutively expressed A7 vWFA module of the alpha 3(VI) chain (33) and shown to be distinct from that involved in the binding of the A1(vWF) domain to the platelet receptor GPIbalpha (Fig. 8).


View larger version (40K):
[in this window]
[in a new window]
 
Fig. 8.   Schematized model of the vWF-mediated platelet adhesion onto Col VI at high shear rate. Upon damage of the arterial wall, the subendothelial Col VI-containing extracellular matrix becomes exposed to the circulating globular vWF, which interacts with it and, at high shear rates, assumes an extended chain conformation (14). The cooperating A1 and A3 domains of the vWF are in concert implicated in the linking of the molecule to the underlying Col VI microfilaments by binding to both the triple-helical region (dark blue) and the globular domains (red) of the tetrameric blocks of the microfilaments. A primary site responsible for the A1(vWF)-mediated vWF interaction with the globular domains of Col VI resides within the A7(VI) module of the amino terminus of the alpha 3 chain. In contrast, the A3(vWF) domain recognizes an apparently structurally complex site residing exclusively within the globular regions of the collagen. Under high flow, the immobilized vWF becomes a filamentous ligand for the GPIb-IX-V complex of the platelet surface (14) through recognition of the A1(vWF) domain, such as to allow for the initial, reversible tethering of the platelets to the substrate. Subsequently, the platelet is activated, and its alpha IIbbeta 3 integrin is converted from an inaccessible to an accessible state on the cell surface (56). This permits its engagement in the platelet-vWF interaction through recognition of the RGD motif. At this point, the platelet is arrested onto the substrate and may bind to other platelets to initiate aggregate formation.

Although the participation of vWF in the high shear rate-induced platelet aggregation upon damage of the blood vessel wall is a critical step in aggregate formation, the ligands that favor optimal immobilization of the circulating vWF (45) remain to be identified. A vaste number of previous studies have suggested that interstitial collagen types I and III (and to a lesser extent V) could be the candidate ligands. However, their localization in the connective tissues significantly below the zone interfacing the subendothelial basement membrane and the interstitium raises some doubts about their physiological relevance in the early phases of vascular repair. Instead, the intimate association of Col VI microfilaments with the basement membrane on one hand (46) and the interstitial collagen fibrils on the other (47) strongly supports an important role for this collagen in binding the circulating vWF at the sites of vascular injury. Furthermore, the colocalization of Col VI and vWF in the vascular subendothelium (48, 49), recently confirmed at the ultrastructural level (50), strongly points to the possibility that Col VI may represent a central component of the subendothelial matrix contributing to platelet aggregation upon rupture of the blood vessel wall. However, previous studies utilizing pepsin-digested and/or guanidine HCl-extracted Col VI tetramers have failed to demonstrate a significant role for this collagen under conditions of high shear rates (23). At present, the nature of the discrepancy between urea- versus GuHCl-extracted Col VI is not clear, nor was it investigated in detail here, but several explanations may be considered. The loss of platelet aggregation-promoting activity of the GuHCl-extracted collagen may be attributed to a more severe unfolding of the molecule by exposure to GuHCl, or inhibitory contaminants may be present in the Col VI preparation based on GuHCl extraction. One such possible contaminant may be the proteoglycan decorin noted to remain associated with Col VI tetramers under such purification procedures (47). Finally, it remains possible that urea but not GuHCl extraction brings out a reactivity that does not occur in the native structure.

The mode and extent of platelet adhesion/aggregation onto Col VI at high shear rates was found to be similar to that reported for collagen type I (15, 51) and was strictly proportional to the amount of vWF that associated with the collagen substrate. Our findings are in disagreement with those previously reported and implicating the alpha 2beta 1 integrin in the direct arrest and tethering of platelets on Col VI under high shear rates (6, 52) but do not preclude the possibility that both this receptor and glycoprotein VI (53) may be responsible for the transduction of specific intracellular signals essential for further activation of platelets, following the initial vWF/GPIbalpha -dependent contact with the collagen substrate.

Crystallographic analysis of the wild type and point-mutated A3(vWF) domain reveals that, opposite to the I domain of the alpha 2beta 1 collagen binding integrin, disruption of the vestigial MIDAS motif of the A3(vWF) domain does not affect collagen binding (54, 55). Because the alpha 2beta 1 integrin has an elected preference for the triple helix of collagens, the above finding is overtly in accord with our observations that the A3(vWF) domain is not involved in the vWF interaction with the triple-helical region of Col VI. Accordingly, the Col VI interaction site of the A3(vWF) domain may reside within the globular domains of the collagen and/or be dependent upon a specific macromolecular structure assumed by the intact, but not the pepsin-digested tetramer deprived of globular domains. This conclusion is in accordance with the A3(vWF)-mediated collagen type I-vWF interaction for which there is a strict requirement of a higher order-organized fibrillar structure to achieve maximal promotion of platelet aggregation (8). Nonetheless, the marked difference in macromolecular configuration between interstitial collagens and the microfilamentous Col VI indicates that the structural nature of the A3(vWF) binding sites must differ in these molecules. Yet, the versatility of this binding site is highlighted by the indiscriminate ability of the A3(vWF) domain to interact with fibrillar collagen type I, monomeric type III, and tetrameric Col VI. The A3(vWF) domain has recently been shown to contain a binding site(s) for both interstitial collagens (15, 19, 21, 54) and the basement membrane collagen type IV (21) but has been proposed to lack binding affinity for Col VI, for which a pivotal binding role has been attributed to the classical collagen-binding A1(vWF) domain (21). Our experiments, in static phase using intact Col VI tetramers purified from three different tissues avoiding the use of GuHCl, revealed that the A1(vWF)-Col VI binding accounted for about 60% of the interaction. Moreover, blockade of either the A1(vWF)-Col VI or the A3(vWF)-Col VI interaction demonstrated an essential role for both A(vWF) domains in promoting the high shear rate-induced platelet adhesion/aggregation. Thus, our results are in disagreement with those of Hoylaerts et al. (21) and may reconduce to subtle structural alterations in the Col VI tetramers deriving from diverse extraction/purification procedures. These alterations may similarly be central for the differential loss of the platelet adhesion-promoting activity at high shear rates (23).

Mapping studies based upon the combined usage of pepsin-digested Col VI tetramers, recombinant polypeptides corresponding to the noncollagenous globular regions of the alpha 3(VI) chain, and anti-Al(vWF)/A3(vWF) antibodies were instrumental in localizing the main A1(vWF) binding site within the globular portion of the Col VI molecule. This site could be identified within the A7(VI) module. This module inhibited platelet adhesion to the collagen under high flow conditions and, in contrast to the recombinant polypeptide rvWF(445-733) and to the anti-A1(vWF) antibody NMC-4, did neither affect the GPIbalpha -vWF binding nor interfere with the A3(vWF)-Col VI interaction. It has previously been reported that in the acquired autoimmune disease vWD, circulating autoantibodies reacting with both the A1(vWF) and A3(vWF) domains may be present that inhibit the vWF-collagen interaction without affecting the ristocetin-induced GPIbalpha -vWF interaction (57). Similarly, a number of experiments using recombinant mutated vWF polypeptides as well as studies on individuals carrying genetic mutations that result in substitutions of amino acids critical for the GPIbalpha -A1(vWF) interaction have also suggested that these two A1(vWF) binding functions can be attributed to disparate binding motifs (15, 18, 58-60). Recent crystallographic analysis of A1(vWF) (61) and A1(vWF)-NMC-4 Fab complex (62) provide structural evidence for a distinct localization of GPIbalpha and other functional sites in the crystal. These findings and our data suggest that the A1(vWF) binding sites for the platelet receptor GPIbalpha and collagens might be distinct.

In conclusion, we propose that to achieve maximal efficiency of vWF in initiating platelet adhesion onto Col VI under conditions of high shear rates, both A1(vWF) and A3(vWF) are necessary. Their concerted participation would provide the biomechanical conditions supporting reversible GPIbalpha -dependent platelet adhesion, alpha IIbbeta 3 activation and its binding to the RGD sequence of vWF, and platelet arrest onto the Col VI. In the setting of vascular lesions, irreversible platelet adhesion to Col VI might enhance the platelet activation response and aggregate formation followed by the activity of alpha IIbbeta 3, alpha 2beta 1, and GP VI (63). Thus, our findings provide new prospects for the understanding of the molecular mechanism responsible for platelet adhesion phenomena and open new avenues for exploring the possible relevance of functional defects in the A1(vWF) and A3(vWF) domains of vWD and for developing new antithrombotic drugs.

    ACKNOWLEDGEMENTS

We are indebted to Drs. Zaverio Ruggeri and L. W. Hoyer for providing monoclonal antibodies and recombinant vWF polypeptides and for helpful suggestions. Dr. Roberto Doliana and Bruna Wassermann are thanked for their assistance in the preparation of recombinant Col VI polypeptides, and Maria Teresa Mucignat is thanked for her supporting technical assistance.

    FOOTNOTES

* This work was supported by AIRC (to A. C.) and by Progetti Ricerca Finalizzata IRCCS 1994 (to L. D. M. and A. C.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger Dagger To whom correspondence should be addressed at Servizio Immunotrasfusionale e Analisi cliniche, Centro di Riferimento Oncologico, Via Pedemontana Occidentale, 12, 33081 Aviano (PN), Italy. Tel.: ++390-434-659 360; Fax: ++390-434-659 427; E-mail: ldemarco{at}ets.it.

The abbreviations used are: vWF, von Willebrand factor; vWD, von Willebrand's disease; rvWF, recombinant polypeptide of vWF; Col VI, type VI collagen; mAb, monoclonal antibody; GP, glycoprotein; BSA, bovine serum albumin; GuHCl, guanidine HCl.

2 According to the nomenclature proposed by Bork and Koonin (64) for the vWF type A domains (65).

    REFERENCES
Top
Abstract
Introduction
References

  1. Agbanyo, F. R., Sixma, J. J., de Groot, P. G., Languino, L. R., and Plow, E. F. (1993) J. Clin. Invest. 92, 288-296[Medline] [Order article via Infotrieve]
  2. Beumer, S., Heijnen, H. F., Ijsseldijk, M. J., Orlando, E., de Groot, P. G., and Sixma, J. J. (1995) Blood 86, 3452-3460[Abstract/Free Full Text]
  3. Godyna, S., Diaz Ricart, M., and Argraves, W. S. (1996) Blood 88, 2569-2577[Abstract/Free Full Text]
  4. van Zanten, H. G., Saelman, E. U., Schut Hese, K. M., Wu, Y. P., Slootweg, P. J., Nieuwenhuis, H. K., de Groot, P. G., and Sixma, J. J. (1996) Blood 88, 3862-3871[Abstract/Free Full Text]
  5. Kehrel, B., Kronenberg, A., Rauterberg, J., Niesing Bresch, D., Niehues, U., Kardoeus, J., Schwippert, B., Tschope, D., van de Loo, J., and Clemetson, K. J. (1993) Blood 82, 3364-3370[Abstract]
  6. Saelman, E. U., Nieuwenhuis, H. K., Hese, K. M., de Groot, P. G., Heijnen, H. F., Sage, E. H., Williams, S., McKeown, L., Gralnick, H. R., and Sixma, J. J. (1994) Blood 83, 1244-1250[Abstract/Free Full Text]
  7. Zaidi, T. N., McIntire, L. V., Farrell, D. H., and Thiagarajan, P. (1996) Blood 88, 2967-2972[Abstract/Free Full Text]
  8. Sixma, J. J., van Zanten, H. G., Huizinga, E. G., van der Plas, R. M., Verkley, M., Wu, Y.-P., Gros, P., and de Groot, P. G. (1997) Thromb. Haemostasis 78, 434-438[Medline] [Order article via Infotrieve]
  9. Savage, B., Saldivar, E., and Ruggeri, Z. M. (1996) Cell 84, 289-297[Medline] [Order article via Infotrieve]
  10. Bahnak, B. R., Coulombel, Q., Assouline, L., Keibiriou-Nabias, Z., Pietu, G., Drouet, L., Caen, J. P., and Meyer, D. (1989) J. Cell. Physiol. 138, 305-310[Medline] [Order article via Infotrieve]
  11. Alevriadou, B. R., Moake, J. L., Turner, N. A., Ruggeri, Z. M., Folie, B. J., Phillips, M. D., Schreiber, A. B., Hrinda, M. E., and McIntire, L. V. (1993) Blood 81, 1263-1276[Abstract]
  12. Baruch, D., Denis, C., Marteaux, C., Schoevaert, D., Coulombel, L., and Meyer, D. (1991) Blood 77, 519-527[Abstract]
  13. Galbusera, M., Zoja, C., Donadelli, R., Paris, S., Morigi, M., Benigni, A., Figliuzzi, M., Remuzzi, G., and Remuzzi, A. (1997) Blood 90, 1558-1564[Abstract/Free Full Text]
  14. Siediecki, C. A., Lestini, B. J., Kottke Marchant, K. K., Eppell, S. J., Wilson, D. L., and Marchant, R. E. (1996) Blood 88, 2939-2950[Abstract/Free Full Text]
  15. Cruz, M. A., Yuan, H., Lee, J. R., Wise, R. J., and Handin, R. I. (1995) J. Biol. Chem. 270, 10822-10827[Abstract/Free Full Text]; Correction (1995) J. Biol. Chem. 270, 19668
  16. Ruggeri, Z. M. (1997) J. Clin. Invest. 99, 559-564[Free Full Text]
  17. Pareti, F. I., Niija, K., McPerson, J. M., and Ruggeri, Z. M. (1987) J. Biol. Chem. 262, 13835-13841[Abstract/Free Full Text]
  18. Lankhof, H., Damas, C., Schiphorst, M. E., Ijsseldijk, M. J., Bracke, M., Sixma, J. J., Vink, T., and de Groot, P. G. (1997) Blood 89, 2766-2772[Abstract/Free Full Text]
  19. Lankhof, H., van Hoeij, M., Schiphorst, M. E., Bracke, M., Wu, Y. P., Ijsseldijk, M. J., Vink, T., de Groot, P. G., and Sixma, J. J. (1996) Thromb. Haemostasis 75, 950-958[Medline] [Order article via Infotrieve]
  20. Sixma, J. J., Schiphorst, M. E., Verweij, C. L., and Pannekoek, H. (1991) Eur. J. Biochem. 196, 369-375[Abstract]
  21. Hoylaerts, M. F., Yamamoto, H., Nuyts, K., Vreys, I., Deckmyn, H., and Vermylen, J. (1997) Biochem. J. 324, 185-191[Medline] [Order article via Infotrieve]
  22. Denis, C., Baruch, D., Kielty, C. M., Ajzenberg, N., Christophe, O., and Meyer, D. (1993) Arterioscler. Thromb. 13, 398-406[Abstract]
  23. Ross, J. M., McIntire, L. V., Moake, J. L., and Rand, J. H. (1995) Blood 85, 1826-1835[Abstract/Free Full Text]
  24. Handa, M., Titani, K., Holland, L. Z., Roberts, J. R., and Ruggeri, Z. M. (1986) J. Biol. Chem. 261, 12579-12585[Abstract/Free Full Text]
  25. De Marco, L., Mazzucato, M., Masotti, A., Fenton, J. W.,2d, and Ruggeri, Z. M. (1991) J. Biol. Chem. 266, 23776-23783[Abstract/Free Full Text]
  26. Niija, K., Hodson, E., Bader, R., Byers-Ward, V., Koziol, J. A., Plow, E. D., and Ruggeri, Z. M. (1987) Blood 70, 475-483[Abstract]
  27. Trapani-Lombardo, V., Hodson, E., Roberts, J. R., Kunicki, T. J., Zimmerman, T. S., and Ruggeri, Z. M. (1985) J. Clin. Invest. 76, 1950-1958[Medline] [Order article via Infotrieve]
  28. Mohri, H., Yoshioka, A., Zimmerman, T. S., and Ruggeri, Z. M. (1989) J. Biol. Chem. 264, 17361-17367[Abstract/Free Full Text]
  29. Pareti, F. I., Cattaneo, M., Carpinelli, L., Zighetti, M. L., Bressi, C., Mannucci, P. M., and Ruggeri, Z. M. (1996) Thromb. Haemostasis 76, 460-468[Medline] [Order article via Infotrieve]
  30. Roth, G. J., Titani, K., Hoyer, L. W., and Hickey, M. J. (1986) Biochemistry 25, 8357-8361[Medline] [Order article via Infotrieve]
  31. Foster, P. A., Fulcher, C. A., Marti, T., Titani, K., and Zimmerman, T. S. (1987) J. Biol. Chem. 262, 8443-8446[Abstract/Free Full Text]
  32. Colombatti, A., Ainger, K., and Colizzi, F. (1989) Matrix 9, 177-185[Medline] [Order article via Infotrieve]
  33. Doliana, R., Mucignat, M. T., Segat, D., Zanussi, S., Fabbro, C., Lakshmi, T. R., and Colombatti, A. (1997) Matrix Biol. 16, 427-442
  34. Kuo, H. J., Keene, D. R., and Glanville, R. W. (1989) Biochemistry 28, 3757-3762[Medline] [Order article via Infotrieve]
  35. Kuo, H. J., Keene, D. R., and Glanville, R. W. (1995) Eur. J. Biochem. 232, 364-372[Abstract]
  36. Perris, R., Kuo, H. J., Glanville, R. W., and Bronner Fraser, M. (1993) Dev. Dyn. 198, 135-149[Medline] [Order article via Infotrieve]
  37. De Marco, L., Girolami, A., Zimmerman, T. S., and Ruggeri, Z. M. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 7424-7428[Abstract]
  38. De Marco, L., Mazzucato, M., Del Ben, M. G., Budde, U., Federici, A. B., Girolami, A., and Ruggeri, Z. M. (1987) J. Clin. Invest. 80, 475-482[Medline] [Order article via Infotrieve]
  39. Doliana, R., Bonaldo, P., and Colombatti, A. (1990) J. Cell Biol. 111, 2197-2205[Abstract]
  40. Sugimoto, M., Ricca, G., Hrinda, M. E., Schreiber, A. B., Searfoss, G. H., Bottini, E., and Ruggeri, Z. M. (1991) Biochemistry 30, 5202-5209[Medline] [Order article via Infotrieve]
  41. Goto, S., Salomon, D. R., Ikeda, Y., and Ruggeri, Z. M. (1995) J. Biol. Chem. 270, 23352-23361[Abstract/Free Full Text]
  42. Perris, R., Kuo, H. J., Glanville, R. W., Leibold, S., and Bronner Fraser, M. (1993) Exp. Cell Res. 209, 103-117[CrossRef][Medline] [Order article via Infotrieve]
  43. Segat, D., Pucillo, C., Marotta, G., Perris, R., and Colombatti, A. (1994) Blood 83, 1586-1594[Abstract/Free Full Text]
  44. Cruz, M. A., Handin, R. I., and Wise, R. J. (1993) J. Biol. Chem. 268, 21238-21245[Abstract/Free Full Text]
  45. Tsuji, S., Sugimoto, M., Kuwahara, M., Nishio, K., Takahashi, Y., Fujimura, Y., Ikeda, Y., and Yoshioka, A. (1996) Blood 88, 3854-3861[Abstract/Free Full Text]
  46. Kuo, H. J., Maslen, C. L., Keene, D. R., and Glanville, R. W. (1997) J. Biol. Chem. 272, 26522-26529[Abstract/Free Full Text]
  47. Keene, D. R., Ridgway, C. C., and Iozzo, R. V. (1998) J. Histochem. Cytochem. 46, 215-220[Abstract/Free Full Text]
  48. Rand, J. H., Wu, X. X., Potter, B. J., Uson, R. R., and Gordon, R. E. (1993) Am. J. Pathol. 142, 843-850[Abstract]
  49. Rand, J. H., Patel, N. D., Schwartz, E., Zhou, S. L., and Potter, B. J. (1991) J. Clin. Invest. 88, 253-259[Medline] [Order article via Infotrieve]
  50. Wu, X. X., Gordon, R. E., Glanville, R. W., Kuo, H. J., Uson, R. R., and Rand, J. H. (1996) Am. J. Pathol. 149, 283-291[Abstract]
  51. Polanowska Grabowska, R., and Gear, A. R. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 5754-5758[Abstract]
  52. Gralnick, H. R., Kramer, W. S., McKeown, L. P., Garfinkel, L., Pinot, A., Williams, S. B., and Krutzsch, H. (1996) Thromb. Res. 81, 113-119[CrossRef][Medline] [Order article via Infotrieve]
  53. Gibbins, J. M., Okuma, M., Farndale, R., Barnes, M., and Watson, S. P. (1997) FEBS Lett. 413, 255-259[CrossRef][Medline] [Order article via Infotrieve]
  54. Bienkowska, J., Cruz, M., Atiemo, A., Handin, R., and Liddington, R. (1997) J. Biol. Chem. 272, 25162-25167[Abstract/Free Full Text]
  55. Huizinga, E. G., Martijn van der Plas, R., Kroon, J., Sixma, J. J., and Gros, P. (1997) Structure 5, 1147-1156[Medline] [Order article via Infotrieve]
  56. Clark, E. A., and Brugge, J. S. (1995) Science 268, 233-239[Medline] [Order article via Infotrieve]
  57. van Genderen, P. J., Vink, T., Michiels, J. J., van't Veer, M. B., Sixma, J. J., and van Vliet, H. H. (1994) Blood 84, 3378-3384[Abstract/Free Full Text]
  58. Hilbert, L., Gaucher, C., de Romeuf, C., Horellou, M. H., Vink, T., and Mazurier, C. (1994) Blood 83, 1542-1550[Abstract/Free Full Text]
  59. Sinha, D., Bakhshi, M., Kunapuli, S., Vora, R., Gabriel, J. L., Kirby, E. P., and Budzynski, A. Z. (1994) Biochem. Biophys. Res. Commun. 203, 881-888[CrossRef][Medline] [Order article via Infotrieve]
  60. Christophe, O., Rouault, C., Obert, B., Pietu, G., Meyer, D., and Girma, J. P. (1995) Br. J. Haematol. 90, 195-203[Medline] [Order article via Infotrieve]
  61. Emsley, J., Cruz, M., Handin, R., and Liddington, R. (1998) J. Biol. Chem. 273, 10396-10401[Abstract/Free Full Text]
  62. Celikel, R., Varughese, K. I., Madhusudan, Yoshioka, A., Ware, J., and Ruggeri, Z. M. (1998) Nat. Struct. Biol. 5, 189-194[Medline] [Order article via Infotrieve]
  63. Nieuwenhuis, H. K., Akkerman, J. W. N., Houdijk, W. P. M., and Sixma, J. J. (1985) Nature 318, 470-472[Medline] [Order article via Infotrieve]
  64. Bork, P., and Koonin, E. V. (1996) Curr. Opin. Struct. Biol. 6, 366-375[CrossRef][Medline] [Order article via Infotrieve]
  65. Colombatti, A., and Doliana, R. (1996) The Superfamily with von Willebrand Factor VA Domains, Springer-Verlag, Berlin


Copyright © 1999 by The American Society for Biochemistry and Molecular Biology, Inc.