Cell Surface Heparan Sulfate Proteoglycans Participate in Factor VIII Catabolism Mediated by Low Density Lipoprotein Receptor-related Protein*

Andrei G. SarafanovDagger , Natalya M. AnanyevaDagger , Midori Shima§, and Evgueni L. SaenkoDagger ||

From the Dagger  Holland Laboratory, American Red Cross, Rockville, Maryland 20855,  George Washington University, Washington D. C. 20037, and the § Department of Pediatrics, Nara Medical University, Kashihara City, Nara 634-8522, Japan

Received for publication, September 1, 2000, and in revised form, January 4, 2001



    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

We have demonstrated previously that catabolism of a coagulation factor VIII (fVIII) from its complex with von Willebrand factor (vWf) is mediated by low density lipoprotein receptor-related protein (LRP) (Saenko, E. L., Yakhyaev, A. V., Mikhailenko, I., Strickland, D. K., and Sarafanov, A. G. (1999) J. Biol. Chem. 274, 37685-37692). In the present study, we found that this process is facilitated by cell surface heparan sulfate proteoglycans (HSPGs). This was demonstrated by simultaneous blocking of LRP and HSPGs in model cells, which completely prevented fVIII internalization and degradation from its complex with vWf. In contrast, the selective blocking of either receptor had a lesser effect. In vivo studies of clearance of 125I-fVIII-vWf complex in mice also demonstrated that the simultaneous blocking of HSPGs and LRP led to a more significant prolongation of fVIII half-life (5.5-fold) than blocking of LRP alone (3.5-fold). The cell culture and in vivo experiments revealed that HSPGs are also involved in another, LRP-independent pathway of fVIII catabolism. In both pathways, HSPGs act as receptors providing the initial binding of fVIII-vWf complex to cells. We demonstrated that this binding occurs via the A2 domain of fVIII, since A2, but not other portions of fVIII or isolated vWf, strongly inhibited cell surface binding of fVIII-vWf complex, and the affinities of A2 and fVIII-vWf complex for the cells were similar. The A2 site involved in binding to heparin was localized to the region 558-565, based on the ability of the corresponding synthetic peptide to inhibit A2 binding to heparin, used as a model for HSPGs.



    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Factor VIII (fVIII)1 is an essential component of the intrinsic pathway of blood coagulation, since genetic deficiency in fVIII results in a coagulation disorder known as hemophilia A and occurs in 1 per 5000 males. In the intrinsic pathway, activated fVIII (fVIIIa) functions as a cofactor for the serine protease factor IXa, and their membrane-bound complex (Xase complex) activates factor X to factor Xa (1). Factor Xa subsequently participates in activation of prothrombin into thrombin, the key enzyme of the coagulation cascade.

FVIII is a glycoprotein (~300 kDa, 2332 amino acid residues) consisting of three homologous A domains, two homologous C domains, and the unique B domain, which are arranged in the order of A1-A2-B-A3-C1-C2 (2). Prior to its secretion to plasma, fVIII is processed intracellularly to a series of Me2+-linked heterodimers produced by cleavage at the B-A3 junction (3) and by a number of additional cleavages within the B domain (2). These cleavages generate a heavy chain (HCh) consisting of the A1 (residues 1-336), A2 (residues 373-740), and B domains (residues 741-1648), and a light chain (LCh) composed of the domains A3 (residues 1690-2019), C1 (residues 2020-2172), and C2 (residues 2173-2332).

In circulation, most of fVIII is bound to vWf, which confers from physiological concentrations of the proteins, which are ~1 (4) and ~50 nM (5), respectively, and a high affinity (0.2-0.5 nM) of their interaction (6, 7). Binding to vWf prevents fVIII from premature interaction with components of Xase complex and is also required for maintenance of the normal fVIII level in plasma (8), since vWf deficiency in both humans (8, 9) and animals (10, 11) leads to a secondary deficiency of fVIII.

We have recently shown that fVIII catabolism from its complex with vWf in vitro and in vivo is mediated by low density lipoprotein receptor-related protein (LRP) (12). LRP, a member of the low density lipoprotein receptor family (13), is responsible for plasma clearance of lipoprotein remnants, serine proteinases, and their complexes with inhibitors (serpins) (13, 14). LRP is most prominent in liver on hepatocytes, and in vasculature it is presented on the surface of smooth muscle cells, fibroblasts, and macrophages (15). Besides fVIII, LRP mediates the clearance of a number of other proteins involved in blood coagulation and fibrinolysis, such as factors IXa (16) and Xa (17, 18), plasminogen activators, and their complexes with plasminogen activator inhibitor (19-21). A unique place among LRP ligands belongs to 39-kDa receptor-associated protein (RAP), which binds to LRP with a high affinity (Kd = 4 nM) and efficiently inhibits binding and endocytosis of all known LRP ligands (22).

The sites of fVIII involved in interaction with LRP were localized within the A2 domain residues 484-509 (12) and within the C-terminal portion of the C2 domain (23). Since the latter region of fVIII is likely to be blocked by vWf (23, 24), the C2 site could contribute to the clearance of fVIII only in the absence of vWf. This is consistent with the reported faster clearance of fVIII in vWf-deficient patients and animals (8, 25, 26), which was shown to be mediated by LRP (11).

The LRP-mediated endocytosis of many ligands is facilitated by cell surface heparan sulfate proteoglycans (HSPGs), one of the components constituting extracellular matrix. Among the LRP ligands, lipoprotein lipase (27), apoE-containing lipoproteins (28, 29), thrombospondin (30), thrombin-protease nexin 1 complex (31), and tissue factor pathway inhibitor (19, 32) are HSPGs-binding proteins. HSPGs serve either as coreceptors of LRP providing the initial binding of the ligands to the cell surface and their subsequent presentation to LRP (14, 29), or function as catabolic receptors themselves, acting independently of LRP (33). All LRP ligands interacting with HSPGs are also able to bind to heparin (34), which is structurally similar to carbohydrate portions of HSPG molecules, and represent a useful model for studying these interactions in a purified system.

Noteworthy, the recently reported Kd of 116 nM for fVIII interaction with LRP (12) is much higher than the normal (~1 nM) concentration of fVIII in plasma (4). This implies that the direct binding of plasma fVIII-vWf complex to LRP is negligible and suggests possible involvement of other receptor(s) in this process. In the present study, we examined participation of cell surface HSPGs in the binding and catabolism of fVIII-vWf complex, based on the ability of fVIII to interact with heparin (35). We demonstrated that HSPGs are indeed responsible for the initial binding of fVIII-vWf complex to the surface of various LRP-expressing cells and subsequent facilitation of fVIII catabolism both in cell culture and in vivo. We found that the binding occurs via the fVIII moiety of fVIII-vWf complex and localized the major heparin-binding site of fVIII within its A2 domain.


    EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Reagents-- Chondroitin sulfate A, heparin (average molecular weight 17-19 kDa), and biotinylated heparin were purchased from Sigma and Celsus Laboratories Inc., respectively. Chondroitin sulfate A was biotinylated using EZ-Link Biotin-LC-Hydrazide (Pierce) as described (36). Human coagulation factors IXa, X, and Xa were purchased from Enzyme Research Laboratories, and heparinase I was purchased from Sigma. Active site fluorescently labeled factor IXa (Fl-FFR-fIXa) was a generous gift of Dr. Philip Fay. Monoclonal antibody 8860 recognizing the A2 domain of fVIII was kindly provided by Baxter/Hyland Healthcare Inc. The rabbit polyclonal anti-LRP antibody Rab 2629, RAP, and 125I-labeled activated alpha 2-macroglobulin were kindly provided by Dr. Dudley Strickland. Phosphatidylserine (PS) and phosphatidylcholine (PC) were purchased from Sigma. Phospholipid vesicles containing 25% PS and 75% PC were prepared as described previously (37). The fVIII peptides 432-456, 484-509, and 558-565 were synthesized using a 9050 Milligen synthesizer (Millipore) by the Fmoc ((9-fluorenyl)methoxycarbonyl) method and pentafluoro-ester activation chemistry and were purified by reverse phase high pressure liquid chromatography using a C18 column (Waters) in a gradient of 0-70% acetonitrile in 0.1% trifluoroacetic acid. The 2.2-3.5 mM solutions of peptides were dialyzed versus 20 mM HEPES, pH 7.4, 0.15 M NaCl (HBS) using membrane with 1-kDa cut-off (Pierce).

Proteins-- FVIII was purified from therapeutic concentrates prepared by Method M, American Red Cross (38). HCh and LCh of fVIII were prepared as described previously (6). The A1 and A2 subunits were obtained from thrombin-activated fVIII using ion exchange chromatography on a Mono S column (Amersham Pharmacia Biotech) (12).

Radiolabeling of fVIII and Its A2 Subunit-- Prior to labeling, fVIII and A2 were dialyzed into 0.2 M sodium acetate, pH 6.8, containing 5 mM calcium nitrate. Five µg of fVIII or A2 in 30 µl of the above buffer were added to lactoperoxidase beads (Worthington) containing 5 µl of Na125I (100 mCi/ml, Amersham Pharmacia Biotech) and 5 µl of 0.03% H2O2 (Mallinckrodt) and incubated for 4 min at room temperature. Unreacted Na125I was removed by chromatography on a PD10 column (Amersham Pharmacia Biotech). The specific radioactivities of 125I-labeled fVIII and A2 were 3-6 µCi/µg of protein. The activity of 125I-fVIII (3650 units/mg) determined in the one-stage clotting assay (39) was similar to that of unlabeled fVIII (3840 units/mg).

Assays for Cell-mediated Surface Binding, Internalization, and Degradation of Ligands-- LRP-expressing mouse embryonic fibroblast cells (MEF) and mouse embryonic fibroblast cells genetically deficient in LRP biosynthesis (PEA 13) were obtained from Dr. Joachim Herz (University of Texas Southwestern Medical Center, Dallas, TX) and maintained as described (40). Cells were grown to a density of 2 × 105 cells/well as we described previously (12). Human smooth muscle cells (SMC) and human alveolar epithelial cells (T2) were obtained from American Tissue Culture Collection. SMC and T2 cells were grown to a density of 105 cells/well in DMEM and Leibovitz's L-15 medium, respectively, containing 10% fetal bovine serum (Life Technologies, Inc.). The complex of 125I-fVIII or unlabeled fVIII with vWf was prepared by incubating the proteins at a 1:50 molar ratio in HBS, 5 mM CaCl2 for 30 min at 25 °C. The complex formation was verified by gel filtration as described previously (12). To assess the contribution of HSPGs in fVIII uptake, the cells were preincubated in the medium containing heparinase-I (Sigma) at a concentration of 0.005 IU/ml for 30 min at 37 °C followed by three washes with HBS containing 0.1% bovine serum albumin. Surface binding, internalization, and degradation assays were conducted as described previously (41). In some experiments, surface binding was determined after incubation at 4 °C to prevent endocytosis (42). Surface binding of radiolabeled ligands was defined as the amount of radioactivity released by treatment with mixture of trypsin (50 µg/ml) and proteinase K (50 µg/ml) (Sigma) as described (43). The radioactivity, which remained associated with the cells, was considered as internalized (41). Degradation was defined as radioactivity in the medium that was soluble in 10% trichloroacetic acid. The value of degradation was corrected for noncellular degradation by subtracting the acid-soluble radioactivity in parallel wells lacking cells.

Factor Xa Generation Assay-- The rate of conversion of factor X to factor Xa was measured in a purified system (39), in which fVIIIa was substituted by its A2 subunit as described (44, 45). The A2 subunit (200 nM) was preincubated with varying concentrations of heparin (0-100 µg/ml) in HBS, 5 mM CaCl2, 0.01% Tween 20, and 200 µg/ml bovine serum albumin for 30 min at room temperature. This was followed by the addition of factor IXa (5 nM) and PSPC vesicles (10 µM) and incubation for 10 min, prior to addition of factor X (300 nM). To determine the initial rates of factor Xa generation, the aliquots were taken at 10, 20, 30, and 45 min, and the reaction was stopped with 0.05 M EDTA. Factor Xa generation was determined from conversion of synthetic chromogenic substrate S-2765 (Chromogenix, Sweden) as described (45).

Fluorescence Anisotropy Measurements-- The measurements of interaction of the A2 subunit with Fl-FFR-fIXa were performed as described (45). A2 was preincubated with varying concentrations of heparin for 15 min at 25 °C in HBS, 5 mM CaCl2. The anisotropy was measured in a 0.2-ml cell upon addition of PSPC vesicles (50 µM) and Fl-FFR-fIXa (30 nM) in the presence or absence of factor X (400 nM). The measurements were carried out using SLM 8000C spectrofluorometer (SLM Instrument Inc.) at the excitation wavelength of 495 nm and emission wavelength of 524 nm. The data were recorded 5 times for each reaction and averaged.

Kinetic Measurements Using Surface Plasmon Resonance (SPR)-- The kinetics of interaction of fVIII-vWf complex, fVIII, its fragments, and vWf with heparin or chondroitin sulfate was measured by SPR technique using Biacore 3000 (Biacore, Sweden). Biotinylated heparin (100 µg/ml) or chondroitin sulfate (100 µg/ml) was immobilized at the level of 300 resonance units on the surface of a biosensor SA chip in HBS, 5 mM CaCl2, 0.05% Tween 20. The binding of the above ligands was measured in the same buffer at a flow rate of 10 µl/min. Dissociation was measured upon replacement of the ligand solution for the buffer without ligand. The chip surface was regenerated by washing with 1 M NaCl, 0.05% Tween 20. The kinetic parameters were derived from the kinetic curves using Biacore BIA evaluation 3.1 software.

Immunofluorescence Microscopy-- Human hepatocellular carcinoma cells HEP G2 (American Tissue Culture Collection) were grown on coverslips to 80% confluence in DMEM containing 10% fetal bovine serum at 37 °C, 6% CO2. Intact cells or cells treated with heparinase as above were incubated with 10 nM of fVIII-vWf complex in 0.5 ml of DMEM, 1% bovine serum albumin for 2 h at 4 °C in the absence or presence of RAP (1 µM). The cells were washed twice with phosphate-buffered saline, fixed in 2% formaldehyde in phosphate-buffered saline, and stained for fVIII, LRP, and HSPGs by triple label immunofluorescence staining. Staining for fVIII was performed by subsequent incubation of cells with mouse anti-fVIII monoclonal antibody 8860, biotinylated anti-mouse antibody, and Texas Red-conjugated Avidin D (2.5 µg/ml). Staining for LRP was performed by subsequent incubation with rabbit polyclonal anti-LRP antibody Rab 2629, biotinylated anti-rabbit IgG, and fluorescein Avidin DCS (2.5 µg/ml). Staining for HSPGs was performed by subsequent incubation with mouse monoclonal anti-heparan sulfate antibody 10E4 (Seikagaku Corp.), biotinylated anti-mouse IgG, and 7-amino-4-methylcoumarin-3-acetic acid Avidin D (5 µg/ml). The primary antibodies were added at 5 µg/ml and incubated with the cells for 1 h at 25 °C. The secondary biotinylated antibodies and fluorescent reagents were purchased from Vector Laboratories and used according to the supplied protocols. Avidin/biotin blocking kit (Vector Laboratories) was applied after staining with each fluorescent probe. The specificity of the staining was controlled using normal mouse or rabbit immunoglobulins instead of the primary antibodies. For microscopy, the coverslips with triple-stained cells were mounted on slides with ProLong Antifade mounting medium (Molecular Probes, Inc.). The images were obtained using an Eclipse E800 microscope (Nikon) equipped with a set of selective fluorescent filter blocks and digital SPOT RT camera (Diagnostic Instruments, Inc.). Simultaneous visualization of fVIII, LRP, and HSPGs was performed by merging the single-dye images using the SPOT Advanced Program Mode.

Clearance of 125I-fVIII-vWf Complex in Mice-- Prior to the experiment, 125I-fVIII, vWf, and RAP were dialyzed into HBS, 5 mM CaCl2 buffer. BALB/c mice (12-14 weeks old, weight 20-24 g) were injected in the tail vein with 100-µl solutions of either 200 µM protamine or 150 µM RAP alone or with 100 µl of 200 µM protamine and 150 µM RAP together in the above buffer. After a 2-min interval, 100-µl samples of 125I-fVIII-vWf complex formed from 125I-fVIII (15 nM) and vWf (750 nM) were injected into mice either in the absence or in the presence of 100 units (1 mg) of heparin. In the control experiment, 125I-fVIII-vWf complex was injected in the absence of protamine and RAP. Blood samples of 30-40 µl were withdrawn from each mouse via retroorbital puncture into 15 µl of 0.1 M sodium citrate buffer, pH 7.4, at selected time intervals (1, 5, 10, 15, 30, 60, 120, 240, 360, and 480 min). The radioactivity per ml of blood at each time point was calculated from radioactivities of the samples and their volumes. The percentage of 125I-fVIII remaining in circulation was calculated assuming the radioactivity of aliquots taken 1 min after injection of 125I-fVIII-vWf complex as 100% (46, 47). To verify that no significant fVIII clearance occurred during the 1st min, we compared the radioactivities of 1-min aliquots (n = 20) with the corresponding initial (0 min) radioactivity values. The 0-min values were calculated from the total amount of injected radioactivity and the blood volume of each mouse determined using the formula V = 0.09 × W0.88 (48), where W is the animal weight in grams and V is the total blood volume in milliliters. Lack of statistically significant differences (p = 0.34 according to Student's t test) between these two groups of values justified our assumption that the radioactivity in blood at 1 min after injection of 125I-fVIII-vWf complex can be considered as 100%. The time course of each of the above conditions was examined in four mice and averaged. The kinetics of 125I-fVIII clearance from circulation was fitted to the previously used double-exponential model (12) by using the Sigmaplot 3.0 computer program (Jandel Scientific).


    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

HSPGs Are the Primary Receptors Responsible for the Initial Binding of fVIII-vWf Complex to LRP-expressing Cells-- We demonstrated previously that RAP inhibited endocytosis and degradation of fVIII from its complex with vWf by LRP-expressing cells, indicating that LRP is involved in catabolism of fVIII (12). Therefore, we examined the role of LRP in the initial binding of fVIII-vWf complex to the cell surface. As seen in Fig. 1A, the binding levels of 125I-fVIII-vWf complex were similar for both LRP-expressing MEF cells and LRP-deficient PEA13 cells. Moreover, RAP did not have a significant inhibitory effect on the binding to MEF cells. These findings suggest that receptor(s) other than LRP is responsible for the surface binding of 125I-fVIII-vWf complex. We next examined whether these receptors could be HSPGs by testing the effect of heparin on the surface binding. As seen in Fig. 1A, heparin significantly reduced the cell surface binding for both LRP-expressing and LRP-deficient cells, supporting our assumption that HSPGs are the major surface receptors responsible for the initial binding of fVIII-vWf complex. Consistent with this assumption, heparin also inhibited degradation of fVIII by MEF cells (Fig. 1B). To exclude the possibility that heparin inhibited fVIII degradation by interfering with fVIII binding to LRP, we tested the effect of heparin on 125I-fVIII binding to immobilized LRP in the assay described previously (12). We found that heparin did not inhibit the binding (data not shown), suggesting the following: (i) inhibition of fVIII degradation in LRP-expressing cells by heparin was not related to inhibition of fVIII interaction with LRP and (ii) heparin- and LRP-binding sites of fVIII do not overlap. Notably, LRP-deficient PEA13 cells also degraded fVIII at the level constituting 22% of that degraded by LRP-expressing cells (Fig. 1B). Although this level was significantly lower in comparison with MEF cells, the ability of LRP-deficient cells to degrade fVIII implies the existence of an alternative, LRP-independent pathway of fVIII catabolism. Since it was inhibited by heparin (Fig. 1B), HSPGs appear to be also required for this LRP-independent pathway.



View larger version (20K):
[in this window]
[in a new window]
 
Fig. 1.   Effect of RAP and heparin on the surface binding and degradation of 125I-fVIII-vWf by MEF and PEA13 cells. 125I-fVIII-vWf complex (1 nM) was added to wells containing 2 × 105 of LRP-expressing MEF cells (solid bars) or LRP-deficient PEA 13 cells (gray bars) in the absence or presence of heparin (100 µg/ml) or RAP (1 µM) and incubated for 6 h at 37 °C. The surface binding of 125I-fVIII (A) and its degradation (B) were subsequently determined as described under "Experimental Procedures." Each data point represents the mean value and S.D. of duplicate determinations.

The Major fVIII Site Involved in Binding to HSPGs Is Located within Its A2 Domain-- Since the LRP binding site of fVIII is located within its A2 domain (12), it is expected that LRP-expressing cells will catabolize the isolated A2 domain as well. To examine whether catabolism of A2 and fVIII from its complex with vWf occurs in a quantitatively similar fashion, we studied dose dependence of their surface binding and degradation by MEF cells. As seen in Fig. 2, the corresponding curves of the surface binding and degradation of A2 and fVIII from its complex with vWf are similar.



View larger version (20K):
[in this window]
[in a new window]
 
Fig. 2.   Comparison of the surface binding and degradation of 125I-A2 and 125I-fVIII from its complex with vWf by MEF cells. Wells containing 2 × 105 of LRP-expressing MEF cells were preincubated without (closed symbols) or with (open symbols) heparinase as described under "Experimental Procedures." This was followed by the addition of increasing concentrations of 125I-fVIII-vWf complex (, black-square) or 125I-A2 (open circle , ), incubation for 6 h at 37 °C, and determination of the surface binding (A) and degradation (B). In additional experiments shown in B, 125I-fVIII (Delta ) and 125I-A2 () were incubated with heparinase-treated MEF cells in the presence of RAP (1 µM). Each data point represents the mean value and S.D. of duplicate determinations.

We next examined whether HSPGs play a similar role in catabolism of the A2 subunit and fVIII. The preliminary evidence of involvement of HSPGs in A2 catabolism was derived from the inhibitory effect of heparin on the surface binding and degradation of A2 (data not shown). To confirm the role of HSPGs in catabolism of A2 and fVIII, we studied the effect of heparinase, which removes carbohydrate portions of proteoglycans, on the surface binding and degradation of these ligands. As seen in Fig. 2, this treatment reduced the surface binding and degradation of 125I-A2 and 125I-fVIII to the same level, indicating that interaction of fVIII-vWf complex with HSPGs is likely to occur primarily via the A2 domain. Notably, the addition of RAP to heparinase-treated cells did not inhibit the surface binding of the ligands (data not shown); however, it further reduced their degradation (Fig. 2B). In the control experiment, we confirmed that the functional activity of LRP was not impaired by heparinase treatment, since this treatment did not have any effect on internalization of a direct LRP ligand 125I-activated alpha 2-macroglobulin (40), data not shown. Altogether, the above experiments demonstrated that the A2 subunit behaves equivalently to fVIII-vWf complex in the catabolic process.

To examine whether involvement of HSPGs in LRP-mediated catabolism of A2 is a common feature of LRP-expressing cells, we tested the binding of A2 to human smooth muscle cells (SMC) and human alveolar epithelial cells (T2) expressing LRP and HSPGs (15). In both cell types heparin and heparinase significantly inhibited the surface binding, internalization, and degradation of 125I-A2 (Fig. 3). Addition of RAP to heparinase-treated cells had no effect on the 125I-A2 binding but led to a further decrease of its internalization and degradation. Thus, the effects of heparinase and RAP on A2 catabolism in MEF (Fig. 2), SMC, and T2 (Fig. 3) are similar, indicating that LRP and HSPGs are both involved in the A2 catabolism by different LRP-expressing cells.



View larger version (40K):
[in this window]
[in a new window]
 
Fig. 3.   Effect of RAP, heparin, and heparinase on the surface binding, internalization, and degradation of 125I-A2 subunit of fVIII by LRP-expressing SMC and T2 cells. Wells containing 105 SMC (gray bars) or T2 cells (hatched bars) were preincubated without or with heparinase as described under "Experimental Procedures." This was followed by the addition of 125I-A2 (1 nM) in the absence or presence of RAP (1 µM) or heparin (100 µg/ml) and determination of the surface binding (A and D), internalization (B and E), and degradation (C and F) of 125I-A2 after 6 h of incubation at 37 °C. Each data point represents the mean value and S.D. of duplicate determinations.

To confirm that the A2 domain is fully responsible for the binding of fVIII-vWf complex to cell surface HSPGs, we studied the effects of increasing concentrations of fVIII fragments and vWf on the surface binding of 125I-fVIII-vWf complex to MEF cells. As seen in Fig. 4, at a concentration of 200 nM, A2 inhibited this binding by 84%. Notably, pretreatment of MEF cells with heparinase resulted in a similar (87%) reduction of 125I-fVIII-vWf binding as shown in Fig. 2A. In contrast, neither A1/A3-C1-C2 heterodimer nor vWf were able to inhibit the binding of 125I-fVIII-vWf complex. This indicates that fVIII but not vWf is responsible for the binding of fVIII-vWf complex to cell surface HSPGs, and the major HSPGs-binding site of fVIII is located within the A2 domain.



View larger version (22K):
[in this window]
[in a new window]
 
Fig. 4.   Effect of fVIII fragments and vWf on the surface binding of fVIII-vWf complex to MEF cells. One nM of 125I-fVIII-vWf complex was added to wells containing 2 × 105 of LRP-expressing MEF cells in the presence of varying concentrations of A2 (open circle ), A1/A3-C1-C2 (), or vWf (Delta ) and incubated for 2 h at 4 °C, followed by determination of surface-bound radioactivity, as described under "Experimental Procedures." Each data point represents the mean value and S.D. of duplicate determinations.

The A2 Domain and fVIII-vWf Complex Bind to the Cells with Similar Affinities-- The presence of the major HSPGs-binding site within A2 implies that affinities of A2 and fVIII-vWf complex for the cell surface should be similar. To verify this, we first determined the affinity of 125I-A2 to MEF cells in a saturation binding experiment similar to that presented in Fig. 2 but performed at 4 °C to exclude internalization (data not shown). The nonspecific binding measured in the presence of 100-fold excess of unlabeled A2 constituted 18% of the total 125I-A2 binding. The specific binding was adequately described by a model implying existence of a single class of binding sites (9.6 × 104 sites per cell) with Kd of 15 ± 2.8 nM. To verify that A2 and fVIII-vWf complex bind to the same sites, we performed displacement of 125I-A2 (1 nM) by unlabeled A2 or fVIII-vWf complex. In this assay, A2 and fVIII-vWf complex were found to be equal as competitors (Fig. 5) with Ki values of 18.8 ± 2.2 and 21.4 ± 1.9 nM, respectively. The similarity of the Ki values further supports that the binding of fVIII-vWf complex to HSPGs is mediated by the A2 domain of fVIII.



View larger version (22K):
[in this window]
[in a new window]
 
Fig. 5.   Determination of affinities of A2 and fVIII-vWf complex for binding to MEF cells. MEF cells were incubated for 2 h at 4 °C with 125I-A2 (1 nM) in the presence of increasing concentrations of unlabeled A2 (open circle ) or fVIII-vWf complex () formed from varying concentrations of fVIII (4-128 nM) and the fixed concentration of vWf (1000 nM) as described under "Experimental Procedures." This was followed by determination of 125I-A2 binding to the cells. Each data point represents the mean value and S.D. of quadruplicate determinations. The solid lines show the best fit of the data to a model describing homologous or heterologous ligand displacement from a single class of binding sites using the LIGAND program. The dashed line is shown for the control experiment in which vWf (Delta ) was used as a competitor.

The Major Site within A2 and the Minor Site within LCh Are Involved in fVIII Binding to Heparin-- To examine whether A2 is the only site responsible for interaction of isolated fVIII with HSPGs, we tested the direct binding of fVIII, A2, and other fVIII fragments to heparin in SPR-based assay (Fig. 6). The kinetic parameters for fVIII and its fragments derived from Fig. 6 are shown in Table I. We found that fVIII, its A2 domain, and HCh (containing A2), but not A1, were able to bind to heparin, consistent with the presence of the heparin-binding site within the A2 subunit. The determined affinity of the A2 subunit for heparin is 25.8 nM. Unexpectedly, LCh was also able to bind heparin with a low affinity (Kd = 571 nM), indicating that it contains another heparin-binding site. Consistent with this observation, the fVIII binding kinetics was optimally fitted to a model implying existence of two heparin-binding sites, which affinities (Kd values of 28 and 652 nM) are similar to the values determined for A2 and LCh, respectively. The 23-fold lower affinity of the LCh site for heparin implies that its contribution to fVIII binding to HSPGs is not significant. In control experiments, the specificity of fVIII and A2 interaction with heparin was demonstrated using Biacore SA chip coated with biotinylated chondroitin sulfate which, similarly to heparin, is composed of negatively charged sulfated polysaccharides. The binding of fVIII (Fig. 6, curve 1b) and its A2 subunit (data not shown) constituted less than 7.3% of the corresponding binding of the ligands to heparin.



View larger version (27K):
[in this window]
[in a new window]
 
Fig. 6.   Interaction of fVIII-vWf complex, fVIII, its fragments, and vWf with heparin in SPR-based assay. Heparin was immobilized to a biosensor chip at a level of 300 resonance units (RU) as described under "Experimental Procedures." The binding of 500 nM of either fVIII (curve 1a), its HCh (curve 2), LCh (curve 3), A2 (curve 4), or A1 (curve 5) was measured for 5 min at a flow rate of 10 µl/min. In the control experiment (dotted curve 1b), fVIII binding to chondroitin sulfate, immobilized on the chip at the same level as heparin, was tested. Dissociation kinetics was measured upon replacement of the ligand solution for the buffer without a ligand. Inset shows interaction of 1000 nM vWf (curve 6) and 500 nM fVIII-vWf complex formed from 500 nM fVIII and 1000 nM vWf (curves 7) with heparin-coated chip.


                              
View this table:
[in this window]
[in a new window]
 
Table I
Kinetic parameters of the binding of fVIII-vWf complex, fVIII, its fragments and vWf to heparin
Interaction of vWf, fVIII-vWf complex, fVIII, and its fragments with immobilized heparin was assessed in an SPR-based experiment shown in Fig. 6. The kinetic data for fVIII-vWf complex and fVIII were optimally fitted to a model implying existence of two independent heparin-binding sites within the fVIII molecule, referred to as 1 and 2. The kinetics of HCh, A2, and LCh interaction with heparin were optimally fitted to a model assuming existence of one heparin-binding site within each fragment. The association rate constants (kon), dissociation rate constants (koff), and affinities (Kd = koff/kon) were derived from the SPR data by using Biacore software BIAevaluation 3.1.

We next compared the parameters of fVIII-vWf complex and vWf binding to heparin (derived from Fig. 6, inset). As seen in Table I, although the parameters of fVIII-vWf interaction with heparin are similar to those of isolated fVIII, isolated vWf bound to heparin with a low affinity (Kd = 8.4 µM). This confirms that its contribution to interaction of fVIII-vWf complex with heparin is negligible. Remarkably, the affinities of fVIII-vWf complex and A2 for heparin determined in a purified system (Table I) are close to the affinities of fVIII-vWf complex and A2 (18.8 and 21.4 nM, respectively) for the surface of MEF cells. Altogether, these data further support our hypothesis that the major fVIII site responsible for the binding to HSPGs is located within the A2 domain.

The A2 Domain Heparin-binding Site Includes the Residues 558-565-- Localization of the heparin-binding site within the A2 domain was initiated by the previous findings that heparin inhibits Xase activity (35, 49), and fVIIIa can be substituted by its A2 subunit in the Xase assay (45). As seen in Fig. 7A, heparin was inhibitory in the A2-dependent Xase assay; the effect was dose-dependent; and 90% inhibition was observed at 10 µg/ml (~600 nM).



View larger version (18K):
[in this window]
[in a new window]
 
Fig. 7.   Inhibition of the A2-dependent factor Xa generation and interaction between A2 and factor IXa by heparin. A, effect of heparin on the generation of factor Xa. The mixtures containing factor IXa (5 nM), PSPC vesicles (10 µM), A2 subunit (200 nM), and the indicated concentrations of heparin were incubated for 10 min, and the reactions were started by the addition of factor X (300 nM). The initial rates of factor Xa generation (Delta ) were determined as described under "Experimental Procedures." B, effect of heparin on interaction between A2 subunit and factor IXa. The A2 subunit (300 nM) was preincubated with indicated concentrations of heparin for 15 min. The anisotropy was measured upon the addition of PSPC vesicles (50 µM) and Fl-FFR-fIXa (30 nM) in the presence (black-square) or absence () of factor X (400 nM). In control experiments, the A2 subunit was omitted from the reaction mixtures with () or without (open circle ) factor X. Each point represents the mean value ± S.D. of five measurements.

Since it was previously shown that heparin does not inhibit interaction of the Xase complex with its substrate factor X (49), we proposed that heparin inhibits Xase assembly by preventing the A2 binding to factor IXa. To examine this possibility, we tested the effect of heparin on the A2 binding to factor IXa by fluorescent anisotropy technique. The experiment was based on the previous observation that anisotropy of Fl-FFR-fIXa increases moderately upon the binding of A2 (45), and this effect becomes more pronounced in the presence of factor X (44, 45). We found that heparin inhibited the increase of anisotropy in a dose-dependent fashion, both in the absence or presence of factor X (Fig. 7B). The maximal effect of heparin was observed at its concentration >= 30 µg/ml, which is similar to the concentration completely suppressing the factor Xase assay (Fig. 7A). In the control experiment performed in the absence of A2, heparin did not affect the anisotropy of Fl-FFR-fIXa in either absence or presence of factor X.

The above findings suggest that heparin blocks interaction between the A2 subunit and factor IXa, which might be due to the overlapping of the A2 domain binding sites for heparin and factor IXa. Since the A2 domain regions comprising residues 484-509 and 558-565 are directly involved in the interaction with factor IXa (45, 50), we tested the effects of the corresponding synthetic peptides on the A2 binding to heparin. In the SPR-based experiment, the peptide 558-565 inhibited the binding by 78% at a concentration of 800 µM (Fig. 8). In contrast, at the same concentration, the peptide 484-509 inhibited the binding by ~25%, and the peptide 417-428 was not inhibitory at all. This suggests that the A2 domain region 558-565 is involved in the fVIII binding to heparin and, possibly, to cell surface HSPGs.



View larger version (17K):
[in this window]
[in a new window]
 
Fig. 8.   Effect of synthetic peptides on the A2 binding to heparin. A, effect of the synthetic peptide 558-565 on A2 binding to heparin measured by SPR technique. Heparin was immobilized on the chip surface as described under "Experimental Procedures." The binding of the A2 subunit (200 nM) was measured in the absence (curve 1) or presence of increasing concentrations of the peptide (25, 50, 100, 200, 400, and 800 µM, curves 2-7, respectively). B, effect of synthetic peptides 432-456 (Delta ), 484-509 (open circle ), and 558-565 () on A2 binding to heparin. The equilibrium binding of A2 to immobilized heparin at indicated concentrations of each peptide was determined as in A. The A2 binding in the presence of peptides is expressed as the percentage of the A2 binding when no peptide was added.

Cell Surface Proteoglycans Participate in fVIII Catabolism in Vivo-- To examine whether HSPGs contribute to fVIII clearance in vivo, we performed clearance studies in mice in the presence of protamine, which prevents HSPGs from interaction with their ligands (32, 51). The data shown in Fig. 9 were fitted to the previously used double exponential model (12), implying existence of the fast and slow phases of fVIII clearance. This model is described by the following Equation 1:



View larger version (27K):
[in this window]
[in a new window]
 
Fig. 9.   Effect of protamine and RAP on clearance of 125I-fVIII-vWf in vivo. BALB/c mice were injected with 100 µl of either 200 µM (1 mg) protamine (Delta ) or 150 µM RAP (open circle ) alone, or with 100 µl of 200 µM protamine and 150 µM RAP together (black-triangle) 2 min prior to injection of 100-µl samples containing 125I-fVIII (15 nM) and vWf (750 nM). In the experiment (black-down-triangle ), 100 units (1 mg) of heparin were administered 2 min after injection of protamine and RAP. In the control experiment (), clearance of 125I-fVIII-vWf complex was studied in the absence of any agent. At the indicated time points, blood samples were taken, and their radioactivity was counted. The percentage of the ligand remaining in circulation was calculated considering radioactivity of 1-min aliquot as 100%. 125I-fVIII clearance was examined in four mice for each of the above conditions. The curves show the best fit of the experimental data to Equation 1 ("Experimental Procedures") describing biphasic exponential clearance of fVIII. The dotted curve represents the best fit for the experiment (black-down-triangle ).


C=C<SUB>1</SUB>e<SUP>−k<SUB>1</SUB>t</SUP>+C<SUB>2</SUB>e<SUP>−k<SUB>2</SUB>t</SUP> (Eq. 1)
where C is the percentage of 125I-fVIII remaining in plasma at a given time; k1 and k2 are the kinetic rate constants corresponding to the fast and slow phases of fVIII clearance; and C1 and C2 are percentages of radioactivity removed during the fast and slow phases of clearance. The values of k1, k2, C1, and C2 constants were derived for each clearance curve by fitting C versus t to the above Equation 1. At the saturating concentration of RAP, the rate of the fast phase of clearance was dramatically reduced (Table II), resulting in prolongation of the half-life of fVIII by 3.5-fold, similar to that reported previously (12). Administration of protamine prolonged the fVIII half-life by 1.6-fold and reduced the rates of both phases of clearance (Table II). This indicates that HSPGs contribute to both RAP-sensitive and RAP-independent pathways of fVIII clearance. Notably, coinjection of RAP and protamine resulted in a greater increase of the fVIII half-life (5.5-fold) than injection of RAP alone (3.5-fold), suggesting that LRP (12) and HSPGs are simultaneously involved in fVIII clearance. To confirm that the effect of protamine on fVIII clearance in vivo was specific, we performed a control experiment in which protamine was administered together with 100 units (1 mg) of heparin. This amount of heparin is sufficient to neutralize 1 mg of protamine by irreversible binding, thus preventing interaction of protamine with HSPGs (51, 52). Administration of heparin abolished the effect of protamine both in the presence of RAP (Fig. 9) and in its absence (data not shown), supporting our assumption that the effect of protamine is due to prevention of fVIII-vWf binding to HSPGs. Thus, the above data suggest that HSPGs participate in fVIII clearance in vivo and are involved in LRP-mediated and LRP-independent catabolic pathways.


                              
View this table:
[in this window]
[in a new window]
 
Table II
Effect of RAP and protamine on the parameters of fVIII clearance from plasma of mice
The values of the kinetic rate constants k1 and k2, corresponding to the fast and slow phases of fVIII clearance, and the percentages of total radioactivity (C1 and C2, respectively) removed during these phases were determined by fitting the clearance data shown in Fig. 9 Equation 1 described under "Results."

FVIII Is Colocalized with HSPGs on the Surface of LRP-expressing Hepatic Cells-- We found previously that injection of 125I-fVIII-vWf complex into mice led to accumulation of most of the radioactivity in liver (12), where LRP is present in high abundance (15). To verify whether HSPGs are involved in the initial fVIII binding to the liver cells, we performed direct visualization of fVIII, HSPGs, and LRP in human hepatic cells HEP G2, expressing both LRP and HSPGs (53). The cells were incubated with fVIII-vWf complex at 4 °C followed by triple label immunofluorescent staining for fVIII, LRP, and HSPGs and microscopy (Fig. 10). For each preparation, the distribution of fVIII, HSPGs, or LRP is shown in red, blue and green images, respectively. For control cells, the individual stainings for fVIII, HSPGs, and LRP are represented by the images a, b, and c, respectively. FVIII was distributed on the cell surface in a grainy pattern, typical for cell surface but not for cytoplasmic staining. The merged image (image d) demonstrates that fVIII colocalized predominantly with HSPGs as the purple areas, resulting from the superimposing of red and blue staining for fVIII and HSPGs, respectively. Colocalization of surface-bound fVIII with LRP was negligible, since large areas in the merged image remained green but not yellow, as would be expected for superimposed red and green images. Consistent with this observation, treatment of the cells with heparinase removing glycosamine residues from HSPGs (image f) led to a dramatic reduction of bound fVIII (image e) and to disappearance of purple areas on the merged image (image h). In contrast, blocking of LRP by RAP (images i, j, k, and l) did not appreciably alter the level of fVIII binding (image i) when compared with the control cells (image a). In the merged image (image l) fVIII remained colocalized with HSPGs, consistent with a negligible role of LRP in the initial surface binding of fVIII-vWf complex. Thus, the microscopy study confirmed that HSPGs are the major receptors responsible for the initial binding of fVIII-vWf complex to the surface of LRP-expressing hepatic cells.



View larger version (59K):
[in this window]
[in a new window]
 
Fig. 10.   Microscopy studies of surface binding of fVIII from its complex with vWf by HEP G2 cells. Control untreated HEP G2 cells (upper panel, images a-d) and the cells treated with heparinase (middle panel, images e-h) or RAP (lower panel, images i-l) were incubated with 10 nM of fVIII-vWf complex for 2 h at 4 °C. This was followed by fixing the cells and triple label staining for fVIII using Texas Red (red images a, e, and i), for HSPGs using AMCA (blue images b, f, and g) and for LRP using FITC (green images c, g, and k) as fluorophores, as described under "Experimental Procedures." Each type of staining was visualized using a selective fluorescent filter block. The merged images (d, h, and l) were obtained by superimposing single-stained images as described under "Experimental Procedures."



    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

In the present study we found that cell surface HSPGs facilitate LRP-mediated catabolism of fVIII from its complex with vWf in cell culture and in vivo. In LRP-expressing cells, the bulk of the initial binding of fVIII-vWf complex occurs via HSPGs, which cooperate with LRP receptor in the consequent internalization of the fVIII molecule. In mice, the simultaneous blocking of HSPGs and LRP led to a significant prolongation of the fVIII half-life compared with fVIII half-lives when HSPGs and LRP were blocked independently.

The interaction of fVIII-vWf complex with HSPGs occurs via the A2 domain of fVIII, which is based on the following findings: (i) the cell surface binding of A2 and fVIII-vWf complex displayed a similar dose dependence and was inhibited by heparinase treatment to the same extent; (ii) the A2 subunit, but not other portions of fVIII or isolated vWf, strongly inhibited the cell surface binding; (iii) the A2 subunit and fVIII-vWf complex bound to the cell surface with similar affinities; (iv) the A2 subunit and fVIII had similar affinities for heparin in a purified system. Although vWf was previously shown to interact with heparin, its contribution to the binding of fVIII-vWf complex to the cells surface is negligible, which follows from the low affinity of vWf for heparin determined in our experiments (Kd = 8.4 µM) and by others (Kd values are 2 (54) and 78 µM (55)). The heparin-binding affinity of vWf in the present study was 300-fold lower than the affinities determined for fVIII and A2 (~28 nM). The interaction of fVIII and its A2 subunit with heparin was specific as demonstrated by a negligible binding of these ligands to chondroitin sulfate, which represents another type of carbohydrates associated with cell surface proteoglycans. This suggests that fVIII-vWf complex selectively binds to cell surface heparan sulfate proteoglycans.

The A2 site involved in the binding to heparin was localized to the region 558-565, based on the ability of the synthetic peptide encompassing this region to inhibit the A2 binding to heparin. Notably, the peptide 484-509 corresponding to the previously localized LRP-binding site (12) did not appreciably inhibit the binding, suggesting that the A2 sites responsible for the binding to LRP and HSPGs are distinct.

Heparin-binding sites of proteins are commonly represented by cationic clusters formed by Arg and Lys residues, which interact with anionic groups (sulfate and carboxyl groups) of glycosaminoglycan chains of the proteoglycans (56). According to the previously published three-dimensional model of the A2 domain (57), there are Lys556, Lys562, Lys570, and Arg571 within the 558-565 region and in the close proximity to it, which are exposed on the A2 surface. We also found another, low affinity heparin-binding site within LCh of fVIII, which precise localization remains to be performed.

Cooperation of HSPGs with LRP in catabolism of fVIII is similar to their role in catabolism of most heparin-binding LRP ligands (19, 27, 31, 41, 42, 58). The proposed role of HSPGs is to concentrate ligands on the cell surface and to facilitate their subsequent internalization by presenting them to LRP (14, 31). This role of HSPGs is consistent with our data, since the affinity of fVIII-vWf complex for HSPGs and heparin (Kd = 15-30 nM) is higher than that for LRP (Kd = 116 nM (12)).

Internalization and degradation of fVIII by LRP-expressing MEF, SMC, and T2 cells could be effectively inhibited by RAP, which confirms the involvement of LRP in fVIII catabolism previously reported by us (12). In LRP-deficient PEA13 cells the level of fVIII degradation was similar to that determined in the previous study (12) and significantly lower (22%) in comparison with LRP-expressing MEF cells. We found that this less effective, LRP-independent degradation by PEA13 cells was strongly inhibited by heparinase treatment, suggesting existence of a different pathway of fVIII catabolism, which involves HSPGs. These findings are consistent with the biphasic character of fVIII clearance in vivo, reflecting the existence of two distinct pathways of fVIII catabolism. The inhibitory effect of protamine on the fast and slow phases of clearance points to involvement of HSPGs in both pathways of fVIII catabolism in vivo. Since only the fast phase of fVIII clearance was RAP-sensitive, we propose that in this phase fVIII bound to cell surface HSPGs undergoes LRP-mediated endocytosis, whereas in the slow phase, also facilitated by HSPGs, fVIII follows LRP-independent pathway. Unlike in cell culture, the simultaneous blocking of HSPGs and LRP by protamine and RAP, respectively, did not completely block the fVIII clearance in mice. This can be explained by either incomplete inhibition of these receptors due to clearance of RAP and protamine or by the existence of another mechanism, which does not involve HSPGs and LRP. It cannot be completely excluded, however, that the inhibitory effect of protamine on fVIII clearance could be due to prevention of fVIII interactions with negatively charged cell surface-associated molecules other than HSPGs.

The proposed role of HSPGs is depicted in Fig. 11, which indicates that catabolism of fVIII from its complex with vWf occurs via initial binding of the complex to HSPGs, followed by both LRP-mediated and LRP-independent endocytosis and degradation of fVIII. The model implies that vWf dissociates prior to fVIII internalization, based on our previous finding that vWf does not follow fVIII in the endocytic pathway (12). Our demonstration that catabolism of the A2 subunit is equivalent to that of fVIII from its complex with vWf suggests that dissociation of the complex is not a rate-limiting step of the catabolic process. The previous finding that the isolated fVIII is catabolized more efficiently than from its complex with vWf (12) can be explained by the presence of the second LRP-binding site within the C2 domain of LCh (23), which is likely to be blocked by interaction with vWf. The overlapping of the C2 domain LRP- and vWf-binding sites (24) was suggested from the inhibitory effect of monoclonal anti-C2 domain antibody ESH4 on fVIII binding to both LRP (23) and vWf.2 The proposed contribution of the LRP-binding site located within the C2 domain to catabolism of fVIII is consistent with a significantly faster clearance of fVIII in vWf-deficient patients (8).



View larger version (28K):
[in this window]
[in a new window]
 
Fig. 11.   Molecular model of catabolism of fVIII from its complex with vWf. Initial binding of fVIII-vWf complex occurs mainly via interaction with HSPGs, followed by either LRP-mediated endocytosis of fVIII occurring via clathrin-coated pits (61) or its LRP-independent endocytosis. Since vWf does not follow fVIII in the endocytic pathway in the cell culture experiments (12), we propose that it dissociates from fVIII prior to entry of the complex into endosomal compartments.

Our finding that the isolated A2 domain of fVIII can also be catabolized by HSPGs- and LRP-mediated mechanisms may reflect the existence of a specific pathway for clearance of activated fVIII. Heterotrimeric fVIIIa (A1/A2/A3-C1-C2) is an unstable molecule due to its rapid but reversible dissociation to A2 and A1/A3-C1-C2 (59, 60). Since the A2 subunit retains a weak fVIIIa-like ability to support Xase and may also reassemble with A1/A3-A3-C1, it is tempting to speculate that clearance of the isolated A2 subunit may have evolved as a mechanism preventing formation of the Xase complex at inappropriate coagulation sites.

In summary, we demonstrated that fVIII catabolism from its complex with vWf involves the initial binding of the complex to cell surface HSPGs due to interaction between polysaccharide portions of HSPGs and the major heparin-binding site of fVIII localized within the A2 domain. The fVIII molecule is subsequently catabolized via LRP-mediated and LRP-independent pathways. Our finding that the simultaneous blocking of LRP and HSPGs receptors dramatically prolonged the lifetime of fVIII in a mouse model supports the physiological role of LRP and HSPGs in fVIII catabolism.


    FOOTNOTES

* This work was supported in part by Scientist Development Grant 9630065N (to E. L. S.) from the American Heart Association and Junior Faculty Award (to E. L. S.) from the American Society of Hematology.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.

|| To whom correspondence should be addressed: American Red Cross, 15601 Crabbs Branch Way, Rockville, MD 20855. Tel.: 301-738-0743; Fax: 301-738-0794.

Published, JBC Papers in Press, January 12, 2001, DOI 10.1074/jbc.M008046200

2 E. L. Saenko, unpublished observations.


    ABBREVIATIONS

The abbreviations used are: fVIII, factor VIII; fVIIIa, activated factor VIII; HCh, heavy chain of factor VIII; LCh, light chain of factor VIII; vWf, von Willebrand factor; HSPGs, heparan sulfate proteoglycans; LRP, low density lipoprotein receptor-related protein; RAP, receptor-associated protein; Fl-FFR-fIXa, fluorescently labeled factor IXa; MEF, mouse embryonic fibroblast cells expressing LRP; PEA 13, mouse embryonic fibroblast cells genetically deficient in LRP; SMC, human smooth muscle cells; T2, human alveolar epithelial cells; HEP G2, human hepatocellular carcinoma cells; SPR, surface plasmon resonance; PC, phosphatidylcholine; PS, phosphatidylserine; DMEM, Dulbecco's modified Eagle's medium; Xase, membrane-bound complex of fVIIIa and factor IXa.


    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES


1. van Dieijen, G., Tans, G., Rosing, J., and Hemker, H. C. (1981) J. Biol. Chem. 256, 3433-3442[Abstract/Free Full Text]
2. Vehar, G. A., Keyt, B., Eaton, D., Rodrigues, H., O'Brien, D. P., Rotblat, F., Opperman, H., Keck, R., Wood, W. I., Harkins, R. N., Tuddenham, E. G. D., Lawn, R. M., and Capon, D. J. (1984) Nature 312, 337-340[Medline] [Order article via Infotrieve]
3. Fay, P. J., Anderson, M. T., Chavin, S. I., and Marder, V. J. (1986) Biochim. Biophys. Acta 871, 268-278[Medline] [Order article via Infotrieve]
4. Wion, K., Kelly, D., Summerfield, J. A., Tuddenham, E. G. D., and Lawn, R. M. (1985) Nature 317, 726-730[Medline] [Order article via Infotrieve]
5. Girma, J.-P., Chopek, M. W., Titani, K., and Davie, E. W. (1986) Biochemistry 25, 3156-3163[Medline] [Order article via Infotrieve]
6. Saenko, E. L., and Scandella, D. (1997) J. Biol. Chem. 272, 18007-18014[Abstract/Free Full Text]
7. Leyte, A., van Schijndel, H. B., Niehrs, C., Huttner, W. B., Verbeet, M. P., Mertens, K., and van Mourik, J. A. (1991) J. Biol. Chem. 266, 740-746[Abstract/Free Full Text]
8. Lethagen, S., Berntorp, E., and Nilsson, I. M. (1992) Ann. Hematol. 65, 253-259[Medline] [Order article via Infotrieve]
9. Morfini, M., Mannucci, P., Tenconi, P. M., Longo, G., Mazzucconi, M. G., Rodeghiero, F., Ciavarela, N., DeRosa, V., and Arter, A. (1993) Thromb. Haemostasis 70, 270-272[Medline] [Order article via Infotrieve]
10. Brinkhous, K. M., Sandberg, H., Garris, J. B., Mattsson, C., Palm, M., and Griggs, T. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 8752-8756[Abstract]
11. Shwarz, H. P., Lenting, P. J., Binder, B., Mihaly, J., Denis, C., Dorner, F., and Turecek, P. L. (2000) Blood 95, 1703-1708[Abstract/Free Full Text]
12. Saenko, E. L., Yakhyaev, A. V., Mikhailenko, I., Strickland, D. K., and Sarafanov, A. G. (1999) J. Biol. Chem. 274, 37685-37692[Abstract/Free Full Text]
13. Neels, J. G., Horn, I. R., Van den Berg, B. M. M., Pannekoek, H., and van Zonneveld, A.-J. (1998) Fibrinol. Proteol. 12, 219-240
14. Strickland, D. K., Kounnas, M. Z., and Argraves, W. S. (1995) FASEB J. 9, 890-898[Abstract/Free Full Text]
15. Moestrup, S. K., Gliemann, J., and Pallesen, G. (1992) Cell Tissue Res. 269, 375-382[Medline] [Order article via Infotrieve]
16. Neels, J. G., van den Berg, B. M., Mertens, K., Pannekoek, H., Zonneveld, A.-J., and Lenting, P. (2000) Blood 96, 3459-3465[Abstract/Free Full Text]
17. Narita, M., Rudolph, A. E., Miletich, J. P., and Schwartz, A. L. (1998) Blood 91, 555-560[Abstract/Free Full Text]
18. Kamikubo, Y., Hamuro, T., Matsuda, J., Kamei, S., Jyu-ri, K., Miyamoto, S., Funatsu, A., and Kato, H. (1996) Thromb. Res. 83, 161-173[CrossRef][Medline] [Order article via Infotrieve]
19. Warshawsky, I., Broze, G. J., Jr., and Schwartz, A. L. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 6664-6668[Abstract]
20. Herz, J., Clouthier, D. E., and Hammer, R. E. (1992) Cell 71, 411-421[Medline] [Order article via Infotrieve]
21. Orth, K., Madison, E. L., Gething, M. J., Sambrook, J. F., and Herz, J. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 7422-7426[Abstract]
22. Williams, S. E., Ashcom, J. D., Argraves, W. S., and Strickland, D. K. (1992) J. Biol. Chem. 267, 9035-9040[Abstract/Free Full Text]
23. Lenting, P., Neels, J. G., van den Berg, B. M., Clijsters, P. F. M., Meijerman, D. W. E., Pannekoek, H., van Mourik, J. A., Mertens, K., and Zonneveld, A.-J. (1999) J. Biol. Chem. 274, 23734-23739[Abstract/Free Full Text]
24. Saenko, E. L., Shima, M., Rajalakshmi, K. J., and Scandella, D. (1994) J. Biol. Chem. 269, 11601-11605[Abstract/Free Full Text]
25. Fijnvandraat, K., Bertorp, E., Ten Cate, J. W., Johnsson, H., Peters, M., Savidge, G., Tengborn, L., Spira, J., and Stahl, C. (1997) Thromb. Haemostasis 77, 298-302[Medline] [Order article via Infotrieve]
26. Over, J., Sixma, J. J., Bruine, M. H., Trieschnigg, M. C., Vlooswijk, R. A., Bieser-Visser, N. H., and Bouma, B. N. (1978) J. Clin. Invest. 62, 223-234[Medline] [Order article via Infotrieve]
27. Chappell, D. A., Fry, G. L., Waknitz, M. A., Muhonen, L. E., Pladet, M. W., Iverius, P. H., and Strickland, D. K. (1993) J. Biol. Chem. 268, 14168-14175[Abstract/Free Full Text]
28. Ji, Z. S., Fazio, S., Lee, Y. L., and Mahley, R. W. (1994) J. Biol. Chem. 269, 2764-2772[Abstract/Free Full Text]
29. Mahley, R. W., and Ji, Z. S. (1999) J. Lipid Res. 40, 1-16[Abstract/Free Full Text]
30. Mikhailenko, I., Kounnas, M. Z., and Strickland, D. K. (1995) J. Biol. Chem. 270, 9543-9549[Abstract/Free Full Text]
31. Knauer, M. F., Crisp, R. J., Kridel, S. J., and Knauer, D. J. (1999) J. Biol. Chem. 274, 275-281[Abstract/Free Full Text]
32. Warshawsky, I., Herz, J., Broze, G. J., Jr., and Schwartz, A. L. (1996) J. Biol. Chem. 271, 25873-25879[Abstract/Free Full Text]
33. Narita, M., Bu, G., Herz, J., and Schwartz, A. L. (1995) J. Clin. Invest. 96, 1164-1168[Medline] [Order article via Infotrieve]
34. Crisp, R. J., Knauer, D. J., and Knauer, M. F. (2000) J. Biol. Chem. 275, 19628-19637[Abstract/Free Full Text]
35. Barrow, R. T., Healey, J. F., and Lollar, P. (1994) J. Biol. Chem. 269, 593-598[Abstract/Free Full Text]
36. Bayer, E. A., Ben-Hur, H., and Wilchek, M. (1988) Anal. Biochem. 170, 271-281[Medline] [Order article via Infotrieve]
37. Barenholz, Y., Gibbes, D., Litman, B. J., Goll, J., Thompson, T. E., and Carlson, F. D. (1977) Biochemistry 16, 2806-2810[Medline] [Order article via Infotrieve]
38. Saenko, E. L., Shima, M., Gilbert, G. E., and Scandella, D. (1996) J. Biol. Chem. 271, 27424-27431[Abstract/Free Full Text]
39. Lollar, P., Fay, P. J., and Fass, D. N. (1993) Methods Enzymol. 222, 128-143[Medline] [Order article via Infotrieve]
40. Willnow, T. E., and Herz, J. (1994) J. Cell Sci. 107, 719-726[Abstract/Free Full Text]
41. Kounnas, M. Z., Chappell, D. A., Wong, H., Argraves, W. S., and Strickland, D. K. (1995) J. Biol. Chem. 270, 9307-9312[Abstract/Free Full Text]
42. Knauer, M. F., Kridel, S. J., Hawley, S. B., and Knauer, D. J. (1997) J. Biol. Chem. 272, 29039-29045[Abstract/Free Full Text]
43. Chappell, D. A., Fry, G. L., Waknitz, M. A., Iverius, P. H., Williams, S. E., and Strickland, D. K. (1992) J. Biol. Chem. 267, 25764-25767[Abstract/Free Full Text]
44. Fay, P. J., and Koshibu, K. (1998) J. Biol. Chem. 273, 19049-19054[Abstract/Free Full Text]
45. Fay, P. J., and Scandella, D. (1999) J. Biol. Chem. 274, 29826-29830[Abstract/Free Full Text]
46. Connelly, S., Gardner, J. M., Lyons, R. M., McClelland, A., and Kaleko, M. (1996) Blood 87, 4671-4677[Abstract/Free Full Text]
47. Wells, M. J., and Blajchman, M. A. (1998) J. Biol. Chem. 273, 23440-23447[Abstract/Free Full Text]
48. Oakley, C. L., and Warrack, G. H. (1940) J. Pathol. Bacteriol. 50, 372-377
49. Barrow, R. T., Parker, E. T., Krishnaswamy, L., and Lollar, P. (1994) J. Biol. Chem. 269, 26796-26800[Abstract/Free Full Text]
50. Fay, P. J., Beattie, T., Huggins, C. F., and Regan, L. M. (1994) J. Biol. Chem. 269, 20522-20527[Abstract/Free Full Text]
51. Narita, M., Bu, G., Olins, G. M., Higuchi, D. A., Herz, J., Broze, G. J., Jr., and Schwartz, A. L. (1995) J. Biol. Chem. 270, 24800-24804[Abstract/Free Full Text]
52. Harenberg, J., Siegele, M., Dempfle, C.-E., Stehle, G., and Heene, D. L. (1993) Thromb. Haemostasis 70, 942-945[Medline] [Order article via Infotrieve]
53. Butzow, R., Fukushima, D., Twardzik, D. R., and Ruoslahti, E. (1993) J. Cell Biol. 122, 721-727[Abstract]
54. Poletti, L. F., Bird, K. E., Marques, D., Harris, R. B., Suda, Y., and Sobel, M. (1997) Arterioscler. Thromb. Vasc. Biol. 17, 925-931[Abstract/Free Full Text]
55. Maruch, D., Ajzenberg, N., Denis, C., Legendre, P., Lormeau, J.-C., and Meyer, D. (1994) Thromb. Haemostasis 71, 141-146[Medline] [Order article via Infotrieve]
56. Mann, D. M., Romm, E., and Migliorini, M. (1994) J. Biol. Chem. 269, 23661-23667[Abstract/Free Full Text]
57. Pemberton, S., Lindley, P., Zaitsev, V., Card, G., Tuddenham, E. G. D., and Kemball-Cook, G. (1997) Blood 89, 2413-2421[Abstract/Free Full Text]
58. Mikhailenko, I., Krylov, D., Argraves, K. M., Roberts, D. D., Liau, G., and Strickland, D. K. (1997) J. Biol. Chem. 272, 6784-6791[Abstract/Free Full Text]
59. Fay, P. J., Haidaris, P. J., and Smudzin, T. M. (1991) J. Biol. Chem. 266, 8957-8962[Abstract/Free Full Text]
60. Fay, P. J., and Smudzin, T. M. (1992) J. Biol. Chem. 267, 13246-13250[Abstract/Free Full Text]
61. Chen, W. J., Goldstein, J. L., and Brown, M. S. (1990) J. Biol. Chem. 265, 3116-3123[Abstract/Free Full Text]


Copyright © 2001 by The American Society for Biochemistry and Molecular Biology, Inc.