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J Biol Chem, Vol. 274, Issue 34, 23734-23739, August 20, 1999
§,
,,,, and
From the Departments of Plasma Protein Technology and
** Blood Coagulation, CLB, 1066 CX Amsterdam The Netherlands and the
¶ Department of Biochemistry, Academic Medical Center/University
of Amsterdam, 1105 AZ Amsterdam, The Netherlands
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ABSTRACT |
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 TOP
 ABSTRACT
 INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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In the present study, the interaction between the
endocytic receptor low density lipoprotein receptor-related protein
(LRP) and coagulation factor VIII (FVIII) was investigated. Using
purified components, FVIII was found to bind to LRP in a reversible and dose-dependent manner (Kd Low density lipoprotein receptor-related protein
(LRP),1 also known as
Coagulation factor VIII (FVIII) is the precursor of its activated
derivative, which stimulates factor IXa-mediated activation of factor X
(for recent reviews, see Refs. 13 and 14). The fact that deficiency or
dysfunction of FVIII is associated with severe bleeding tendencies
demonstrates that this cofactor is indispensable for appropriate
hemostasis. FVIII comprises a domain structure (A1-A2-B-A3-C1-C2) (15)
and circulates in plasma predominantly as a heterodimeric protein
consisting of a metal ion-linked light and heavy chain (16, 17). The
heavy chain (90-220 kDa) contains the A1-A2-B domains and is
heterogenous as a result of limited proteolysis within the B domain.
The light chain (80 kDa) consists of the A3-C1-C2 domains. The amino-
and carboxyl-terminal ends of FVIII light chain together comprise the
binding site for von Willebrand factor (vWF) (18, 19), the
physiological carrier protein of FVIII (20). The FVIII precursor is
converted into its activated derivative upon limited proteolysis by
thrombin (21, 22). Activated FVIII consists of the A2 domain, which is
noncovalently associated with the metal-ion linked A1/A3-C1-C2 dimer,
whereas the B domain and the amino-terminal part of the A3 domain have
been removed (23). Due to the release of the amino-terminal part, high
affinity binding to vWF is lost (18). vWF prevents the FVIII precursor
from binding to components of the factor X-activating complex (14, 24,
25). Furthermore, the half-life of FVIII is considerably reduced in the
absence of vWF (26, 27), indicating that vWF prevents FVIII from
premature clearance. However, the mechanism by which FVIII is removed
from the circulation has remained unidentified.
In the present study, we investigated the possibility that FVIII is
recognized by the multifunctional receptor LRP. To this end, the
interaction between LRP and FVIII or its constituent subunits has been
addressed using purified components. In addition, cellular degradation
of FVIII has been studied. It is demonstrated that LRP recognizes FVIII
as a ligand, and that binding involves the light chain of FVIII.
Furthermore, both LRP-mediated binding and degradation of FVIII are
down-regulated by vWF. Our data are in support of a mechanism in which
LRP contributes to binding and internalization of FVIII.
Materials--
Glutathione-Sepharose 4B and protein A-Sepharose
CL-4B were from Amersham Pharmacia Biotech. Microtiter plates were from
Dynatech (Plockingen, Germany). Cell culture plates, fetal calf serum, penicillin, and streptomycin were from Life Technologies, Inc. Dulbecco's modified Eagle's medium:F12 (DMEM:F12) medium was from BioWittaker (Verviers, Belgium). The BIAcoreTM2000
biosensor system and reagents (amine-coupling kit and CM5 sensor chips)
were from Biacore AB (Uppsala, Sweden).
Proteins--
FVIII light chain, thrombin-cleaved FVIII light
chain, and FVIII heavy chain were prepared as described previously (25, 28). The integrity of the isolated subunits was assessed in reconstitution experiments as described previously (28). As expected,
isolated subunits could effectively be reassembled into biologically
active heterodimers (data not shown). Plasma-derived FVIII heterodimer
was isolated as described previously (25). FVIII was labeled with
Na125I (Amersham Pharmacia Biotech) using the IODO-GEN
method (Pierce) as described previously (29), except that FVIII was
stored in 150 mM NaCl, 2 mM CaCl2,
0.005% (v/v) Tween 20, and 20 mM Hepes (pH 7.4) at
Protein Concentrations--
Protein was quantified by the method
of Bradford (32), using human albumin as a standard. FVIII activity was
assayed using Coatest FVIII (Chromogenix AB, Mölndal, Sweden).
Pooled plasma, which was calibrated against World Health Organization
standard 91-666, was used as a standard. The amount of FVIII present in 1 ml of human plasma (1 unit/ml) was assumed to correspond to 0.4 nM (28).
Surface Plasmon Resonance Analysis--
Binding studies were
performed using a BIAcoreTM2000 biosensor system, based on
surface plasmon resonance (SPR) technology. SPR analysis was performed
essentially as described previously (33). LRP was immobilized onto a
CM5-sensor chip, using the amine coupling kit as prescribed by the
supplier, at indicated densities. A control channel was routinely
activated and blocked in the absence of protein. Binding to coated
channels was corrected for binding to noncoated channels (less than 5%
of binding to coated channels). SPR analysis was assessed in 150 mM NaCl, 2 mM CaCl2, 0.005% (v/v)
Tween 20, and 20 mM Hepes (pH 7.4) at 25 °C with a flow
rate of 5 µl/min or 20 µl/min, where appropriate. Regeneration of
the sensor chip surface was performed by incubating with 100 mM H3PO4 for 2 min at a flow rate
of 5 µl/min.
Data Analysis--
For analysis of the association and
dissociation curves in the obtained sensorgrams, BIAevaluation software
(Biacore AB) was used. Interaction constants were determined by
performing nonlinear fitting of data corrected for bulk refractive
index changes according to a two-site model, using equations described
previously (33). Data fitting to a one-site model proved inappropriate,
as judged from residual plots and statistical parameters (data not shown).
Competition Experiments--
Purified LRP (125 fmol/well) was
adsorbed onto microtiter wells in 50 mM NaHCO3
(pH 9.5) in a volume of 50 µl for 16 h at 4 °C. LRP-coated
and noncoated wells were blocked with 1% (w/v) gelatin in 150 mM NaCl, 2 mM CaCl2, 0.01% (v/v)
Tween 20, and 20 mM Hepes (pH 7.4) in a volume of 100 µl
for 2 h at 37 °C. After washing, FVIII (40 nM) was
added in the same buffer to LRP-coated and noncoated wells in the
presence (0-1 µM) of GST-RAP in a volume of 50 µl and
incubated for 3 h at 37 °C. Bound FVIII was quantified by
incubating for 15 min at 37 °C with peroxidase-labeled antibody CLB-CAg 117.
Cellular Degradation Experiments--
Cellular degradation of
FVIII was examined essentially as described elsewhere (34). CHO cells
(ATCC CCL-61) were grown to 80-95% confluence in 24-well plates in
DMEM:F12 medium supplemented with 10% (v/v) fetal calf serum, 100 units/ml penicillin, and 100 µg/ml streptomycin. Before incubation,
cells were washed extensively with DMEM:F12 medium.
125I-labeled FVIII (20 nM) was then added in a
volume of 200 µl in DMEM:F12 medium containing 1% (w/v) bovine
albumin and 5 mM CaCl2. In some experiments,
125I-labeled FVIII was added in the presence of vWF (500 nM), GST-RAP (1 µM), or protein A-Sepharose
purified polyclonal antibodies directed against LRP (0.9 mg/ml). After
a 35-min incubation at 37 °C, cells were washed three times with 500 µl of DMEM:F12 to remove nonbound material. Subsequently, incubation
was allowed to proceed for another 4.5 h at 37 °C in a volume
of 200 µl of DMEM:F12 medium containing 1% (w/v) bovine albumin and
5 mM CaCl2, in the presence of freshly added
competitor where appropriate. Then, 100 µl samples were drawn to
determine the amount of degraded material. Degraded material is defined
as radioactivity that is soluble in 10% trichloroacetic acid (35). In
all experiments, a control was included in which the amount of
degradation was assessed in the absence of cells.
Ligand Blotting--
Ligand blotting experiments were performed
essentially as described elsewhere (35). Briefly, 1 µg of purified
LRP was subjected to SDS-polyacrylamide gel electrophoresis on a 5%
gel under nonreducing conditions and blotted onto nitrocellulose
filters. Blots were blocked with 1% (w/v) non-fat milk in 100 mM NaCl, 0.01% (v/v) Tween 20, and 20 mM Hepes
(pH 7.4). The blots were subsequently incubated with FVIII light chain
(50 nM) in the absence or presence of GST-RAP (125 nM) in the same buffer containing 5 mM
CaCl2 for 16 h at room temperature. After washing the
blots, bound FVIII light chain was detected using the
peroxidase-labeled anti-FVIII light chain-directed antibody CLB-CAg 69. Binding was visualized using 3,3-diaminobenzidine tablets (Ken-En-Tec,
Copenhagen, Denmark).
FVIII Binding to Immobilized LRP--
The interaction between LRP
and FVIII was first investigated by SPR analysis using purified
components. As shown in Fig. 1, an
increase in response was observed as FVIII (80 nM) was
passed over immobilized LRP (8 and 25 fmol/mm2),
demonstrating that FVIII associates with LRP. Binding appeared to be
dose-dependent in that the highest response was detected in
case of the highest density of LRP (Fig. 1). Upon replacement of FVIII
solution with buffer, the response started to decline gradually,
indicating that FVIII dissociates from immobilized LRP. The interaction
between LRP and FVIII was studied in more detail by assessment of the
association and dissociation rate constants kon
and koff. The results are summarized in Table
I. Binding of FVIII heterodimer to LRP
could be described using a two-site model. The affinity constants
(Kd) derived from kon and
koff values are 59 and 65 nM,
respectively. These data indicate that FVIII is able to bind to LRP
with moderate affinity in a reversible and dose-dependent
manner.
Effect of GST-RAP and vWF on the FVIII-LRP Interaction--
The
interaction between FVIII and LRP was further analyzed in competition
experiments using the FVIII carrier protein vWF and the LRP antagonist
RAP. With regard to RAP, its effect was tested in an immunosorbent
assay by incubating immobilized LRP (125 fmol/well) with mixtures of
FVIII (40 nM) and various concentrations of GST-RAP (0-1
µM). Residual FVIII binding was subsequently determined using an anti-FVIII-directed antibody. The amount of FVIII bound decreased when concentrations of GST-RAP were increased (Fig. 2A). Half maximum binding was
found at a concentration of approximately 1 nM GST-RAP,
showing that RAP efficiently inhibits the binding of FVIII to LRP. The
effect of vWF on the interaction between LRP and FVIII was studied by
SPR analysis. Whereas FVIII (40 nM) bound efficiently to
LRP (16 fmol/mm2) in the absence of vWF, association with
LRP was inhibited dose-dependently in the presence of vWF
(10-500 nM) (Fig. 2B). The presence of a
12-fold excess of vWF resulted in over 90% inhibition, indicating that
vWF interferes with complex formation between FVIII and LRP. These data
demonstrate that the interaction between FVIII and LRP may be inhibited
at the level of LRP using RAP or at the level of FVIII using vWF.
Cellular Degradation of FVIII--
To address the contribution of
LRP to the transport of FVIII to the endosomal degradation pathway,
cellular degradation of FVIII was examined in experiments using CHO
cells, which express LRP constitutively (6). It appeared that
125I-labeled FVIII was rapidly degraded by CHO cells ( Binding of FVIII Subunits to LRP--
To identify FVIII regions
involved in binding of LRP, we first examined the interaction of LRP
with the isolated heavy and light chain of FVIII. Using 100 nM FVIII heavy chain, no association of this subunit to LRP
(25 fmol/mm2) could be detected (Fig.
4A). In contrast, in the
presence of FVIII light chain (100 nM), a clear increase in
response was found (Fig. 4A), indicating that FVIII light
chain displays binding to LRP. Binding of FVIII light chain to LRP was
further investigated in ligand blotting experiments. When
nitrocellulose filters containing purified LRP (1 µg) were incubated
with FVIII light chain (50 nM), a clear band could be
visualized (Fig. 4B, lane I), whereas only a faint band was observed when incubated in the presence of FVIII
light chain (50 nM) and RAP (125 nM) (Fig.
4B, lane II). Thus, these data
strongly suggest that FVIII light chain comprises a site that is
recognized by LRP.
Effect of Thrombin Cleavage on FVIII Light Chain Binding to
LRP--
Because both vWF and LRP bind to FVIII light chain (18, Fig.
4), we tested the possibility that LRP and vWF share similar sites
within this part of the FVIII molecule. FVIII comprises two sites that
are involved in vWF binding, one of which is located between residues
1649 and 1689 at the amino-terminal part of the light chain (18, 36).
Thrombin-cleaved FVIII light chain, which lacks this particular
sequence, was therefore compared with intact light chain for binding to
LRP by SPR analysis to reveal the kinetic parameters
kon and koff. As for
FVIII heterodimer, binding of both intact and thrombin-cleaved light
chain to LRP could appropriately be described using a two-site model.
Similar kon and koff
values were obtained for both intact and thrombin-cleaved FVIII light
chain, indicating that these proteins are similar in their interaction
with LRP. Apparently, binding to LRP is independent of the
amino-terminal part of FVIII light chain.
Interaction between LRP and the FVIII C2 Domain--
Apart from
its amino-terminal part, the carboxyl-terminal C2 domain of FVIII light
chain also comprises a vWF binding site (19). Because vWF binding is
inhibited by the C2 domain-directed antibody ESH4, the effect of this
antibody on LRP binding was tested. As shown in Fig.
5A, ESH4 interfered with FVIII
light chain binding to LRP. Inhibition appeared to be specific because ESH4 was unable to affect binding of tissue-type plasminogen
activator/plasminogen activator inhibitor-1 complexes to LRP (data not
shown). Moreover, other FVIII light chain directed antibodies (CLB-CAg
A and CLB-CAg 69) were unable to interfere with LRP binding (data not
shown). Thus, these data suggest that the FVIII C2 domain contributes to the interaction with LRP. This was further investigated using recombinant C2 domain. However, even at high concentrations of this
17.5-kDa fragment (500 nM), only a modest association with LRP was observed (Fig. 5B, line I).
The conformation of the C2 domain may be affected by residues elsewhere
in FVIII light chain or by the C2 domain-directed antibody ESH8 (37).
Binding of the C2 domain to LRP was therefore addressed in the presence
of this antibody. When complexes of C2 domain and antibody ESH8 were applied to LRP, a pronounced, dose-dependent increase in
response could be observed (Fig. 5B, lines
II-IV), indicating that ESH8 promotes binding of the
isolated C2 domain to LRP. Binding was dependent on exposure of the LRP
binding site in the C2 domain because C2 domain-ESH8 complexes or C2
domain alone did not associate to LRP in the presence of antibody ESH4
(Fig. 5B, lines V and VI).
Collectively, these data strongly suggest that a LRP binding site is
present within the C2 domain of FVIII light chain.
The surface of cells comprises numerous receptors that contribute
to the binding and internalization of plasma proteins. Among these
receptors is LRP, a multifunctional, endocytic receptor that is
involved in the transport of a wide spectrum of ligands from the cell
surface to the endosomal degradation pathway. In the present study,
evidence is provided that LRP recognizes coagulation procofactor FVIII
as a ligand. First, in a system using purified components, FVIII proved
to bind to LRP in a manner that is reversible and
dose-dependent (Fig. 1). Furthermore, binding could be
inhibited efficiently in the presence of the FVIII carrier protein vWF
or the LRP antagonist RAP (Fig. 2). Finally, both RAP- and
anti-LRP-directed antibodies interfered with cellular degradation of
125I-labeled FVIII (Fig. 3). It is of interest to note that
inhibition of LRP does not fully prevent FVIII degradation. Whether or
not residual degradation involves a receptor-mediated process is
currently under investigation. Irrespective thereof, our data indicate
that the transport of FVIII from the cellular surface to the
intracellular degradation pathway involves LRP. Because FVIII is
structurally and functionally unrelated to the ligands of LRP that have
been described thus far, it therefore provides a novel member of the already extensive range of established ligands for LRP.
The affinity by which FVIII heterodimer binds to LRP was found to be
approximately 60 nM (Table I). This is in the same range as
reported for some of the other LRP ligands, such as hepatic lipase (52 nM) (38), It has been reported that the A2 domain isolated from
thrombin-activated FVIII has the potential to associate with LRP (41). Our observation that FVIII heavy chain does not associate with LRP may
result from a different experimental approach. Alternatively, it cannot
be excluded that the LRP binding site within the FVIII A2 domain is
exposed in a suboptimal manner when this domain is linked to the A1 and
B domains. This opens the possibility that the binding site for LRP
within the A2 domain requires proteolysis of the FVIII heavy chain by
thrombin for its exposure.
A positive identification of the LRP binding site on the FVIII light
chain was achieved using the monoclonal antibody ESH4 (Fig. 5), which
has previously been described to be directed against the FVIII C2
domain (42). This suggests that the C2 domain contributes to the
interaction with LRP. Indeed, purified recombinant C2 domain displayed
modest binding to LRP (Fig. 5B). Surprisingly, the binding of C2 domain to LRP was markedly increased in the presence of antibody
ESH8 (Fig. 5B), in a manner that was more pronounced than that observed
for other antibodies (data not shown). It has been well established
that antibody ESH8 is able to change the conformation of the C2 domain
in thrombin-cleaved FVIII light chain, resulting in altered affinities
for vWF and phospholipids (37, 43). It seems conceivable therefore that
this antibody provokes a similar event in the isolated C2 domain, which
then results in a more optimal exposure of the LRP binding site. The presence of a binding site for LRP within the C2 domain may explain the
inhibitory effect of vWF (Fig. 2B), which is known to bind to the C2 domain of FVIII (19). However, whether vWF and LRP share a
common binding site within the C2 domain or whether vWF interferes with
binding by sterical hindrance remains to be determined.
In plasma, FVIII is in a dynamic equilibrium with vWF in which
approximately 95% of the FVIII molecules have been calculated to be in
complex with vWF (44). In complex with vWF, cellular uptake and
degradation of FVIII is almost fully suppressed (Fig. 3), indicating
that the contribution of LRP to the cellular uptake of FVIII-vWF
complexes in vivo is limited. However, in the absence of
vWF, FVIII is degraded efficiently in a process that involves LRP (Fig.
3). In this view, our findings may provide an explanation for the
beneficial effect of vWF that has been reported with regard to the
expression of recombinant FVIII in CHO cells (17, 45). vWF may well
contribute to the accumulation of FVIII in medium by interfering with
LRP-mediated uptake of FVIII. Our findings may also be of relevance to
the in vivo survival of FVIII in the absence of vWF. The
physiological significance of complex formation between FVIII and vWF
is particularly apparent in patients having von Willebrand disease type
3, who have no detectable vWF protein. Not only do these patients have
a secondary deficiency of FVIII, but they also have a considerably
reduced half-life of intravenously administered FVIII (26, 27). It is
tempting to speculate that the decreased levels of FVIII in these
patients are associated with increased binding and internalization of
FVIII by LRP due to the absence of vWF.
60 nM). The interaction appeared to be specific because the
LRP antagonist receptor-associated protein readily inhibited binding of
FVIII to LRP (IC50 1 nM). In addition, a
12-fold molar excess of the physiological carrier of FVIII,
i.e. von Willebrand factor (vWF), reduced the binding of
FVIII to LRP by over 90%. Cellular degradation of
125I-labeled FVIII by LRP-expressing cells ( 8 fmol/105 cells after a 4.5-h incubation) was reduced by
approximately 70% in the presence of receptor-associated protein.
LRP-directed antibodies inhibited degradation to a similar extent,
indicating that LRP indeed contributes to binding and transport of
FVIII to the intracellular degradation pathway. Degradation of FVIII was completely inhibited by vWF. Because vWF binding by FVIII involves
its light chain, LRP binding to this subunit was studied. In ligand
blotting experiments, binding of FVIII light chain to LRP could be
visualized. More detailed analysis revealed that FVIII light chain
interacts with LRP with moderate affinity (kon 5 × 104 M
1
s1; koff 2.5 × 103 s1; Kd 50 nM). Furthermore, experiments using recombinant FVIII C2
domain showed that this domain contributes to the interaction with LRP.
In contrast, no association of FVIII heavy chain to LRP could be
detected under the same experimental conditions. Collectively, our data
demonstrate that in vitro LRP is able to bind FVIII at the
cell surface and to mediate its transport to the intracellular
degradation pathway. FVIII-LRP interaction involves the FVIII light
chain, and FVIII-vWF complex formation plays a regulatory role in LRP
binding. Our findings may explain the beneficial effect of vWF on the
in vivo survival of FVIII.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
2-macroglobulin receptor, is a member of the low density lipoprotein
receptor family of endocytic receptors (for a review, see Refs. 1 and
2). It consists of a heavy chain and a light chain, which are
associated in a noncovalent manner. The 85-kDa light chain comprises
the transmembrane and cytoplasmic domains, whereas the ligand binding
regions are located within the 515-kDa heavy chain (3). LRP is
abundantly present in various tissues such as the liver, placenta,
lung, and brain (4) and is expressed in an array of cell types:
parenchymal cells, neurons and astrocytes, Leydig cells, smooth muscle
cells, monocytes, and fibroblasts (4). Commonly used cell lines such as
monkey kidney COS cells and Chinese hamster ovary (CHO) cells also
express LRP (5, 6). The function of LRP is to mediate the binding and
transport of ligands from the cell surface to the endosomal degradation pathway (1, 2). Binding and internalization of ligands is antagonized
by a 39-kDa chaperone protein designated receptor-associated protein
(RAP) (7, 8). Currently, a wide spectrum of structurally and
functionally unrelated ligands involved in a variety of processes such
as lipoprotein metabolism, cell growth and migration, and neuronal
regeneration (1, 2) has been identified. Furthermore, LRP seems to be
linked to the process of blood coagulation. This is apparent from the
observations that LRP recognizes thrombin/antithrombin and factor
Xa/2-macroglobulin complexes and the Kunitz-type inhibitor tissue
factor pathway inhibitor (9-11). In addition, LRP contributes to
down-regulation of tissue factor expression at the surface of monocytes
(12).
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
20 °C. Specific radioactivity was 4.2 (± 0.7) × 103 cpm/fmol FVIII (mean ± range; n = 2). Recombinant FVIII C2 domain (residues 2172-2332) was obtained
using the baculovirus expression system as described previously (30)
and purified by immunoaffinity chromatography as described for FVIII
light chain (25). Purified recombinant wild-type vWF was kindly
provided by Prof. H. P. Schwarz (Baxter-Immuno, Vienna, Austria).
Purified LRP (31) and serum containing polyclonal antibodies against
LRP were a generous gift from Dr. S. K. Moestrup (University of
Aarhus, Aarhus, Denmark). Total IgG was purified from the serum using
protein A-Sepharose CL-4B as recommended by the manufacturer. A plasmid
encoding glutathione S-transferase fused to RAP (GST-RAP) was kindly
provided by Dr. J. Kuiper (Leiden University, Leiden, The Netherlands)
and used for expression of GST-RAP in Escherichia coli
DH5 as described previously (7). GST-RAP was purified using
glutathione-Sepharose 4B as recommended by the manufacturer. Because
the GST tag does not interfere with the binding properties of RAP (7),
GST-RAP was used throughout the present study. Purified anti-FVIII
antibodies CLB-CAg 69, CLB-CAg 117, and CLB-CAg A have been described
previously (25). Anti-FVIII antibodies ESH4 (interferes with vWF
binding) and ESH8 (promotes vWF binding to thrombin-cleaved FVIII) were obtained from American Diagnostica. Human albumin was from the division
of products of CLB (Amsterdam, The Netherlands). Bovine albumin
(fraction V) was from Merck.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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Fig. 1.
Binding of FVIII to immobilized LRP. LRP
immobilized at a CM5 sensor chip at 8 (I) and 25 fmol/mm2 (II) was incubated with FVIII (80 nM) in 150 mM NaCl, 2 mM
CaCl2, 0.005% (v/v) Tween 20, and 20 mM HEPES
(pH 7.4) at a flow of 5 µl/min for 2 min at 25 °C. Ligand solution
was subsequently replaced with buffer to initiate dissociation.
Response is indicated in Resonance Units (RU) and is
corrected for nonspecific binding, which was less than 5% relative to
binding to LRP-coated channels.
Kinetic parameters for the binding of FVIII or its derivatives to LRP
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Fig. 2.
Effect of RAP and vWF on FVIII binding to
immobilized LRP. A, FVIII (40 nM) was
incubated with immobilized LRP (125 fmol/well) in a volume of 50 µl
in 150 mM NaCl, 2 mM CaCl2, 0.01%
(v/v) Tween 20, 1% (w/v) gelatin, and 20 mM Hepes (pH 7.4)
in the presence of various concentrations of GST-RAP (0-1
µM) for 3 h at 37 °C. After washing with the same
buffer, bound FVIII was quantified by incubation with
peroxidase-labeled anti-FVIII antibody CLB-CAg 117 for 15 min at room
temperature. Binding is expressed as the percentage of binding in the
absence of GST-RAP and is corrected for nonspecific binding (5-10%
relative to binding to LRP-coated wells). Data represent the mean ± S.D. of three experiments. B, binding of FVIII (40 nM) to immobilized LRP (16 fmol/mm2) was
examined as described in the legend of Fig. 1. Binding was assessed in
the absence of vWF (I) or in the presence of 10 (II), 50 (III), or 500 nM
(IV) vWF. Line V represents the sensorgram
obtained for vWF (500 nM) in the absence of FVIII. The
concentration of vWF refers to the concentration of vWF monomers.
Complexes were allowed to form for 30 min before SPR analysis.
8 fmol/105 cells after 4.5 h), and degradation did not
occur in the presence of vWF (Fig. 3).
The addition of GST-RAP (1 µM) inhibited degradation of
125I-labeled FVIII by approximately 65% (Fig. 3).
Moreover, a similar extent of inhibition was observed using polyclonal
antibodies directed against LRP (Fig. 3). This demonstrates that LRP
contributes to the cellular uptake and subsequent degradation of
FVIII.
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Fig. 3.
Cellular degradation of FVIII. CHO cells
were incubated with 125I-labeled FVIII (20 nM)
in the absence or presence of GST-RAP (1 µM), anti-LRP
antibodies (0.9 mg/ml), or vWF (500 nM) for 35 min at
37 °C. After washing, bound material was incubated for an additional
4.5-h period, and degradation of FVIII was determined as described
under "Experimental Procedures." Degradation of FVIII in the
absence of inhibitors is referred to as 100% and corresponds to 8.2 fmol/105 cells after 4.5 h. Data represent the
mean ± S.E. of three experiments.
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Fig. 4.
Binding of FVIII subunits to LRP.
A, binding of FVIII heavy (I) or light chain
(II) to immobilized LRP (25 fmol/mm2) was
examined as described in the legend of Fig. 1. The sensorgrams obtained
using 100 nM of each subunit are shown. B,
purified LRP (1 µg) was subjected to a 5% SDS-polyacrylamide gel
electrophoresis gel under nonreducing conditions and transferred to
nitrocellulose. Filters were then preincubated with 1% (w/v) non-fat
milk powder in 100 mM NaCl, 0.01% (v/v) Tween 20, and 20 mM Hepes (pH 7.4) before incubation with FVIII light chain
(50 nM) in the absence (lane I) or
presence (lane II) of GST-RAP (125 nM) in the same buffer containing 5 mM
CaCl2 for 16 h at room temperature. Bound FVIII light
chain was detected using the peroxidase-labeled anti-FVIII light
chain-directed antibody CLB-CAg 69 and 3,3-diaminobenzidine. The
mobility of molecular mass markers is indicated at the
left.
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[in a new window]
Fig. 5.
Binding of FVIII or its C2 domain to LRP in
the presence of anti-FVIII C2 domain antibodies. A,
immobilized LRP (16 fmol/mm2) was incubated with FVIII
light chain (150 nM) in the presence or absence of antibody
ESH4 as described in the legend of Fig. 1. The maximal response
(RU), corrected for nonspecific binding (less than 5%), is
shown at the indicated antibody concentrations. B, LRP,
immobilized at a CM5 sensor chip at 16 fmol/mm2 was
incubated with the C2 domain (500 nM; line
I) or with complexes of the C2 domain with antibody ESH8.
Complexes consisted of 100 nM C2 domain (line
II), 200 nM C2 domain (line
III), or 400 nM C2 domain (line
IV) with 500 nM ESH8. Similarly, complexes of C2
domain (400 nM) with ESH4 (500 nM) and
complexes of the C2 domain (400 nM) with both antibodies
(500 nM each) were incubated with LRP (lines
V and VI, respectively). Complexes were allowed
to form for 45 min before SPR analysis.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-amyloid precursor protein (80 nM)
(39), two-chain urokinase (60 nM) (40), and plasminogen
activator inhibitor-1 (35 nM) (33). The data obtained for
FVIII binding to LRP are in agreement with a two-site binding model
(Table I), indicating that multiple regions contribute to the
interaction with LRP. FVIII light chain proved similar to the FVIII
heterodimer in that LRP binding involves two classes of binding sites
(referred to in Table I as 1 and 2). Furthermore, both proteins display similar affinity with regard to the class 1 binding site (Table I).
Therefore, it seems conceivable that FVIII light chain serves an
important role in the interaction between FVIII and LRP. It is
noteworthy that the class 1 association and dissociation rate constants
for FVIII heterodimer differ from that for FVIII light chain by 25-fold
(Table I), suggesting that exposure of the LRP binding site in FVIII
light chain is distinct from that in the FVIII heterodimer. The same
may be true for the class 2 binding site because its affinity for LRP
is 2-3-fold lower in FVIII light chain than in FVIII heterodimer. One
explanation for this observation may be that the exposure of LRP
binding sites within FVIII light chain depends on the presence of FVIII
heavy chain. A similar mechanism has been reported previously for the
interaction between FVIII light chain and vWF. The affinity for vWF
increases 10-fold when FVIII light chain is associated with FVIII heavy
chain (19).
| |
ACKNOWLEDGEMENTS |
|---|
We thank Dr. J. Voorberg and E. A. M. Turenhout for preparation of medium containing the recombinant C2 domain and Dr. J. A. Kolkman for critical reading of the manuscript.
| |
FOOTNOTES |
|---|
* 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: Dept. of Plasma Protein Technology, CLB, Plesmanlaan 125, 1066 CX Amsterdam, The Netherlands. Tel.: 31-20-5123120; Fax: 31-20-5123680; E-mail: P_Lenting@clb.nl.
Supported by a the Netherlands Organization for Scientific
Research Grant 902-26-175.
| |
ABBREVIATIONS |
|---|
The abbreviations used are: LRP, low density lipoprotein receptor-related protein; CHO, Chinese hamster ovary; DMEM:F12, Dulbecco's modified Eagle's medium:F12; FVIII, factor VIII; GST, glutathione S-transferase; RAP, receptor-associated protein; vWF, von Willebrand factor; SPR, surface plasmon resonance.
| |
REFERENCES |
|---|
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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