J Biol Chem, Vol. 274, Issue 43, 31000-31007, October 22, 1999
Role of Factor VIII C2 Domain in Factor VIII Binding to Factor
Xa*
Keiji
Nogami,
Midori
Shima
,
Kazuya
Hosokawa§,
Toyoaki
Suzuki§,
Takehiko
Koide¶,
Evgueni L.
Saenko
,
Dorothea
Scandella,
Masaru
Shibata,
Seiki
Kamisue,
Ichiro
Tanaka, and
Akira
Yoshioka
From the Department of Pediatrics, Nara Medical University, 840 Shijo-cho Kashihara City, Nara 634, Japan, § Fujimori Kogyo
Co., 56 Imaikami-cho, Nakahara-ku, Kawasaki City, Kanagawa 211, Japan,
the ¶ Department of Life Science, Faculty of Science, Himeji
Institute of Technology, Harima Science Garden City, Kamigori-cho,
Ako-gun, Hyogo 678, Japan, and the Holland Laboratory, American
Red Cross, Rockville, Maryland 20855
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ABSTRACT |
Factor VIII (FVIII) is activated by proteolytic
cleavages with thrombin and factor Xa (FXa) in the intrinsic blood
coagulation pathway. The anti-C2 monoclonal antibody ESH8, which
recognizes residues 2248-2285 and does not inhibit FVIII binding to
von Willebrand factor or phospholipid, inhibited FVIII activation by
FXa in a clotting assay. Furthermore, analysis by SDS-polyacrylamide
gel electrophoresis showed that ESH8 inhibited FXa cleavage in the presence or absence of phospholipid. The light chain (LCh) fragments (both 80 and 72 kDa) and the recombinant C2 domain
dose-dependently bound to immobilized anhydro-FXa, a
catalytically inactive derivative of FXa in which dehydroalanine
replaces the active-site serine. The affinity (Kd)
values for the 80- and 72-kDa LCh fragments and the C2 domain were 55, 51, and 560 nM, respectively. The heavy chain of FVIII did
not bind to anhydro-FXa. Similarly, competitive assays using
overlapping synthetic peptides corresponding to ESH8 epitopes (residues
2248-2285) demonstrated that a peptide designated EP-2 (residues
2253-2270; TSMYVKEFLISSSQDGHQ) inhibited the binding of the C2 domain
or the 72-kDa LCh to anhydro-FXa by more than 95 and 84%,
respectively. Our results provide the first evidence for a direct role
of the C2 domain in the association between FVIII and FXa.
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INTRODUCTION |
Factor VIII (FVIII)1 is
a glycoprotein cofactor that accelerates the generation of factor Xa
(FXa) by factor IXa in the presence of Ca2+ and negatively
charged phospholipid (PL) expressed on a membrane surface (1).
Quantitative and qualitative deficiencies of FVIII result in the
congenital bleeding disorder, hemophilia A. FVIII is noncovalently
bound to von Willebrand factor (vWF) in plasma. vWF regulates the
synthesis, the cofactor activity, and the transport of FVIII to the
site of vascular injury (2-4). Mature FVIII is synthesized as a single
chain polypeptide consisting of 2332 amino acid residues (5, 6). Based
on internal homologies of the amino acid sequence, FVIII has three
types of domains arranged in the order of A1-A2-B-A3-C1-C2 (7). FVIII
circulates in the plasma as a heterodimer of a heavy chain (HCh)
consisting of the A1, A2, and heterogeneous fragments of partially
proteolyzed B domains, together with a light chain (LCh) consisting of
A3, C1, and C2 domains (6, 7).
Several findings have indicated that the structure and function of the
C2 domain is important for the expression and regulation of FVIII. The
C2 domain contains a PL binding site (8, 9) and a vWF binding site
(10-12) together with a common epitope for FVIII inhibitor
alloantibodies, which develop in patients with severe hemophilia A
(13). Furthermore, residues Val2248-Gly2285
within the C2 domain contain the epitope for a monoclonal antibody ESH8, which reduces the rate of FVIII/vWF dissociation after thrombin activation of FVIII (14).
FVIII is transformed into an active form (FVIIIa) by limited
proteolysis by two serine proteases, thrombin and FXa (15, 16).
Cleavage at Arg372 and Arg740 of the 90-kDa HCh
fragment containing the A1 and A2 domains produces 54-kDa (A1) and
44-kDa (A2) species. Cleavage of the 80-kDa LCh fragment (A3-C1-C2) at
Arg1689 removes 40 amino-terminal acidic peptides from the
A3 domain (16) and produces a 72-kDa fragment. Cleavage by FXa at
Arg1721 produces a 67-kDa LCh fragment (17). Proteolysis at
Arg372 and Arg1689 is essential for generating
FVIIIa cofactor activity (18-20). FXa-dependent FVIII
activation is different from thrombin-dependent FVIII
activation in several ways (21, 22). The procoagulant activity of
FVIIIa produced by FXa is 4-fold lower and is more stable than that
generated by thrombin (22). Furthermore, the presence of vWF moderates
the activation of FVIII by FXa but not by thrombin (23). Recently,
Lapan and Fay (24) localized a factor X (FX) binding site within the A1
domain. The role of FXa-dependent FVIII activation in
vivo is still uncertain, however.
In the present study, we demonstrated that an anti-C2 monoclonal
antibody, containing an epitope within residues
Val2248-Gly2285, inhibited FXa cleavage of
FVIII in the absence of PL. Furthermore, the C2 domain competed with
FVIII for FXa cleavage of the LCh and bound directly to immobilized
anhydro-FXa, a catalytically inactive derivative of FXa in which
dehydroalanine replaces the active-site serine, indicating that the C2
domain contains a FXa binding site.
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EXPERIMENTAL PROCEDURES |
Proteins
FVIII was affinity-purified using monoclonal antibody
NMC-VIII/10, recognizing the FVIII A3 domain. Elution from the
monoclonal antibody column was performed with 1 M KI and
40% ethylene glycol as described previously (25). The specific
activity of the purified FVIII was 2700 units/mg. Enzyme-linked
immunosorbent assay (ELISA) demonstrated that the purified FVIII was
free of vWF antigen (26). LCh and HCh fragments of FVIII, together with
A1, A2, and thrombin-cleaved 72-kDa LCh fragments, were prepared from
plasma FVIII as described previously (27-29). Recombinant C2 domain
preparations were produced and purified as previously reported (30).
vWF was purified from a commercially available FVIII/vWF concentrate
(Confact F®; Chemo-Sero-Therapeutic Research Institute,
Kumamoto, Japan) using gel filtration on a column of Sepharose CL-4B
(Amersham Pharmacia Biotech, Uppsala, Sweden) as previously reported
(10). Residual FVIII was removed using immunobeads coated with
immobilized anti-FVIII monoclonal antibody. ELISA confirmed that FVIII
antigen was not present in the vWF fraction (26). Purified human FXa (specific activity 125 units/mg) was obtained from American Diagnostica Inc. (Greenwich, CT).
1-Palmitoyl-2-oleoyl-sn-glycero-3-phosphatidylserine and
L-
-lecithin egg phosphatidylcholine were obtained from
Avanti Polar Lipids Inc. (Alabaster, AL). PL vesicles were prepared as
a sonicated phosphatidylserine/phosphatidylcholine mixture (20:80 molar
ratio) in 20 mM Tris-HCl, 150 mM NaCl, pH 7.4, as described previously (31).
Coagulation Assays
FVIII activity was assayed in a one-stage clotting assay.
Anti-FVIII activity was quantified using the Bethesda assay (32). One
Bethesda unit (BU)/ml was defined as the concentration of antibody that
inhibited 50% of the FVIII activity contained in 1 ml of normal plasma
after a 2-h incubation at 37 °C. The specific anti-FVIII activity of
each monoclonal antibody was expressed as BU/mg of IgG.
Anti-FVIII Monoclonal Antibodies
Ranges of monoclonal antibodies against different epitopes of
FVIII were utilized. Two monoclonal antibodies against the FVIII C2
domain, ESH8 (American Diagnostica Inc.) and NMC-VIII/5, recognize amino acid residues 2248-2285 and 2170-2327, respectively (11, 12).
NMC-VIII/5 inhibits FVIII binding to vWF and PL (11). In contrast, ESH8
does not prevent FVIII binding to vWF or PL (12). Its FVIII inhibitory
activity is attributed to the inhibition of release of vWF from FVIII
following thrombin activation (14). Monoclonal antibody NMC-VIII/10,
recognizing residues 1675-1684 of the A3 domain, inhibits vWF binding,
but it has no effect on PL binding (25, 33). Monoclonal antibody C5,
recognizing the carboxyl-terminal acidic region of the A1 domain, was
kindly provided by Dr. C. A. Fulcher (Scripps Clinic Research
Institute, La Jolla, CA) (34). Monoclonal antibody JR8 (JR8 Scientific
Inc., Woodland, CA) recognizes the A2 domain. C5 and JR8 have no effect
on FVIII binding to either vWF or
PL.2 These properties of the
monoclonal antibodies are summarized in Table
I. The IgG of each monoclonal antibody
was fractionated by protein A-Sepharose affinity chromatography
(Amersham Pharmacia Biotech). F(ab)'2 fragments of IgG
antibodies were prepared using immobilized pepsin (Pierce) and protein
A-Sepharose.
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Table I
Properties of anti-FVIII monoclonal antibodies
NMC-VIII/10 and C5 bind to the acidic region of the A3 and A1 domains,
respectively.
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Protein Iodination
Five µg of purified FVIII was radiolabeled by incubation with
0.5 mCi of Na125I (Amersham Pharmacia Biotech) using
IODO-GEN® (Pierce) for 3 min as described previously (35).
Remaining free Na125I was removed by chromatography on a
PD-10 column (Amersham Pharmacia Biotech). The specific radioactivity
of 125I-FVIII was 10 µCi/µg protein. The activity of
125I-FVIII determined in a one-stage clotting assay was
similar to that of unlabeled FVIII. Aliquots of radiolabeled FVIII were
stored at 
80 °C for up to 1 month.
Preparation of Anhydro-FXa
Anhydro-FXa, a catalytically inactive derivative of FXa in which
dehydroalanine replaces the active-site serine, was prepared as
described for the preparation of anhydrothrombin (36). In outline, FXa
was chemically modified with phenylmethylsulfonyl fluoride (PMSF; Wako
Pure Chemical Industries Ltd., Osaka, Japan). To convert the
phenylmethylsulfonyl residues of the modified FXa to dehydroalanine
residues, the product was diluted with 0.05 M NaOH and
incubated for 12 min at 0 °C, and the pH was adjusted to 7.5. After
dialysis against 50 mM Tris-HCl, pH 7.5, containing 1 M NaCl, anhydro-FXa was purified by benzamidine-Sepharose
4B column chromatography (Amersham Pharmacia Biotech). The purified anhydro-FXa demonstrated <1% coagulant activity, and its molecular mass was estimated to be 43 kDa by SDS-polyacrylamide gel
electrophoresis (SDS-PAGE), similar to that of the native FXa (data not shown).
Synthetic Peptides
Synthetic peptides, each consisting of 13-18 overlapping amino
acids and corresponding to the known epitope of monoclonal antibody
ESH8 (residues 2248-2285), were synthesized by the method of
simultaneous multiple peptide synthesis as described previously (37).
They were analyzed and purified by reversed-phase high pressure liquid
chromatography (purity >95%).
Activation of FVIII by FXa
FVIII (100 nM) was diluted in veronal buffer (50 mM sodium acetate, 7 mM sodium barbital, 0.1 M NaCl), containing 2% bovine serum albumin (BSA; Bovine
Fraction V®, Katayama Chemical, Osaka, Japan) and was
incubated together with FXa (2 nM), PL vesicles (10 µM), and CaCl2 (2.5 mM) at
37 °C. At timed intervals, samples (10 µl) were taken from the
mixture, and FXa action was immediately quenched by 1000-fold dilution in 1 mM PMSF in veronal buffer at 4 °C. Each sample was
tested for FVIIIa coagulant activity using a one-stage clotting assay. To assess the inhibitory effects of monoclonal antibodies on FVIII activation by FXa, each antibody was mixed with FVIII prior to FXa
activation and incubated for 2 h at 37 °C. The anti-FVIII activity of each antibody was adjusted to 2 BU/ml. Control experiments indicated that the presence of FXa and PMSF in the diluted samples did
not influence the FVIII activity during the coagulation assay.
Analyses of FVIII Cleavage by FXa
SDS-PAGE--
125I-FVIII (10 nM) in 20 mM Tris-HCl, 150 mM NaCl, pH 7.4, was mixed
together with FXa (20 nM) and CaCl2 (2.5 mM) in the presence or absence of PL vesicles (10 µM). The mixture was incubated at 37 °C for 30 min in
the presence of PL and for 1 h in the absence of PL. At timed
intervals, samples (20 µl) were taken, and FXa action was quenched by
adding an equal volume of 0.4% SDS and immediately heating the samples
to 100 °C for 5 min. Each sample was analyzed on 7.5% SDS-PAGE
(38), followed by autoradiography of the dried gels. To assess the
inhibitory effects of antibodies on FVIII cleavage by FXa, an equal
volume of each antibody (5 µg) was mixed with 125I-FVIII
for 2 h at 37 °C prior to incubation with FXa, as described above.
To examine the cleavage of FXa in the presence of vWF,
125I-FVIII (10 nM) was incubated with vWF (50 nM) for 1 h at 37 °C prior to the addition of FXa
in the absence of PL.
ELISA for Evaluation of FXa Cleavage of FVIII
LCh--
Microtiter wells (NUNC-Immuno Plate MaxiSorp, NUNC, Denmark)
were coated overnight at 4 °C with 2 µg of each monoclonal
antibody (NMC-VIII/5, ESH8, C5, or JR8) per well in 100 µl of coating
buffer (0.1 M sodium bicarbonate, pH 9.6). After washing
three times with washing buffer (phosphate-buffered saline, pH 7.4, containing 0.05% Tween 20), the wells were then blocked for 2 h
at 37 °C by the addition of coating buffer containing 4% BSA. After
washing, FVIII (10 nM) in washing buffer containing 4% BSA
was added to each well and incubated for 2 h at 37 °C. FXa (20 nM) and CaCl2 (2.5 mM) were then
added at 37 °C. At timed intervals, the supernatants were removed,
and FXa action was quenched by the addition of 1 mM PMSF.
Bound FVIII was detected by incubation with peroxidase-conjugated NMC-VIII/10, which recognizes the amino-terminal acidic region of LCh,
followed by the addition of o-phenylenediamine
dihydrochloride substrate dissolved in 25 mM citric acid,
50 mM Na2HPO4, 0.03% hydrogen
peroxide. After 2 M H2SO4 was added
as a quenching solution, the absorbance was read at 492 nm (Labsystem
Multiskan Multisoft, Helsinki, Finland). Control experiments indicated
that the presence of PMSF did not influence this system. Furthermore,
SDS-PAGE confirmed that NMC-VIII/10, which was used to detect bound
FVIII, did not itself inhibit FXa cleavage. The rate of FVIII LCh
cleavage was calculated as follows: (1 (bound nonspecific
A492/bound at time zero nonspecific A492)) × 100(%). The
absorbance reading in the absence of FVIII was regarded as nonspecific.
In competitive inhibition experiments using FVIII fragments (72-kDa
LCh, A1, A2, or recombinant C2 domain), 2 µg of NMC-VIII/10 was
coated onto microtiter wells as described above. In this assay, a 100 nM concentration of each FVIII fragment was added
simultaneously with FXa prior to FXa action, and peroxidase-conjugated
NMC-VIII/5 was used for detection of bound FVIII.
Measurement of Binding of FVIII to Immobilized Anhydro-FXa
Six µg of anhydro-FXa in 20 mM Tris-HCl, 150 mM NaCl (TBS), pH 7.4, were immobilized onto each well of a
microtiter plate. After blocking with 4% BSA, serially diluted FVIII
fragments in TBS, containing 2.5 mM CaCl2 and
4% BSA, were added and incubated for 2 h at 37 °C. Bound LCh
or HCh fragment was detected by peroxidase- conjugated NMC-VIII/5 or
JR8, respectively.
In competitive inhibition experiments using FVIII fragments, serially
diluted 125I-FVIII was added to the immobilized
anhydro-FXa. Bound 125I-FVIII was measured in a
-counter. In this assay, serially diluted FVIII fragments were mixed
with 125I-FVIII (100 nM) prior to adding to the
anhydro-FXa. The percentage inhibition was calculated as follows: (1 (bound nonspecific count)/(maximum nonspecific)) × 100 (%). Radioactive counts in the absence of 125I-FVIII were
regarded as nonspecific.
Kinetic Measurements Using Biomolecular Interaction Analysis
The kinetics of FVIII and anhydro-FXa interaction were
determined by surface plasmon resonance using a BIAcore 2000 instrument (Biacore AB, Uppsala, Sweden). Anhydro-FXa was covalently bound to an
activated carboxymethyldextran-coated CM5 sensor chip surface by amine
coupling according to the manufacturer's recommendations (39, 40).
Binding (association) of all ligands were monitored in TBS, pH 7.4, containing 2.5 mM CaCl2, 0.005% Tween 20 at a flow rate of 10 µl/min for 4 min. Dissociation was monitored over a
5-10 min range after return to buffer flow. After each analysis, regeneration of the chip surface was achieved by 0.1 M
glycine, pH 2.0, for 1 min. The values of association rate constants
(ka) and dissociation rate constants
(kd) were determined by nonlinear regression
analysis as described previously (39, 40) using the evaluation software
provided by Biacore AB. The values of equilibrium dissociation
constants (Kd) were calculated as
kd/ka.
Inhibitory Effects of Synthetic Peptides on the Binding of
the C2 Domain or LCh to Anhydro-FXa
Each overlapping peptide was serially diluted and mixed with 100 nM recombinant C2 domain or 72-kDa LCh fragment prior to addition to the immobilized anhydro-FXa. Bound FVIII was detected using
peroxidase-conjugated NMC-VIII/5. Control experiments indicated that
none of the synthetic peptides affected binding of FVIII fragments to
NMC-VIII/5. The percentage inhibition was calculated as follows: (1 (bound nonspecific A492)/(maximum nonspecific A492)) × 100(%). Absorbance at 492 nm in the absence of FVIII was regarded as nonspecific.
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RESULTS |
Inhibitory Effects of Antibodies on FVIII Activation by
FXa--
Five min after incubation of FVIII with FXa there was an
initial 4.5-fold increase in FVIII coagulant activity (Fig.
1A). Peak activity was
followed by inactivation, and the base-line level was reached within 45 min of incubation. In order to examine the influence of anti-FVIII
monoclonal antibodies, FXa-dependent FVIII activation in
the presence of each antibody was performed in the presence of PL.
Monoclonal antibody ESH8 recognizing the FVIII C2 domain strongly
prevented the activation at a concentration of 2 BU/ml (Fig.
1A), and the inhibitory effect was
dose-dependent (Fig. 1B). In contrast, the
alternative anti-C2 monoclonal antibody, NMC-VIII/5, tended to enhance
FVIII activation by FXa when compared with the pattern in the absence
of antibody. None of the other monoclonal antibodies, anti-A1 antibody
(C5), anti-A2 antibody (JR8), and anti-A3 antibody (NMC-VIII/10),
inhibited FXa-dependent activation of FVIII at
concentrations of 2 BU/ml (Fig. 1A) or 5 BU/ml (not
shown).
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Fig. 1.
Inhibitory effects of FVIII monoclonal
antibodies on FVIII activation by FXa. A, FVIII (100 nM) was preincubated with 2 BU/ml of the anti-FVIII
monoclonal antibodies for 2 h at 37 °C and subsequently
activated with FXa (2 nM), PL vesicles (10 µM), and CaCl2 (2.5 mM). FVIII
procoagulant activity was determined by a one-stage clotting assay at
the indicated time points.  , NMC-VIII/5;  , ESH8;  , C5;  ,
JR8;  , NMC-VIII/10;  , no antibody. B, inhibitory
effects of various concentrations of ESH8 antibody on FXa activation.
, 1 BU/ml; , 1.5 BU/ml; , 2 BU/ml; , no antibody.
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Inhibitory Effects of Antibodies on FVIII Cleavage by FXa--
We
postulated that the inhibitory effect of the anti-C2 monoclonal
antibody ESH8 on FVIII activation by FXa might be caused by either a
change in the cleaved FVIIIa molecule that alters its coagulant
activity or by a direct inhibition of the proteolytic cleavage of FVIII
by FXa. To distinguish between these possibilities, we incubated
125I-labeled FVIII together with FXa for 1 h at
37 °C in the absence or presence of FVIII antibodies and then
examined the cleavage pattern by SDS-PAGE. FVIII cleavage by FXa in the
absence of antibodies resulted in the conversion of the 90-210 kDa
fragments of the HCh into 54- and 44-kDa fragments and proteolysis of
the 80-kDa fragment of the LCh into 72- and 67-kDa fragments (Fig.
2A, lane 2). In this instance, however, the 54-kDa fragment was
observed only very weakly, and 47- and 40-kDa faint fragments as well
as strong bands at dye front were also visible in the lower part of
lane 2, suggesting that the 54-kDa fragment had
been extensively proteolyzed by FXa. ESH8 completely blocked the
cleavage of the 80-kDa LCh fragment and reduced the formation of the
54- and 44-kDa fragments (Fig. 2A, lane
3). These results suggested that ESH8 completely prevented
proteolytic cleavage at Arg1689 and Arg1721 in
the LCh and partially inhibited Arg372 in the HCh. In
contrast, NMC-VIII/5 did not block the cleavage of the 80-kDa LCh
fragment; rather, it tended to promote proteolysis, since the 72-kDa
LCh fragment was more strongly evident than in other reactions (Fig.
2A, lane 4). Moreover, the 54-kDa
fragment was markedly stronger and the 90-kDa fragment was not observed in the presence of NMC-VIII/5. These findings suggested that the antibody enhanced FXa-induced proteolysis of the HCh as well as the
LCh, although selective inhibition of cleavage at Arg336 by
NMC-VIII/5 could not be excluded. NMC-VIII/10, C5, and JR8 did not
interfere with FXa cleavage of FVIII (Fig. 2A,
lanes 5-7, respectively).
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Fig. 2.
Inhibitory effects of antibodies on FVIII
cleavage by FXa analyzed by SDS-PAGE. 125I-FVIII (10 nM) was incubated with FXa (20 nM) and
CaCl2 (2.5 mM) in the presence (A)
or absence (B) of PL vesicles (10 µM). The FXa
reaction was quenched by adding 0.4% SDS at 100 °C, followed by
SDS-PAGE. FVIII in the absence of FXa is shown in lane 1. FVIII cleavage in the absence and presence of anti-FVIII
monoclonal antibodies (5 µg) is illustrated in lanes 2 and lanes 3-7, respectively.
Lanes 3-7 correspond to ESH8, NMC-VIII/5,
NMC-VIII/10, C5, and JR8, respectively.
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The C2 domain contains a PL binding site, and several anti-C2
antibodies are known to inhibit FVIII binding to PL (9). Furthermore,
since FVIII cleavage by FXa occurs at a faster rate in the presence of
PL than in its absence, inhibition of FVIII binding to PL results in
indirect inhibition of FVIII cleavage by FXa. Therefore, we further
examined the effects of monoclonal antibodies in the absence of PL.
ESH8 again completely blocked the cleavage of the 80-kDa LCh fragment
and delayed the formation of the 54- and 44-kDa fragments from the
90-kDa HCh fragment (Fig. 2B, lane 3).
This finding indicated that the inhibitory effect of ESH8 was not due
to the presence of PL. Also, the cleavages by FXa in the presence of
NMC-VIII/5 in the non-PL system were similar to those obtained in the
presence of PL and tended to be more marked in the presence of the
antibody than in its absence (Fig. 2B, lane
4). Moreover, NMC-VIII/10, C5, and JR8 did not inhibit FVIII
cleavage in the absence of PL (Fig. 2B, lanes
5-7, respectively). All of these findings indicated that
the inhibitory effect of ESH8 on FXa-induced activation of FVIII could
be attributed to a PL-independent mechanism, in particular inhibition
of FVIII LCh proteolysis at Arg1689 and
Arg1721.
Inhibitory Effects of vWF on FVIII Cleavage by FXa--
We have
previously reported that the monoclonal antibody NMC-VIII/5 promoted
the dissociation of FVIII from the FVIII·vWF complex (11), whereas
ESH8 prevented thrombin-induced dissociation of FVIII and vWF (14). We
now observe from the above results that ESH8 and NMC-VIII/5 had
opposite effects on FXa activation and cleavage of FVIII, although both
recognize the C2 domain. Since the C2 domain is involved in FVIII
binding to vWF, we further analyzed the effects of these two C2
monoclonal antibodies on FVIII cleavage by FXa in the presence of vWF
by SDS-PAGE. vWF completely blocked the cleavage of 80-kDa LCh and also
delayed the cleavage of the 90-210-kDa HCh (Fig.
3, compare lane 3 with lane 2). These findings indicated that the
vWF of the FVIII·vWF complex protected FVIII from the proteolytic
activity of FXa. When ESH8 was added to FVIII in the presence of vWF
prior to the addition of FXa, the protective effect of vWF remained
evident, and as in the absence of antibody, cleavage of the LCh was
completely inhibited, and proteolysis of the HCh was markedly delayed
(Fig. 3, lane 4). In contrast, when NMC-VIII/5
was added prior to the addition of FXa, the protective effect of vWF
was lost, and both the LCh and HCh were proteolyzed to their respective
lower molecular weight fragments (Fig. 3, lane
5). These results were in keeping with our earlier findings
that FVIII was dissociated from vWF by NMC-VIII/5 (11) and therefore
became susceptible to proteolysis by FXa.
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Fig. 3.
Effect of C2 antibodies on FVIII cleavage by
FXa in the presence of vWF. FXa in the absence of PL was added to
125I-FVIII (10 nM) in the absence
(lane 2) or presence (lane 3) of vWF (50 nM). After incubation for 1 h
at 37 °C, each sample was analyzed on SDS-PAGE. ESH8 or NMC-VIII/5
(5 µg, lane 4 or 5, respectively)
was incubated with FVIII·vWF complex for 2 h at 37 °C prior
to the addition of FXa. FVIII in the absence of FXa is shown in the
control lane (lane 1).
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Inhibition of FXa Proteolysis of FVIII LCh by Monoclonal
Antibodies--
In order to quantify the inhibitory effects of
anti-FVIII antibodies on FVIII cleavage by FXa, we utilized an ELISA in
the absence of PL. In this system, NMC-VIII/10 was used for detection, since it binds to the amino-terminal acidic region (epitope,
1675-1684) of LCh, does not bind to the cleaved 72- and 67-kDa LCh
fragments, and does not interfere with FXa activity. It loses its
binding ability if the LCh is cleaved at Arg1689 or
Arg1721. The decrease in reactivity of NMC-VIII/10 with
bound FVIII provides a measure, therefore, of FXa-dependent
cleavage of the intact LCh. No cleavage of LCh was observed in the
presence of ESH8 for 1 h after the addition of FXa (Fig.
4). In contrast, in the presence of
NMC-VIII/5, C5, and JR8, cleavages of the LCh at Arg1689
and Arg1721 were almost complete (>95%) at 1 h.
Notably, proteolysis of LCh by FXa in the presence of NMC-VIII/5
appeared to be more rapid than in the presence of C5 or JR8, thus
confirming the results of SDS-PAGE analysis.
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Fig. 4.
Inhibitory effects of antibodies on FVIII LCh
cleavage by FXa analyzed by ELISA. FXa (20 nM) and
CaCl2 (2.5 mM) were added to FVIII (10 nM) bound to each of the immobilized anti-FVIII monoclonal
antibodies NMC-VIII/5, ESH8, C5, and JR8 (2 µg), and FVIII was
subsequently activated by FXa. The supernatant was removed at the
indicated times, and the FXa reaction was quenched with 1 mM PMSF. Cleavage of FVIII LCh was detected using
peroxidase-conjugated NMC-VIII/10. , NMC-VIII/5; , ESH8; , C5;
, JR8.
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Competitive Inhibition of FXa Proteolysis of LCh by FVIII
Fragments--
Since the anti-C2 antibody ESH8 inhibited
FXa-dependent proteolysis and activation, we investigated
the hypothesis that the C2 domain is an essential domain for the
association between FVIII and FXa. FVIII fragments (72-kDa LCh, A1, A2,
or C2 domain) were tested for their ability to compete for the
proteolysis of FVIII LCh by FXa in the ELISA described above. The
72-kDa LCh fragment competitively inhibited FXa cleavage of FVIII LCh
by >95%. Similarly, the recombinant C2 domain inhibited cleavage by
63%. Minimal competitive inhibition (<5%) was observed, however,
using the A1 and A2 domains (Fig. 5).
These findings implicated a direct role for the C2 domain in FVIII and
FXa association.
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|
Fig. 5.
Competitive inhibition of FVIII cleavage by
FXa with FVIII fragments. Each FVIII fragment (100 nM)
was mixed with FXa (20 nM) and CaCl2 (2.5 mM) and was added to FVIII (10 nM) bound to
immobilized NMC-VIII/10. The FXa reaction was quenched with 1 mM PMSF at the indicated times. Cleavage of FVIII LCh was
detected by peroxidase-conjugated NMC-VIII/5. , 72-kDa LCh; , C2
domain; , A1 domain; , A2 domain; , no fragment.
|
|
Binding of the C2 Domain to Immobilized Anhydro-FXa--
To
further investigate the relationship between the C2 domain and FXa, we
developed an ELISA to measure the direct binding of FXa to FVIII
fragments. To prevent the possible FXa-mediated cleavage of FVIII, we
used active-site-modified FXa (anhydro-FXa), which lacks proteolytic
activity. Binding was detected using NMC-VIII/5 or JR8 (known not to
inhibit FXa action) for LCh or HCh, respectively. Control experiments
showed that whole FVIII bound to immobilized anhydro-FXa in a
dose-dependent manner (Fig.
6). Similarly, the 80- and 72-kDa LCh
fragments demonstrated a dose-dependent binding pattern and
appeared to bind more strongly than the whole FVIII (Fig.
6A). In addition, the C2 domain bound to anhydro-FXa in a
dose-dependent manner, although in this instance the
binding efficiency was approximately half that of the LCh fragments.
The HCh fragment and the A2 domain showed little or no binding to anhydro-FXa (Fig. 6B).
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Fig. 6.
Binding of the C2 domain and FVIII fragments
to anhydro-FXa. Serially diluted FVIII fragments were added to the
immobilized anhydro-FXa (6 µg). Bound FVIII was detected using
peroxidase-conjugated NMC-VIII/5 (A) or JR8 (B)
for LCh or HCh fragment, respectively. A, , whole FVIII;
, 80-kDa LCh; , 72-kDa LCh; , C2 domain. B, ,
whole FVIII; , A2 domain; , HCh.
|
|
Direct binding of FXa to FVIII was confirmed in a competitive assay
using FVIII fragments and 125I-FVIII. The 80- and 72-kDa
LCh fragments inhibited anhydro-FXa binding of 125I-FVIII
by approximately 90%, and the C2 domain also inhibited binding by
58%. The HCh, however, did not inhibit binding of FVIII to anhydro-FXa
(Fig. 7). These findings strongly
suggested that the C2 domain is directly associated with the reactions
between FVIII and FXa.
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Fig. 7.
Competitive inhibition of FVIII binding to
anhydro-FXa by FVIII fragments. Serially diluted FVIII fragments
were mixed with 125I-FVIII (100 nM) prior to
the assay of anhydro-FXa binding. Bound 125I-FVIII was
measured in a -counter. , 80-kDa LCh; , 72-kDa LCh; , C2
domain; , HCh.
|
|
Kinetic Parameters of the Interaction between FVIII Fragments and
Anhydro-FXa--
The kinetic measurements (ka,
kd, and Kd) for binding of FVIII
to anhydro-FXa were calculated by surface plasmon resonance analysis
and are illustrated in Table II. The
Kd value for FVIII was 190 nM. The
Kd values for the 80- and 72-kDa LCh fragments (55 and 51 nM, respectively) were approximately 4-fold less
than that of the whole FVIII. The Kd value for the
C2 domain was 560 nM. The HCh did not react with
anhydro-FXa.
Inhibition of FVIII Fragment Binding to Anhydro-FXa by Synthetic
Peptides--
Since the anti-C2 monoclonal antibody, ESH8, inhibited
cleavage of FVIII by FXa and the recombinant C2 domain bound to
anhydro-FXa, we focused on the known epitope structure of ESH8 (Fig.
8) to identify the potential FXa binding
site. One of the synthetic peptides, designated EP-2 (residues
2253-2270), completely inhibited (>95%) binding of the recombinant
C2 domain to anhydro-FXa. The concentration of the synthetic peptide
producing 50% inhibition (IC50 value) was 13 µM (Fig. 9A).
EP-2 also inhibited (84%) binding of the 72-kDa LCh fragment to
anhydro-FXa (IC50 = 25 µM; Fig. 9B). Similarly, the synthetic peptide EP-3 (residues
2258-2272) inhibited binding of the C2 domain and the 72-kDa LCh to
anhydro-FXa but to a lesser extent (84 and 51%; IC50 = 25 and 100 µM, respectively). EP-4 (residues 2263-2277)
partially inhibited binding to FXa, while EP-1 (residues 2248-2265),
EP-5 (residues 2269-2281), and EP-6 (residues 2272-2285) demonstrated
very weak or no inhibitory reactions. A control peptide
(QHGDQSSSILFEKVYMST) containing the same composition as EP-2 but in a
random sequence did not interfere with the binding of FVIII fragments
to anhydro-FXa binding (not shown). These findings indicated that the
FXa binding site is located within residues 2253-2270 of the C2 domain
of FVIII.
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Fig. 8.
Schematic representation of synthetic FVIII
peptides. The FVIII amino acid residues from 2248 to 2285 of the
FVIII C2 domain are represented by their one-letter notations. The
lines below the amino acid residues indicate the
inclusive amino acid residues of the synthetic peptides.
|
|
View larger version (14K):
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|
Fig. 9.
Inhibition of FVIII fragment binding to
anhydro-FXa by synthetic peptides. Each overlapping synthetic
peptide was serially diluted and was mixed with a 100 nM
concentration of the C2 domain (A) or 72-kDa LCh fragment
(B) prior to incubation with the immobilized anhydro-FXa.
Bound FVIII fragment was detected by peroxidase-conjugated NMC-VIII/5.
, EP-1; , EP-2; , EP-3; , EP-4; , EP-5; , EP-6.
|
|
| |
DISCUSSION |
The present study revealed several novel findings that implicate
the involvement of the C2 domain in the association between FVIII and
FXa. First, the anti-C2 monoclonal antibody, ESH8, inhibited cleavage
of FVIII by FXa, suggesting either that the antibody directly inhibited
FXa binding to the C2 domain or that antibody binding produced a
conformational change that prevented FXa cleavage. Second, the C2
domain as well as the 72-kDa LCh fragment of FVIII competitively
inhibited FXa cleavage of the FVIII LCh. This finding indicated that
the C2 domain is required for binding of FVIII to FXa rather than for
cleavage of FVIII by FXa. Third, the C2 domain bound to a catalytically
inactive FXa, anhydro-FXa, indicating more directly that the C2 domain
contains the FXa binding site; and fourth, synthetic peptides,
corresponding to sequences within the known epitope of ESH8, inhibited
the binding of both the C2 domain and the 72-kDa LCh fragment of FVIII
to anhydro-FXa. These data identified amino acid residues 2253-2270
within the C2 domain as essential for FXa binding.
In order to more precisely verify the relationship between the
inhibitory effects of the monoclonal antibody and C2 epitope specificity, we compared ESH8 with another anti-C2 monoclonal antibody,
NMC-VIII/5, which also inactivates FVIII. Although their anti-FVIII
activities were comparably high, other characteristics were notably
different. ESH8, which has an epitope within the region
Val2248-Gly2285, strongly inhibited both
activation and cleavage of FVIII by FXa but did not inhibit FVIII
binding to PL (14). Conversely, NMC-VIII/5, which has an epitope within
residues 2170-2327 and inhibits PL binding (11), enhanced the
activation and cleavage of FVIII by FXa. These results suggested that
the critical region for the association between FVIII and FXa is more
likely to be within the amino-terminal C2 domain than in the PL binding
region. Furthermore, the inhibitory effect of ESH8 on FVIII cleavage by FXa was not due to inhibition of FVIII binding to PL.
The cleavage of FVIII by FXa was completely inhibited by the addition
of vWF in our PL-independent system. Similar inhibitory effects of vWF
on FXa-dependent activation were previously reported by
Koedam et al. (23). Those workers also described the loss of
the amino-terminal 50-kDa HCh fragment in the absence of vWF, coincident with the formation of minor products of lower molecular mass, and suggested that the formation of the FVIII·vWF complex protects FVIII from extensive proteolytic cleavage by FXa. The formation of the FVIII·vWF complex also inhibits PL binding to FVIII.
Because the vWF and PL binding sites have been identified in the C2
domain (8, 12), our results strongly support the involvement of the C2
domain in the association between FVIII and FXa. The earlier findings
and our present data suggest that a vWF binding site is located close
to the FXa binding site, although the possibility of steric hindrance
of FXa due to conformational changes brought about when FVIII is
complexed with vWF cannot be excluded.
The two anti-C2 monoclonal antibodies, ESH8 and NMC-VIII/5, show
different characteristics in moderating FVIII and vWF interaction. ESH8
inhibits FVIII release from vWF (14), but NMC-VIII/5 dissociates FVIII
from the FVIII·vWF complex and inhibits vWF binding (11). In the
current investigation, NMC-VIII/5 did not inhibit the cleavage by FXa
but rather tended to enhance it. Furthermore, the inhibitory effect of
vWF on FXa-induced proteolysis of FVIII at both Arg1689 and
Arg1721 was blocked in the presence of NMC-VIII/5 but was
not blocked in the presence of ESH8. Thrombin cleaves FVIII only at
Arg1689 in the LCh, and its reaction is not inhibited in
the presence of vWF (23). It is evident, therefore, that activation of
FVIII by FXa is regulated by the presence of vWF and that the binding mechanism for FXa is different from that of thrombin, although both
proteases cleave at Arg1689.
Recently, a binding site for FX was localized within the acidic region
of FVIII at the carboxyl terminus of the A1 domain (24). This was
determined in binding experiments using immobilized FVIII captured by
the same monoclonal antibody, ESH8, which inhibited FXa cleavage in our
study. Those workers obtained similar results using FVIII immobilized
on an anti-HCh monoclonal antibody and ruled out the involvement of the
FVIII LCh in FX binding. We focused on FXa instead of FX, since FVIII
is proteolytically activated by FXa. It is not surprising that FXa
binds to FVIII at a different site from FX. FXa binding sites in factor
V, which is homologous with FVIII and has a similar domain structure,
were recently identified within both the HCh and LCh (41). Furthermore,
a membrane protein similar to the LCh of the factor V has been
identified as a membrane receptor for FXa in leukocytes (42).
In order to demonstrate more directly that the C2 domain contains the
FXa binding site, we used a catalytically inactivated derivative
of FXa in our binding experiments. We prepared anhydro-FXa, in which
the active-site serine was initially inactivated by PMSF and then
modified the phenylmethylsulfonyl serine to dehydroalanine by
elimination of phenylmethylsulfonyl under alkaline conditions. Previous
experiments using anhydrothrombin had shown that physiological substrate binding activity of the derivative is completely preserved under these conditions (36). In our investigation, the recombinant C2
domain or the LCh fragments (80 and 72 kDa) bound to anhydro-FXa in a
dose-dependent and saturable manner. The
Kd value (560 nM) for the C2 domain was
higher than those for the 80- and 72-kDa LCh fragments (55 and 51 nM, respectively). Several reasons for this lower affinity
of the C2 domain can be considered. One explanation may be that at
least the whole 72-kDa LCh is necessary for intact conformation of the
C2 domain. The Kd value for the binding to vWF of
the C2 domain is similarly higher than that for the LCh (43). Since the
Kd value for the 80-kDa LCh fragment was very close
to that for the 72-kDa LCh, it seemed unlikely that amino-terminal
acidic region of the A3 domain was essential for FXa. It is pertinent
that the HCh did not bind to anhydro-FXa. Furthermore, although
proteolytic cleavage at Arg372 in the HCh was inhibited by
the anti-C2 monoclonal antibody ESH8, this inhibition was less than
that seen at Arg1689 and Arg1721 in the LCh.
These results suggest that the role of the C2 domain is more dominant
than that of the HCh in FXa binding.
Finally, we obtained direct evidence for the presence of the FXa
binding site in the C2 domain by competitive experiments using
overlapping synthetic peptides based on the known epitope sequence of
ESH8. One of the peptides (EP-2), corresponding to residues 2253-2270,
completely (>95%) inhibited binding of the C2 domain and partially
inhibited (84%) binding of the 72-kDa LCh fragment to anhydro-FXa.
This inhibition was specific, since a control peptide, containing the
same amino acids with a random sequence did not inhibit the reactions.
An alternative peptide (EP-3), corresponding to residues 2258-2272,
also inhibited binding of the C2 domain to anhydro-FXa. So it appears
that residues 2258KEFLISSSQDGHQ2270 contained
an important binding site for FXa in the C2 domain. These data provide
strong evidence for the presence of a major binding site for FXa in the
C2 domain of FVIII, although the possibility of the presence of an
additional binding site in the A3-C1 region cannot be totally excluded.
Our findings provide the first direct evidence that the C2 domain of
FVIII contains a major FXa binding site. Since FXa cleavage sites are
located in the A3 domain, FXa may bind the C2 domain at a site remote
from its active site. Our results also suggest that inhibition of FXa
proteolytic activity may represent a new FVIII inhibitory mechanism.
Further studies are required to determine the precise physiological
role of FXa binding to FVIII.
| |
ACKNOWLEDGEMENT |
We thank Dr. J. C. Giddings for helpful suggestions.
| |
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 Pediatrics,
Nara Medical University, 840 Shijo-cho Kashihara City, Nara 634, Japan.
Tel.: 81-744-29-8881; Fax: 81-744-24-9222; E-mail: mshima@nmu-gw.cc.naramed-u.ac.jp.
2
K. Nogami, M. Shima, K. Hosokawa, T. Suzuki, T. Koide, E. L. Saenko, D. Scandella, M. Shibata, S. Kamisue, I. Tanaka, and A. Yoshioka, unpublished data.
| |
ABBREVIATIONS |
The abbreviations used are:
FVIII, factor VIII;
FXa, factor Xa;
PL, phospholipid;
vWF, von Willebrand factor;
HCh, heavy chain of FVIII;
LCh, light chain of FVIII;
FVIIIa, activated
FVIII;
FX, factor X;
ELISA, enzyme-linked immunosorbent assay;
PMSF, phenylmethylsulfonyl fluoride;
PAGE, polyacrylamide gel
electrophoresis;
TBS, Tris-buffered saline;
BSA, bovine serum albumin;
BU, Bethesda unit(s) determined by inhibitor assay.
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