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 Previous Article | Table of Contents | Next Article 
Blood, Vol. 92 No. 9 (November 1), 1998:
pp. 3240-3249
Induction of Fibrinogen Binding and Platelet Aggregation as a
Potential Intrinsic Property of Various Glycoprotein IIb/IIIa
( IIb 3) Inhibitors
By
Karlheinz Peter,
Meike Schwarz,
Jari Ylänne,
Benedikt Kohler,
Martin Moser,
Thomas Nordt,
Peter Salbach,
Wolfgang Kübler, and
Christoph Bode
From the Department of Internal Medicine III, University of
Heidelberg, Heidelberg, Germany; and the Department of Biochemistry,
University of Helsinki, Helsinki, Finland.
 |
ABSTRACT |
The blockade of platelet integrin glycoprotein (GP) IIb/IIIa is a
promising new antiplatelet strategy. The binding of ligands or of the
ligand-mimetic peptide RGD causes a conformational change of GP
IIb/IIIa from the nonactivated to the activated state. Because several
blocking agents/inhibitors are ligand-mimetics, the current study
evaluates whether these agents have the intrinsic property to activate
GP IIb/IIIa. Fibrinogen binding to GP IIb/IIIa on platelets or on CHO
cells expressing recombinant GP IIb/IIIa was evaluated by flow
cytometry or 125I-labeled fibrinogen. Incubation with the
monoclonal antibody (MoAb) fragment c7E3 (abciximab) results in
fibrinogen binding to GP IIb/IIIa and in the access of ligand-induced
binding sites. At low concentrations (0.01 to 0.1 µg/mL), this
intrinsic activating property of c7E3 can result in platelet
aggregation. The disintegrin flavorodin and the RGD analogue fradafiban
also induce fibrinogen binding, whereas the blocking MoAbs 2G12 and P2
and the activation-specific MoAb PAC-1 do not. Aspirin and indomethacin
cannot block c7E3-induced fibrinogen binding to GP IIb/IIIa, but can
inhibit c7E3-induced platelet aggregation. Thus, we conclude that GP
IIb/IIIa inhibitors can demonstrate an intrinsic activating property,
which can result in fibrinogen binding to GP IIb/IIIa and consequently
in platelet aggregation. Cyclooxygenase inhibitors can inhibit platelet
aggregation caused by GP IIb/IIIa inhibitors. Further studies will have
to evaluate the clinical relevance of the potential intrinsic
activating property of GP IIb/IIIa inhibitors and define consequences
for the future drug development and evaluation of these potent
antiplatelet agents.
© 1998 by The American Society of Hematology.
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INTRODUCTION |
THERAPEUTIC STRATEGIES to inhibit
platelet function, eg, by aspirin, are beneficial in various clinical
settings.1 More recently, the platelet fibrinogen receptor,
glycoprotein (GP) IIb/IIIa, which mediates platelet aggregation and
partially platelet adhesion, has become a successful target for
antiplatelet therapy.2-5 This glycoprotein belongs to the
adhesion molecule family of integrins and is also termed
 IIb 3.2,6,7 Upon platelet
activation, GP IIb/IIIa is functionally regulated by change in the
anchorage of the receptor to the cytoskeleton8 and by a
conformational change of GP IIb/IIIa that results in a high-affinity
state for the ligand fibrinogen (activated GP
IIb/IIIa).2,6,7 The amino acid sequence RGD, which is found
in the chain of fibrinogen but also in other ligands of GP
IIb/IIIa, has been demonstrated to be directly involved in ligand
binding to GP IIb/IIIa.2,7,9 For small peptides containing
the RGD sequence, an effective inhibition of fibrinogen binding to GP
IIb/IIIa and thus an effective inhibition of platelet aggregation has
been demonstrated.9 Stimulated by the results with RGD
peptides, several chemically synthesized RGD analogues have been
developed.2,4 Furthermore, various snake venoms proved to
be a rich source of a wide variety of GP IIb/IIIa blocking peptides,
the so-called disintegrins.2 And finally, blocking
monoclonal antibodies (MoAbs), such as c7E3 (abciximab), can be used
for the blockade of GP IIb/IIIa.2-5
The binding of the ligand fibrinogen causes a conformational change of
GP IIb/IIIa.10,11 RGD peptides mimic fibrinogen and thereby
also induce a conformational change.10-14 In contrast to
soluble fibrinogen, the small RGD peptides can bind to GP IIb/IIIa in
the nonactivated, low-affinity state.13,14 If the RGD
peptide is washed out from its receptor, GP IIb/IIIa is left in a
high-affinity state with respect to the binding of
fibrinogen.13 The present study evaluates whether GP
IIb/IIIa inhibitors have the intrinsic property of inducing instead of
blocking fibrinogen binding to GP IIb/IIIa. The major focus is on c7E3,
because it is presently the most widely clinically used GP IIb/IIIa
inhibitor.
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MATERIALS AND METHODS |
Blood preparation and cells.
Blood was collected by venipuncture with a 21-gauge butterfly needle
from healthy volunteers and anticoagulated with citric acid.
Platelet-rich plasma was obtained by centrifugation at 100g in
plastic tubes at room temperature for 15 minutes in a laboratory centrifuge (Sorvall RT 6000; Du Pont, Bad Homburg, Germany).
CHO cells expressing either low-affinity (nonactivated) or
high-affinity (activated) GP IIb/IIIa were produced as described elsewere in detail.15-17 For creation of the first,
wild-type IIb, for the second, a VGFFK-deleted
IIb, with an additional exchange of the
IIb cytoplasmic domain by the L
cytoplasmic sequence, were transfected together with wild-type
3 by electroporation.15,16 Cells were
maintained in Dulbecco's modified Eagle's medium (DMEM), 10% fetal calf serum, 1% MEM nonessential amino acids, 2 mmol/L L-glutamine, 700 µg/mL Geneticin, 100 U/mL penicillin, and 100 µg/mL streptomycin (all from GIBCO, Eggenstein, Germany).
Antibodies and peptides.
The mouse/human chimeric Fab c7E3 (abciximab; ReoPro) was purchased
from Beiersdorf-Lilly (Hamburg, Germany). IgG and
F(ab )2 of MoAb 7E3 were gifts of Centocor (Malvern,
PA). The GP IIb/IIIa complex-specific MoAb 2G12 was provided by Dr
Virgil Woods (University of California, San Diego, CA). The
activation-dependent anti-GP IIb/IIIa MoAb PAC-118 was
provided by Dr Sanford Shattil (Scripps Research Institute, La Jolla,
CA). Anti-LIBS6 (anti-3)19 was a gift from
Dr Mark Ginsberg (Scripps Research Institute). The GP IIb/IIIa
complex-specific MoAb P2 was purchased from Immunotech (Hamburg,
Germany). The anti-P-selectin (anti-CD62P) MoAb (AK6) was purchased
from Dianova (Hamburg, Germany). The fluorescein isothiocyanate
(FITC)-labeled polyclonal chicken antifibrinogen antibody
was purchased from Biopool (Umeå, Sweden), the peptide GRGDSP from
Biomol (Hamburg, Germany), and flavorodin from Sigma (Deisenhofen,
Germany). Fradafiban was a gift from the Dr Karl Thomae GmbH (Biberach,
Germany).20 Human fibrinogen was purified from plasma as
described.8 c7E3 binding was evaluated with biotinylated
c7E3 and R-phycoerythrin-conjugated streptavidin (Dianova).
Biotinylation was performed with BAC-SulfoNHS (Sigma) at a pH of 7.2, resulting in a biotin/protein ratio of 1.6.
Flow cytometry for the detection of P2, c7E3, and fibrinogen binding
to GP IIb/IIIa as well as P-selectin expression on platelets.
Whole blood (1 µL) was diluted 1 to 50 in modified Tyrode's buffer
(150 mmol/L NaCl, 2.5 mmol/L KCl, 12 mmol/L NaHCO3, 2 mmol/L MgCl2, 2 mmol/L CaCl2, 1 mg/mL bovine
serum albumin [BSA], 1 mg/mL dextrose, pH 7.4) and
incubated with increasing concentrations of biotinylated c7E3 at room
temperature for 20 minutes, either without or with the addition of 20 µmol/L ADP. A second incubation was performed with
R-phycoerythrin-conjugated streptavidin (10 µg/mL; Dianova) at room
temperature for 20 minutes. Fibrinogen binding and P-selectin
expression was evaluated after dilution of whole blood as described
above and one incubation step with FITC-labeled polyclonal chicken
antifibrinogen Ab (10 µL) or FITC-labeled anti-P-selectin MoAb (5 µL), respectively. All samples were examined without
centrifugation or fixation on FACScan with Lysis II (both Becton
Dickinson, Mountain View, CA) software, gating platelets by forward/sideward scatter. Gates were established with an
FITC-anti-GP Ib MoAb (Immunotech).
After detachment by Trypsin-EDTA (GIBCO), the GP IIb/IIIa-expressing
CHO cells were washed twice in modified Tyrode's buffer. Three hundred
thousand cells per 50 µL modified Tyrode's buffer were then
incubated with biotinylated c7E3 (10 µg/mL) or FITC-conjugated MoAb
P2 (20 µg/mL) for 30 minutes at room temperature and examined on
FACScan.
Binding of fibrinogen to platelets and GP IIb/IIIa-expressing CHO
cells pretreated with various GP IIb/IIIa inhibitors.
The percentage of platelets demonstrating binding of fibrinogen was
measured by flow cytometry. The washout of GP IIb/IIIa inhibitors was
performed similarly to the method described by Du et al.13
Platelet-rich plasma (1 µL) was diluted 1 to 50 in modified Tyrode's
buffer and incubated for 30 minutes at room temperature with increasing
concentrations of various GP IIb/IIIa inhibitors. Mild fixation was
performed with 1% paraformaldehyde for 10 minutes at room temperature
by the addition of CellFIX (Becton Dickinson) at one tenth of the
sample volume. Then platelets were washed by dilution in 50 mL modified
Tyrode's buffer including fibrinogen at a final concentration of 3 g/L
for 10 minutes and by a following centrifugation step. Pellets were
resuspended in 50 µL modified Tyrode's buffer with fibrinogen at a
final concentration of 3 g/L, incubated for 30 minutes at
room temperature together with 10 µL FITC-labeled polyclonal chicken
antifibrinogen Ab, and analyzed on a FACScan. GP IIb/IIIa-expressing
CHO cells were detached and washed as described above. Three hundred
thousand cells per 50 µL modified Tyrode's buffer were incubated
with increasing concentrations of c7E3 or 2G12 for 30 minutes at room
temperature. Without fixation, the CHO cells were washed and analyzed
as described above for platelets.
Binding of fibrinogen to platelets induced by low concentrations of
c7E3.
Whole blood (1 µL) was diluted 1 to 50 in modified Tyrode's buffer
and coincubated with various concentrations of c7E3 and 10 µL
FITC-labeled polyclonal chicken antifibrinogen Ab for 30 minutes at
room temperature. Without fixation or washing step, fibrinogen binding
was evaluated as described above.
Purified human fibrinogen was radiolabeled with sodium
[125I]-iodide using the chloramine-T method (Amersham
International, Buckinghamshire, UK). Platelet-rich plasma was diluted
with modified Tyrode's buffer to a concentration of 150,000 platelets/µL. A total of 4.5 × 107 platelets per
sample were incubated with 125I-fibrinogen (10 nmol/L) and
various concentrations of c7E3 for 30 minutes at room temperature.
Samples were either preincubated with the MoAb P2 (20 µg/mL) or
without the addition. 125I-fibrinogen binding was evaluated
without further fixation or washing by a Gamma counter LB 2103 (Berthold, Germany). Fifty-microliter aliquots were layered in
quintuplets on 300 µL of 20% sucrose in modified Tyrode's buffer
and centrifuged for 3 minutes at 12,000 rpm. Counts associated with the
cell pellet were determined.
Binding of MoAbs directed against a ligand-induced binding site
(LIBS) on GP IIb/IIIa.
Whole blood (1 µL) was diluted l to 50 in modified Tyrode's buffer
and then incubated for 30 minutes at room temperature with 10 µg/mL
of MoAb anti-LIBS6 and with saturating concentrations of c7E3, GRGDSP,
or ADP (20 µmol/L) or without any addition. Cells were then fixed for
10 minutes at room temperature by the addition of CellFIX at one tenth
of the sample volume. To specifically stain the anti-LIBS MoAb, but not
c7E3, the pellet was resuspended after centrifugation in 50 µL
modified Tyrode's buffer containing 20 µg/mL of an
FITC-labeled, polyclonal Fc-fragment-specific antimouse goat Ab
(Dianova) that we proved did not bind to c7E3. After
another incubation of 30 minutes at room temperature, cells were
diluted in 300 µL modified Tyrode's buffer and evaluated as
described above. The fluorescence intensity of unspecific staining
after incubation with an unspecific MoAb and with the secondary MoAb (mean fluorescence, 33 ± 5 arbitrary units) was subtracted from the
evaluated specific mean fluorescence and the corrected value is given.
Aggregometry.
Aggregation of platelet-rich plasma was performed at a final volume of
220 µL after the addition of 20 µL of a 22 mmol/L CaCl2 and MgCl2 solution on a Bio/Data PAP4
aggregometer (Moelab, Hilden, Germany) with a stirring
rate of 1,000 rpm. As a positive control, aggregation was induced by 20 µmol/L ADP. Platelet-rich plasma was preincubated with either 100 µg/mL aspirin, 10 µmol/L indomethacin, 100 nmol/L prostaglandin
I2 (PGI2), 20 µg/mL MoAb P2, or
no addition for 15 minutes at room temperature. Incubation with 0.1 µg/mL c7E3, 10 µg/mL anti-LIBS6, or 0.1 µg/mL P2 was then
performed for 30 minutes at room temperature. No stimulation (except
for the positive control) and no fixation of platelets were performed.
| |
RESULTS |
c7E3 binds to the activated and nonactivated GP IIb/IIIa.
Because binding of the ligand fibrinogen and the ligand-mimetic peptide
RGD can induce a conformational change of GP IIb/IIIa,10-14 we hypothesized that the GP IIb/IIIa inhibitor, c7E3, by imitating a
ligand, can also induce a conformational change. For this hypothesis, the binding of c7E3 at the low-affinity (nonactivated) GP IIb/IIIa is a
precondition. Therefore, the binding of c7E3 to resting and activated
platelets was evaluated by flow cytometry. In fact, steady-state
binding of biotinylated c7E3 to activated platelets is only slightly
higher than that to resting platelets (Fig
1A). The activation status of platelets was affirmed by the expression of P-selectin and the binding of fibrinogen as evaluated in flow cytometry (Fig 1B and C). In those experiments with platelets, two
variables make a cautious interpretation necessary. First, the number
of the surface-exposed GP IIb/IIIa receptors can increase upon platelet
activation. Second, platelets are potentially activated by the
experimental procedure, and it cannot be excluded that the resting
platelets are partially activated. To avoid these problems, two
genetically engineered CHO cell lines expressing similar amounts of GP
IIb/IIIa receptors (see Fig 1E), either in an activated or nonactivated
state, were used as a model with clearly defined activation status of
GP IIb/IIIa.15,16 In the comparison of the two cell lines,
c7E3 binds similarly to activated and to nonactivated GP IIb/IIIa (Fig
1D).
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| Fig 1.
Flow cytometric comparison of c7E3 and fibrinogen binding
as well as P-selectin expression on resting and activated platelets and
evaluation of the expression level and c7E3 binding of CHO cells
transfected with recombinant GP IIb/IIIa, either in the activated or
nonactivated state. (A) Binding of various concentrations of
biotinylated c7E3 to ADP-stimulated and resting platelets are expressed
as the mean ± standard deviation of three determinations. (B)
Histogram of FITC-conjugated anti-P-selectin MoAb binding to
ADP-stimulated and resting platelets. (C) Histogram of FITC-conjugated
polyclonal antifibrinogen chicken Ab binding to ADP-stimulated and
resting platelets. (D) Binding of biotinylated c7E3 to CHO cells
expressing no, activated, or nonactivated GP IIb/IIIa. Results are
expressed as the mean ± standard deviation of three determinations.
(E) Histograms of FITC-conjugated MoAb P2 (anticomplex GP IIb/IIIa)
with GP IIb/IIIa (in the activated and nonactivated state) expressing
CHO cell lines, together with CHO cells as a negative control. Typical
histograms of several determinations are depicted.
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c7E3 induces high-affinity binding of fibrinogen to GP IIb/IIIa, in
contrast to the MoAbs 2G12, P2, and PAC-1.
Receptor activating properties of inhibitors are primarily masked by
the blockade of the receptor. Therefore, c7E3 was released by washing
in modified Tyrode's buffer. This washout of c7E3 was demonstrated in
flow cytometry by evaluation of the remaining MoAb binding after the
washout procedure (Fig 2A; shown for the incubation with 1 µg/mL c7E3). The specificity of c7E3 binding was
evaluated by the competition in binding with the GP IIb/IIIa-blocking MoAb P2.
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| Fig 2.
c7E3 binding before and after washout procedure and
fibrinogen (fg) binding to unstimulated platelets after incubation with
various GP IIb/IIIa inhibitors and following washout. (A) Initially
bound biotinylated-c7E3 (solid line) and the remaining c7E3 binding
after washout procedure (dashed line) as detected by
R-phycoerythrin-conjugated streptavidin. Biotinylated unspecific Fab
was used as negative control (pointed line). (B) Typical flow
cytometric histogram of fg binding without c7E3 and after incubation
with c7E3 and following washout. The marker that is used to determine
the percentage of cells binding fg is shown. Platelets were incubated
with increasing concentrations of GRGDSP (C ), c7E3 (D), 7E3 IgG (E),
P2 (F), or PAC-1 (G) and then fixed and washed as described in
Materials and Methods. After incubation with fibrinogen solution (3 g/L), fibrinogen binding was measured with an FITC-labeled polyclonal
chicken antifibrinogen antibody in flow cytometry. The results are
expressed as the percentage of platelets binding fibrinogen as the mean ± standard deviation of five determinations.
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Fibrinogen binding was measured by an FITC-labeled chicken
antifibrinogen MoAb in flow cytometry and expressed as percentage of
cells binding fibrinogen. A marker region in the histograms depicting
platelet fibrinogen binding was defined, allowing maximally 4% of
nonstimulated platelets to be in the positive range (shown in Fig 2B).
A similar increase in fibrinogen binding can be demonstrated by the
measurement of mean fluorescence intensity (data not shown). Incubation
of resting platelets with the peptide GRGDSP and a following washout
resulted in a concentration-dependent binding of fibrinogen to GP
IIb/IIIa (Fig 2C). Incubation with c7E3 and a following washout induced
fibrinogen binding to GP IIb/IIIa (Fig 2D). Thus, c7E3 exhibits a
similar intrinsic activating property as RGD peptides. Because the
molecular size of ligands may determine potential intrinsic activating
properties, the F(ab)2 fragment and the whole IgG
MoAb of 7E3 were used in the washout experiments described above. For
both, the same activating property on GP IIb/IIIa could be demonstrated
(depicted for IgG in Fig 2E). Thus, even large molecules with around
150 kD can induce a conformational change of GP IIb/IIIa. To prove
whether the intrinsic activating effect is a general property of GP
IIb/IIIa-blocking MoAbs, additional blocking MoAbs were evaluated. For
the blocking MoAbs 2G12 and P2, no intrinsic activating property could
be demonstrated (depicted for P2 in Fig 2F). Nevertheless, similar to
c7E3, a washout of these MoAbs could be demonstrated in flow cytometry.
After incubation with 1 µg/mL and the washout procedure, only 35% ± 3.8% of the originally occupied GP IIb/IIIa receptors for 2G12
and 29.2% ± 4.46% for P2 demonstrated remaining binding of these
MoAbs. Differences in epitopes on GP IIb/IIIa of these two MoAbs
compared with 7E3 may explain these contrasting findings.
The antibody PAC-1 is described as an activation-specific MoAb directed
against GP IIb/IIIa that does not bind to the nonactivated GP
IIb/IIIa.18,21 PAC-1 seems to bind in the
fibrinogen-binding pocket of activated GP IIb/IIIa and thus to directly
mimic soluble fibrinogen.21 There was no binding of PAC-1
to nonactivated GP IIb/IIIa on platelets or on CHO cells (data not
shown) and no induction of fibrinogen binding by PAC-1 (Fig 2G). Thus,
PAC-1 demonstrates no intrinsic activating property.
To exclude the possibility of a conformational change of GP
IIb/IIIa by a general activation of platelets caused by c7E3 and thus to assure a direct effect of c7E3 on the GP IIb/IIIa receptor, a
CHO cell line that expresses nonactivated GP IIb/IIIa was
used as a model system. In these CHO cells, recombinant GP IIb/IIIa is
not activatable by intracellular signals.17 Thus, an
indirect effect that is not caused by a direct interaction between c7E3 and GP IIb/IIIa is not to be expected. Furthermore, in contrast to
platelets, these cells can be centrifuged and washed without the risk
of activating GP IIb/IIIa. Therefore, for the performed washout
experiment, no fixation of these cells was necessary. Nevertheless,
recombinant GP IIb/IIIa expressed by these cells is functional and can
be activated to bind fibrinogen by activating anti-LIBS
MoAbs.17 Thus, CHO cells expressing recombinant GP IIb/IIIa
are an appropriate tool to check the hypothesis of whether GP IIb/IIIa
inhibitors exert an activating effect on GP IIb/IIIa. After incubation
with c7E3 and washout, fibrinogen binding on GP IIb/IIIa-expressing CHO
cells could be detected by flow cytometry (Fig 3A). As control, 2G12 did not induce
fibrinogen binding to GP IIb/IIIa (Fig 3B).
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| Fig 3.
Fibrinogen (fg) binding to CHO cells expressing
wild-type, nonactivated GP IIb/IIIa after incubation with c7E3 (A) or
anti-GP IIb/IIIa MoAb 2G12 (B) and following washout. Experiments were
performed as described in Fig 2 and in Materials and Methods.
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Detection of c7E3-induced conformational change of
GP IIb/IIIa by MoAb anti-LIBS6.
LIBS on GP IIb/IIIa are more accessible for anti-LIBS MoAbs after
binding of the ligand fibrinogen or the ligand-mimetic peptide RGD.10,11,19 Incubation of platelets with c7E3 also induce an increase in anti-LIBS6 MoAb binding, which is small but
statistically significant and which is similar in extent after
incubation with ADP and RGD peptides (Fig
4). This finding is consistent with a conformational change of GP
IIb/IIIa induced by c7E3. For other anti-LIBS MoAbs, anti-LIBS1 and
PMI-1, an increase in binding to GP IIb/IIIa induced by c7E3 has
been demonstrated as well (Dr Meinrad Gawaz, Munich, Germany, personal
communication, November 6, 1997).
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| Fig 4.
Binding of MoAb anti-LIBS6 (10 µg/mL) induced by ADP
(20 µmol/L), c7E3 (10 µg/mL), and GRGDSP (2 mmol/L) or no addition.
Binding of MoAb anti-LIBS6 was detected by an FITC-labeled, polyclonal
Fc-fragment-specific anti-IgG mouse Ab. Background binding with
unspecific MoAb has been subtracted. Results are depicted as the mean
of three determinations ± standard deviation. Using the unpaired
Student's t-test, P values less than .02 were obtained
for comparisons between no addition and the addition of ADP, c7E3, and
GRGDSP, respectively.
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At low concentrations of c7E3, the intrinsic activating effect is
strongest relative to the blocking effect.
If c7E3 has an intrinsic activating property, the effect on fibrinogen
binding is expected to be strongest, relative to the blocking effect,
at low concentrations. Compared with the number of GP IIb/IIIa
receptors, only a limited number of c7E3 is present. If c7E3
dissociates from a receptor, the probability that this receptor is not
again occupied and thus blocked by another c7E3 molecule is higher at
low concentrations of c7E3. Thus, the intrinsic activating effect of
c7E3 may be unmasked at low concentrations. During incubation with
increasing concentrations of c7E3 with no fixation of platelets and no
washout of c7E3, fibrinogen binding of resting platelets was evaluated
in flow cytometry and with 125I-labeled fibrinogen
(Fig 5). At low concentrations (0.01 to 0.1 µg/mL) of c7E3, fibrinogen binding on platelets increased
significantly. With higher concentrations of c7E3 ( 1 µg/mL),
fibrinogen binding on resting platelets decreased. The effective
blockade of the c7E3-induced fibrinogen binding by MoAb P2 demonstrates
a specificity of this effect for GP IIb/IIIa. Overall, at low
concentrations of c7E3, the activating property of this GP IIb/IIIa
inhibitor is unmasked.
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| Fig 5.
Evaluation of fibrinogen (fg) binding in flow cytometry
(A) and with 125I-fibrinogen (B) at various concentrations
of c7E3 without washout procedure. (A) The percentage of platelets
binding fibrinogen was assessed by an FITC-labeled polyclonal chicken
antifibrinogen antibody in flow cytometry. (B)
125I-fibrinogen was determined as described in Materials
and Methods in relation to the maximum binding by stimulation of
platelets with 20 µmol/L ADP. The MoAb P2 (20 µg/mL) was
preincubated for 10 minutes at room temperature. Results are depicted
as the mean of five determinations ± standard deviation. Using the
unpaired Student's t-test, P values less than .01 were
obtained for the comparisons between no addition of c7E3 and the
additions of 0.01 and 0.1 µg/mL c7E3.
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Low concentrations of c7E3 result in platelet aggregation.
To evaluate the functional consequence of fibrinogen binding at low
c7E3 concentrations, aggregometry was performed with resting platelets.
At a concentration of 0.1 µg/mL, c7E3 induces platelet aggregation
(Fig 6). Whereas no addition or the
incubation with MoAb P2 at 0.1 µg/mL did not induce platelet
aggregation (Fig 6; representative examples of aggregation curves are
shown in Fig 8). Aggregation induced by a low concentration of c7E3
could be blocked by the preincubation of platelets with 20 µg/mL of the GP IIb/IIIa-specific MoAb P2 (see Fig 8).
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| Fig 6.
Platelet aggregation after incubation of unstimulated
platelets with a low concentration (0.1 µg/mL) of c7E3 or P2 (anti-GP
IIb/IIIa MoAb) or without addition. The bar graphs show mean maximal
aggregation of 10 measurements ± standard deviations. P
value was evaluated with the unpaired Student's t-test.
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Flavoridin as a disintegrin, and fradafiban as a RGD-analogue
demonstrate an intrinsic activating property.
The snake venom flavorodin, as a member of the disintegrin group,
inhibits GP IIb/ IIIa.22 Disintegrins contain a RGD
sequence or a sequence similar to RGD and can bind to GP IIb/IIIa on
unstimulated platelets.23 Thus, an intrinsic activating
property of these proteins can be expected. Incubation with increasing
concentrations of flavorodin and the following washout resulted in
fibrinogen binding to platelets (Fig 7A).
As an example for RGD analogues, fradafiban20 was evaluated
in a similar experimental set-up. Again, a conformational change of the
GP IIb/IIIa could be demonstrated (Fig 7B). Thus, both flavorodin and
fradafiban demonstrate an intrinsic activating property.
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| Fig 7.
Fibrinogen (fg) binding to unstimulated platelets after
incubation with flavorodin as an example for a disintegrin (A) and
fradafiban as an example for a RGD analogue (B) and a following
washout. For the experimental procedure, see Fig 2 and Materials and
Methods.
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Aspirin does not inhibit c7E3-induced fibrinogen binding to GP
IIb/IIIa, but does inhibit c7E3-induced platelet aggregation.
In clinical trials, c7E3 most often is combined with heparin and
aspirin.2,4,5 Therefore, c7E3-induced fibrinogen binding and platelet aggregation were evaluated under coincubation with both
drugs. Heparin does not influence c7E3-induced fibrinogen binding or
platelet aggregation (data not shown). Incubation with c7E3 in the
presence of aspirin (100 µg/mL) and the following washout of the MoAb
fragment did not alter c7E3-induced fibrinogen binding to platelets
(data not shown). In contrast, c7E3-induced platelet aggregation could
be inhibited by coincubation with aspirin (Fig 8). Additionally to aspirin, another
cyclooxygenase inhibitor, indomethacin (10 µmol/L), caused inhibition
of c7E3-induced platelet aggregation (Fig 8). The same inhibiting
effect could be demonstrated for PGI2 (100 nmol/L; Fig 8).
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| Fig 8.
Platelet aggregation tracings starting with the addition
of CaCl2 and MgCl2 to a final concentration of
2 mmol/L to platelet-rich plasma, either without addition, with
incubation with 20 µmol/L ADP (as positive control), or with 0.1 µg/mL c7E3. c7E3 samples were additionally preincubated
with either 100 µg/mL aspirin, 10 µmol/L indomethacin, 100 nmol/L
PGI2, or 20 µg/mL MoAb P2. Representative tracings of
several experiments as determined by increase of light transmission in
a Bio/Data PAP4 aggregometer are depicted.
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Aspirin inhibits platelet aggregation induced by an activating
anti-LIBS MoAb.
Anti-LIBS MoAbs induce conformational changes of GP IIb/IIIa resulting
in high-affinity binding of ligands. In their effect to cause a
conformational change by interaction with the extracellular side of GP
IIb/IIIa, anti-LIBS MoAbs can be compared with c7E3. Indeed,
preincubation with aspirin inhibits anti-LIBS6-induced platelet
aggregation (Fig 9). Thus, aspirin showed
the same inhibitory effect on anti-LIBS-induced as on c7E3-induced
platelet aggregation.
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| Fig 9.
Anti-LIBS6-induced platelet aggregation is inhibited by
aspirin. Platelet aggregation tracings start with the addition of
CaCl2 and MgCl2 at a final concentration of 2 mmol/L to platelet-rich plasma. Aggregation is induced by addition of
anti-LIBS6 to a final concentration of 10 µg/mL. Preincubation was
performed with 100 µg/mL aspirin, 20 µg/mL MoAb P2, or no addition.
Aggregation was determined by increase of light transmission in a
Bio/Data PAP4 aggregometer. Representative tracings of several
experiments are depicted.
|
|
| |
DISCUSSION |
The major findings of this study are as follows. (1) The mouse/human
chimeric Fab fragment c7E3 induces a conformational change of the
platelet integrin GP IIb/IIIa. (2) c7E3 exhibits an intrinsic activating property that at low concentrations of c7E3 results in
fibrinogen binding to GP IIb/IIIa. (3) As a functional consequence, c7E3 induces platelet aggregation at low concentrations and blocks platelet aggregation at high concentrations. (4) The GP
IIb/IIIa-blocking MoAbs P2 and 2G12 and the activation-specific,
anti-GP IIb/IIIa MoAb PAC-1 do not exhibit an intrinsic activating
property. (5) The disintegrin flavorodin and the RGD analogue
fradafiban also induce fibrinogen binding to GP IIb/IIIa. (6) Aspirin
and indomethacin cannot inhibit c7E3-induced fibrinogen binding to GP
IIb/IIIa, but can inhibit c7E3-induced platelet aggregation.
A potential explanation of our findings is shown in
Fig 10. c7E3 binding to nonactivated GP
IIb/IIIa results in a conformational change of GP IIb/IIIa. After
dissociation of c7E3, GP IIb/IIIa is unblocked and left in an
activated state, able to bind soluble fibrinogen. We could demonstrate
that c7E3 binds to nonactivated GP IIb/IIIa on platelets and on CHO
cells. Binding of the intact IgG, F(ab)2, and
Fab of 7E3 to resting platelets has been
demonstrated.24,25 Furthermore, in several animal studies
and clinical trials, a blockade of nonactivated GP IIb/IIIa by 7E3 is
documented.2,4,5,26 Nevertheless, the combination of three
binding characteristics of c7E3 implies a binding at or close to the
fibrinogen binding pocket on GP IIb/IIIa. (1) The MoAb 7E3 exhibits an
enhancend on-rate of binding to GP IIb/IIIa on activated compared with
resting platelets.24,27 (2) 7E3 competes with fibrinogen
for the binding to GP IIb/IIIa.3,5 (3) As evaluated in the
present study, c7E3 has the intrinsic property to induce a
conformational change of GP IIb/IIIa. This potential property of c7E3
has been hypothetically discussed5,36 but has not been
demonstrated until now. For the MoAb OP-G2, similar binding
characteristics as for c7E3 could be demonstrated; interestingly, this
antibody can also induce a conformational change of GP IIb/IIIa as
detected with an anti-LIBS MoAb (PMI-1).28
Other MoAbs that block fibrinogen binding are expected to have epitopes
outside the fibrinogen-binding pocket. For two of those blocking MoAbs,
2G12 and P2, we could demonstrate that they cannot induce binding of
fibrinogen. MoAbs with these properties may provide an alternative
basis for GP IIb/IIIa blocking drugs. An even more interesting
alternative is MoAbs such as PAC-1. This MoAb is activation-dependent
and does not bind to the nonactivated GP IIb/IIIa.18,21
Therefore, as we could demonstrate, MoAb PAC-1 does not induce
fibrinogen binding. Furthermore, because resting platelets are not
blocked, GP IIb/IIIa-mediated adhesion of resting platelets on
immobilized fibrinogen may still be possible. Thereby, if MoAbs with
features such as PAC-1 could be used for clinical applications, no
intrinsic activating effect and possibly less bleeding compared with
c7E3 might be present.
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| Fig 10.
Schematic drawing of the proposed intrinsic activating
property of c7E3: Induction of fibrinogen binding to GPIIb/IIIa.
|
|
In this study, we describe the use of two CHO cell lines expressing
either a nonactivated or an activated GP IIb/IIIa. Because it has been
proven that the expression of recombinant GP IIb/IIIa results in a
funtional receptor,17 both cell lines have been used for
various functional studies.15,16 Using the CHO cell line
with nonactivated GP IIb/IIIa, affinity regulation29 and interaction with the cytoskeleton30 have been studied. Du
et al13 used the same GP IIb/IIIa-expressing CHO cell line
to demonstrate the activating effect of RGD peptides on GP IIb/IIIa.
The CHO cell line with activated GP IIb/IIIa has been instrumental for the evaluation of the role of integrin affinity and cytoskeletal anchorage in IIb3-mediated fibrinogen
binding,16 cell adhesion,15 cell
migration,31 and fibronectin matrix assembly.32
Experiments with platelets are very often hampered by the fact that
they are easily activated by the preparatory procedure. Furthermore,
for many drugs it may be difficult to dissect general effects on
platelets from isolated effects on GP IIb/IIIa. Therefore, our study
may serve as an example for the direct evaluation of drug effects on
the GP IIb/IIIa receptor, using recombinant GP IIb/IIIa.
Aspirin was not able to inhibit c7E3-induced fibrinogen binding to GP
IIb/IIIa. Nevertheless, c7E3-induced platelet aggregation was inhibited
by aspirin. This effect may be cyclooxygenase-dependent, because
another cyclooxygenase inhibitor, indomethacin, also demonstrates similar inhibiton. Furthermore, PGI2 was able to inhibit
c7E3-induced platelet aggregation. Anti-LIBS MoAbs-induced platelet
aggregation is inhibited by indomethacin and aspirin, as shown by us
(Fig 9) and others.19 For anti-LIBS MoAbs, as with c7E3,
the conformational change of GP IIb/IIIa originates in the
extracellular domain of the integrin. Cyclooxygenase inhibitors may
modulate postreceptor effects such as changes in the cytoskeletal
anchorage of GP IIb/IIIa or in the cytoskeletal organizaton
itself.33 Further studies are needed to define the role of
cyclooxygenase in GP IIb/IIIa inhibitor-induced platelet aggregation.
The data presented in this study are based on in vitro experiments and
do not prove clinical relevance of the described intrinsic activating
property of GP IIb/IIIa inhibitors. In vivo data from patients treated
with c7E3 showed a transfer of c7E3 from initially occupied GP IIb/IIIa
to GP IIb/IIIa of those platelets newly released into the
circulation.34 This gradual recovery of c7E3 blockade for
each platelet can be detected in flow cytometry in an unimodal decrease
in c7E3 binding of the whole circulating platelet
population.5,34 Therefore, GP IIb/IIIa receptors with a
history of c7E3 occupancy and after dissociation are
present5 and, thus, according to our findings, could
demonstrate fibrinogen binding. Nevertheless, proaggregatory effects of
GP IIb/IIIa inhibitors have not been seen or at least have not been
reported yet. Several reasons may account for this. (1) Most patients
treated with GP IIb/IIIa inhibitors did also receive aspirin. This
comedication may have prevented a proaggregatory effect. (2) The
c7E3-induced aggregation may not have the same properties as platelet
aggregation induced in vivo by physiological platelet agonists. In the
aggregation curves, the time at which maximal aggregation is reached
and the maximal slope are different as compared for example with
ADP-induced platelet aggregation. Similar differences in comparison to
ADP-induced platelet aggregation are reported for
anti-LIBS3-induced19 and RGDS-peptide-induced14 platelet aggregation. Thus, the
stability of c7E3-induced aggregates may differ from regular platelet
aggregates. (3) The number of GP IIb/IIIa receptors per platelet that
are left in an activated state after dissociation of the GP IIb/IIIa inhibitors may be too low to result in stable aggregates. (4) The
activation of GP IIb/IIIa may result in platelet adhesion to
the endothelium and/or in sequestration within the spleen. A
decrease in platelet count has been seen in many patients treated with
GP IIb/IIIa inhibitors, even in those without bleeding
complications.5,35,36 In two recent
reviews,5,36 the induction of potentially allergenic neoepitopes (LIBS) on GP IIb/IIIa by a conformational change caused by
the binding of GP IIb/IIIa antagonists are discussed as a potential reason for thrombocytopenia. Until now, there is no proven explanation for thrombocytopenia induced by GP IIb/IIIa inhibitors.5,36
Three groups of GP IIb/IIIa inhibitors are under investigation as
therapeutics2-5: (1) GP IIb/IIIa blocking MoAbs, (2) short
peptides originating from disintegrins of snake venoms that mostly
contain RGD or KGD sequences, and (3) RGD/KGD analogues that are
modeled according to the structure of RGD/KGD peptides. For members of
all three groups, we could demonstrate an intrinsic activating
property. Because disintegrins and also RGD/KGD analogues are
ligand-mimetics, the same mechanism for change in conformation of GP
IIb/IIIa, as shown in Fig 10, can be postulated. In fact, the
disintegrins eristostatin and echistatin caused an increase in
anti-LIBS MoAb binding37 and tetrafibricin, a nonpeptide GP
IIb/IIIa inhibitor, transformed GP IIb/IIIa in a high-affinity state
for fibrinogen and could induce platelet aggregation.38
Nevertheless, there may also be members of the group of disintegrins
(or short peptides derived from disintegrins) and RGD/KGD analogues (as
there are also blocking MoAbs) that block GP IIb/IIIa but do not
exhibit an intrinsic activating property. For example,
anti-LIBS and washout experiments with pentamidine would suggest that
this nonpeptide agent inhibits fibrinogen binding to GP IIb/IIIa
without an intrinsic activating effect.39 Our description
of an intrinsic activating property of various GP IIb/IIIa inhibitors
may initiate a systematic evaluation of the large number of different
GP IIb/IIIa inhibitors that are presently available or in development.
| |
FOOTNOTES |
Submitted November 25, 1996;
accepted June 18, 1998.
Supported by the German Research Foundation with a grant to K.P. and
C.B. (SFB 320: C/3) and by a cooperation grant of the DAAD (Deutscher
Akademischer Austauschdienst) and the Academy of Finland to K.P. and
J.Y.
Presented in part at the American Heart Association Meeting 1997, Orlando, FL (Circulation 96:I-664, 1997).
Address reprint requests to Karlheinz Peter, MD, Innere Medizin III,
Universität Heidelberg, Bergheimer Str. 58, 69115 Heidelberg, Germany; e-mail: kpeter{at}ukl.uni-heidelberg.de.
The publication costs of this article were defrayed in part by page charge payment. This article must therefore be hereby marked "advertisement" is accordance with 18 U.S.C. section 1734 solely to indicate this fact.
| |
ACKNOWLEDGMENT |
The authors thank Dr Timothy E. O'Toole and Dr Mark H. Ginsberg for
their support and Dr Meinrad Gawaz for unpublished data. The expert
technical assistance of Simone Bauer, Petra Jung, and Dr Siegfried Lang
is gratefully acknowledged.
| |
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Abstract