From the Division of Biopharmaceutics,
Leiden/Amsterdam Center for Drug Research, Leiden
University, Gorlaeus Laboratories, 2300 RA Leiden, The Netherlands
and the ¶ Center for Molecular and Vascular Biology,
University of Leuven, Herestraat 49, B-3000 Leuven, Belgium
Received for publication, September 10, 2002, and in revised form, December 31, 2002
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ABSTRACT |
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P-selectin plays an important role in the
development of various diseases, including atherosclerosis and
thrombosis. In our laboratory we recently identified a number of
specific human P-selectin-binding peptides containing a
Glu-Trp-Val-Asp-Val consensus motif, displaying a low micromolar
affinity for P-selectin (IC50 = 2 µM).
In search of more potent antagonists for P-selectin, we have optimized
the EWVDV pentapeptide core motif via a two-step combinatorial
chemistry approach. A dedicated library of peptide derivatives was
generated by introducing seven substituents at the N and C termini of
the motif. In particular, pentapeptides with gallic acid or
1,3,5-benzenetricarboxylic acid substituents at the N terminus proved
to be considerably more potent inhibitors of P-selectin binding than
the parental peptide. After removal of the N-terminal glutamic acid
from the core sequence, which appeared to be replaceable by a
carboxamide function without loss of affinity, a second library was
synthesized to map the chemical moieties within the gallic acid or
1,3,5-benzenetricarboxyl acid groups responsible for the enhanced
P-selectin binding. Moreover, by varying the length and rigidity of the
connective spacer, we have further optimized the spatial orientation of
the N-terminal substituent. The combined use of phage display and
subsequent combinatorial chemistry led to the design of a number of
gallic acid- containing peptides with low nanomolar affinity for
P-selectin both under static and dynamic conditions
(IC50 = 15.4 nM). These small synthetic
antagonists, which are equally as potent as the natural ligand
P-selectin glycoprotein ligand-1, are promising leads in
anti-atherothrombotic therapy.
P-selectin, a cell adhesion molecule involved in the initial
attachment and "rolling" of leukocytes across the inflamed vessel wall (1-4), plays a key role in atherosclerosis. In fact, P-selectin deficiency in mice has been shown to reduce atherosclerotic lesion formation (5). Also, P-selectin activation induces hypercoagulance of
platelets and mediates platelet-monocyte aggregation and has thus been
associated with thrombosis (6-9). Therefore, intervention in
P-selectin-mediated processes is an attractive therapeutic entry.
The endogenous ligand for P-selectin is P-selectin glycoprotein
ligand-1 (PSGL-1),1 a 220-kDa
disulfide-linked homodimeric sialomucin (10). P-selectin binding to
PSGL-1 proceeds via a short N-terminal amino acid sequence of the
latter, containing three sulfated tyrosines and a sialyl Lewis X (sLeX,
Neu5Ac In our lab we recently identified, through the use of phage display, a
number of human P-selectin-binding peptides containing an EWVDV
pentapeptide consensus motif (16). Binding of these peptides to human
P-selectin was calcium-dependent and highly specific over
E- and L-selectin. With its IC50 of 8 µM, the
stripped pentapeptide already appeared to be much more potent than most of the sLeX-derived carbohydrate ligands. For therapeutic purposes, however, the affinity of an antagonist has to be in the low nanomolar range. We obtained this affinity by tetrameric exposure of the EWVDV
peptide on streptavidin (IC50 = 2 nM). However,
streptavidin-peptide complexes are rather inadequate for in
vivo use, and smaller synthetic leads are pharmaceutically much
more interesting. For this reason an optimization of the core sequence
was performed.
In this paper, we describe the rational design of potent monomeric
P-selectin antagonists using a combinatorial chemistry strategy with
the consensus motif (E)WVDV as core sequence. A structure-activity
study yielded a number of peptide derivatives that are equally as
potent as the natural ligand PSGL-1.
Materials--
Fmoc protected amino acids, 1-hydroxybezotriazole
(HOBt), 2-(1H-benzotriazole-1-yl)-1,1,3,3-tetramethyluronium
tetrafluoroborate (TBTU),
benzotriazol-1-yloxytris(dimethylamino)phosphonium hexafluorophosphate (BOP), and 4-hydroxymethylphenoxyacetic acid (HMPA) were
purchased from Nova Biochem (Läufelingen, Switzerland),
except Fmoc-4-aminobenzoic acid, Fmoc-(4-aminomethyl)-benzoic acid, and
Fmoc-tranexamic acid, which were from Neosystem (Strasbourg, France).
Trifluoroacetic acid, N,N-diisopropylethylamine
(Dipea), dichloromethane, dichloroethane, N,N-dimethylformamide (DMF), piperidine,
and 1-methyl-2-pyrrolidine were of peptide grade and purchased from
Biosolve (Valkenswaard, The Netherlands). 4-Dimethylaminopyridine
was obtained from Janssen (Beersse, Belgium).
N,N'-dicyclohexylcarbodiimide, hydrazine
monohydrate, and all of the carboxylic acids were obtained from
Acros (Hertogenbosch, The Netherlands). N-Methylmorpholine
was obtained from Fluka (Buchs, Switzerland). Tentagel
S-NH2 (0.26 mmol/g) was from Rapp Polymer (Tübingen,
Germany). Triisopropylsilane, goat anti-human IgG (Fc-specific), and
bovine serum albumin were from Sigma-Aldrich. TM11-biotin
(biotin-CDVEWVDVSSLEWDLPC) was synthesized by Dr. Van der Zee
(Department of Immunology, Utrecht, The Netherlands). Human
P-selectin/IgG-Fc and human E-selectin/IgG-Fc chimeras were kindly
provided by Drs. Appelmelk and Van Dijk (Free University of Amsterdam,
Amsterdam, The Netherlands). Human L-selectin and mouse P-selectin were
purchased by R&D Systems Europe, Ltd. (Abingdon, UK). Streptavidin
peroxidase was obtained from Amersham Biosciences, and
biotin-PAA-Lea-SO3H was from Synthesome
(München, Germany).
3,3',5,5'-Tetramethylbenzine/H2O2 was obtained
from Pierce. RPMI 1640 medium, Dulbecco's modified Eagle's medium,
fetal calf serum, and penicillin/streptomycin were obtained from
BioWhittaker Europe (Verviers, Belgium).
Chemical Synthesis of Resin-bound Core Sequence
9--
Core sequence 9 FmocHN-Glu(OtBu)-Trp(Boc)-Val-Asp(OtBu)-Val-Lys(DDE)- Synthesis of Library 10--
The solid phase synthesis of
library 10 was performed using a Flexchem© system (Robbins
Scientific). After removal of the N-terminal Fmoc group of sequence 9 by 20% piperidine in DMF, the resin was washed (in DMF) and dried. The
resin was distributed in 10-mg quantities over a solvent-resistant
48-well filter plate. After washing with DMF, a mixture of the desired
carboxylic acid (40 eq), BOP (20 eq), HOBt (20 eq), and
N-methylmorpholine (100 eq) was added (total volume, 300 µl), and the suspended resin was incubated for 3 h.
Subsequently, the resin was washed with DMF and incubated three times
for 3 min with hydrazine monohydrate (2% in DMF) to remove the DDE
group. After washing with DMF, a mixture of the second carboxylic acid,
BOP, HOBt, and N-methylmorpholine (same amounts as described
above) was added and once again incubated for 3 h. Peptides, which
were only modified at the C-terminal lysine (peptides HP01-HP07), were
first N-bocylated with di-tert-butyl-dicarbonate (0.25 M) and Dipea (0.125 M) in
1-methyl-2-pyrrolidine to protect the N-terminal amine function. After
removal of the solvent, the peptides were cleaved off from the resin
with a trifluoroacetic acid, triisopropylsilane, and water mixture
(95:2.5:2.5, v/v/v). Each sample was lyophilized and stored at
Synthesis of Peptides 11-13, Library 14, and Peptides
27-33--
Peptides 11-13, library 14, and peptides 27-33 were
prepared in the same manner as described for library 10 from resin
bound core sequence FmocHN-Trp(Boc)-Val-Asp(OtBu)-Val-HMPA-resin.
Peptide 11 was acetylated using acetic anhydride (0.25 M)
and Dipea (0.125 M) in 1-methyl-2-pyrrolidine.
Preparation of Samples and Determination of Peptide
Concentration--
Lyophilized peptides were dissolved in ammonia (100 mM, 100 µl) and aqueous ammonium bicarbonate solution (5 mM, 400 µl). The peptide concentration was determined
spectrophotometrically at 280 nm (tryptophan; Competition Assay with TM11-PO or
Biotin-PAA-Lea-SO3--
The peptides were
assayed for their ability to inhibit TM11-PO binding to human
P-selectin (16) or biotin-PAA-Lea-SO3H binding
to human and mouse P-selectin and human E- and L-selectin (17).
TM11-PO, a tetrameric TM11/streptavidin peroxidase complex, were
freshly prepared by incubating streptavidin peroxidase (8.4 µl, 2.0 µM) and TM11-biotin (biotin-CDVEWVDVSSLEWDLPC, 1.5 µl, 190 mM) for 2 h at room temperature in assay buffer.
For competition studies, a 96-well microtiter plate (high binding, flat
bottom; Costar, Corning, NY) was coated overnight at 4 °C with 10 µg/ml goat anti-human IgG in coating buffer (50 mM
NaHCO3, pH 9.6). Subsequently, the wells were washed with
assay buffer (20 mM HEPES, 150 mM NaCl, 1 mM CaCl2, pH 7.4) and incubated for 1 h at
37 °C with blocking buffer (3% bovine serum albumin in assay
buffer). After washing with assay buffer, the wells were incubated for 2 h at 37 °C with human P-selectin/IgG-Fc (0.3 µg/ml).
Subsequently, the wells were washed with assay buffer and incubated for
1 h at 4 °C with the TM11-PO complex or
biotin-PAA-Lea-SO3. The wells were washed six
times with washing buffer (0.1% Tween 20 in assay buffer).
3,3',5,5'-Tetramethylbenzine/H2O2 was added,
and the wells were incubated at room temperature for 15 min. The
reaction was halted by the addition of 2 M
H2SO4, and the absorbance was measured at 450 nm.
HL60 Adhesion Assay--
HL60 cells were fluorescently labeled
by incubation for 30 min at 37 °C with 5 µM
calcein-AM (Molecular Probes, Leiden, The Netherlands) in RPMI.
These cells (50,000/well) were added to cultured CHO cells expressing
P-selectin (CHO-P cells, cultured in Dulbecco's modified Eagle's
medium with 10% fetal calf serum, 5 mM nonessential amino
acids, 5 mM L-glutamine, and 20,000 units of
penicillin/streptomycin), seeded in 96-well plates in the presence or
absence of the P-selectin antagonists (1h, 4 °C) (16). After gentle
washing with RPMI, CHO-P-associated fluorescence was measured ( Flow Chamber and Perfusion Studies--
Dynamic interactions
between HL60 cells and CHO-P cells monolayers grown onto glass
coverslips coated with 30 µg/ml collagen (collagen S type
I; Roche Diagnosis, Brussel, Belgium) were analyzed in a parallel plate
perfusion chamber as described (18), with some modifications. The
coverslip constituted the bottom of the chamber, and the actual chamber
was formed by a 254-µm height silicon rubber gasket designed with a
conically shaped flow path, thus resulting in a 3-fold increase of wall
shear rate from the inlet of the chamber to the outlet.
Calcein-AM-labeled HL60 cells suspended in RPMI (0.5 × 106/ml) were perfused at 37 °C with an inverted syringe
pump (Harvard Instruments, South Natick, MA) at a flow rate of 1 ml/min. By mounting the flow chamber on the table of an inverted
epifluorescence microscope (Diaphot; Nikon, Melville, NY) coupled to a
Cohu CCD video camera (COHU Inc., San Diego, CA), HL60 cells
translocation over CHO-P monolayers were observed at wall shear rates
of 300 and 600 s In pursuit of P-selectin antagonists for intervention in
inflammatory diseases such as atherosclerosis, a
cysteine-constrained phage-displayed peptide library was
screened for P-selectin binders (16). A number of positive clones,
including TM11, were identified and sequenced for their peptide insert
(Table I). Comparison of the peptides for
sequence homology revealed a pentapeptide consensus motif, which was
established to be critical for human P-selectin binding by subsequent
truncation and alanine scanning: EWVDV. With its low micromolar
affinity, we argued that the therapeutic potential of the EWVDV peptide
would greatly benefit from further optimization studies.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
2-3Gal
1-4[Fuc
1-3]GlcNAc) moiety (11-14). Most
P-selectin antagonists are carbohydrate derivatives of the sLeX
structure (15). However, as compared with PSGL-1, these glycosides are
relatively poor and unselective P-selectin inhibitors, because binding
to the other selectin family members (E- and L-selectin) is equally affected.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-aminobutyric
acid-HMPA-resin was synthesized on an Applied Biosystems 9050 peptide
synthesizer (Warrington, UK) using standard Fmoc chemistry. In short,
Tentagel S-NH2 (load 0.26 mmol/g) was provided with HMPA as
a linker, resulting in resin 8. Fmoc-
-aminobutyric acid-OH (10 eq)
was attached to the HMPA resin 8 under the agency of
N,N'-dicyclohexylcarbodiimide (5 eq) and
4-dimethylaminopyridine (0.5 eq). All other amino acids, with
acid-labile side chain protection if necessary, were attached by
coupling in the presence of HOBt/TBTU/Dipea (4, 4, and 8 eq,
respectively). After coupling, the resin was washed with DMF,
iso-propanol, and diethyl ether and subsequently dried.
20 °C until use.
= 5.5 mM
1 cm
1). Absorptions were
corrected for the absorption coefficient of the introduced carboxylic
acid(s). Compound purity was checked randomly (~10% of all
compounds) by HPLC analysis on a C8 or C18 reversed phase column
(Alltech, Breda, The Netherlands) using an acetonitrile/water gradient
with 0.1% trifluoroacetic acid at 280 nm and by matrix-assisted laser
desorption ionization mass spectrometry. Compounds in Tables I and II
were all purified by HPLC analysis (>90%) and analyzed by mass spectrometry.
exc = 485,
em = 530 nm).
1, in the presence or absence of
P-selectin antagonists added to HL60 suspensions 2 min before the onset
of perfusion. Real time movies of 12 s (10 images/s), recorded at
random positions in the flow path corresponding to chosen wall shear
rates were stored into the memory of an attached computer and digitized
with a Scion LG3 frame grabber (Scion Corp, Frederick, MD). The
velocity of HL60 cells rolling over the CHO-P cells was determined by
measuring the distance traveled by the HL60 cells during at least
1 s of flow, using the NIH Image program, version 6.1.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
Peptides and their affinities for human P-selectin as determined by
competition enzyme-linked immunosorbent assay
Instead of conventional replacement of individual amino acids by
naturally occurring amino acids, we preferred introduction of new
chemical entities within the EWVDV core sequence by acylation of
available amine groups to enhance the affinity for P-selectin. This
flexible strategy enables the introduction of an infinite range of
substituents and already has been shown effective for the optimization
of an SH2 binding peptide by Yeh et al. (19). Although Yeh et al. used a vast peptide library
(~103 peptides) for screening, we considered a stepwise
optimization protocol on the basis of dedicated libraries of
approximately 100 EWVDV analogues to be at least equally effective and
more practical. In the first screening step we have addressed the
effect of substituting the N and C termini of the EWVDV motif with
seven different moieties (Fig. 1,
acyl moieties 1-7), resulting in a library of 63 compounds.
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The N-terminal amine group within the peptide was readily available for
coupling to the carboxylic acids after removal of the protecting Fmoc
group. To enable modification at the C terminus, however, a
DDE-protected lysine was introduced behind the last valine of the core
peptide. The DDE group can be selectively removed with 2% hydrazine
without affecting the acid-labile side chain protecting groups (20),
thus allowing independent introduction of substituents at either site
of the peptide. Starting from Tentagel S-NH2 resin with an
acid-labile HMPA linker (resin 8), core sequence 9 was synthesized
using HOBt/TBTU/Dipea couplings. The first amino acid, -aminobutyric
acid, was introduced to increase the distance between the C-terminal
carboxylic acid and the amine function of the lysine. After the
introduction of carboxylic acids 1-7, library 10 was cleaved from the
resin by incubation with a trifluoroacetic acid/triisopropylsilane/H2O mixture (Fig.
2). To elucidate peptides with enhanced
P-selectin binding as compared with the EWVDV core, all of the crude
peptides were tested below the IC50 of the EWVDV peptide
(IC50 = 6 µM) at 5 µM in a
competition assay for binding TM11-PO to P-selectin (Fig.
3). This complex was previously shown to
be a potent and specific ligand for P-selectin (16). Peptides with
N-terminal 1,3,5-tricarboxylic acid (acyl moiety 1) or gallic acid
(acyl moiety 6) substituents were found to be most effective in
inhibiting P-selectin binding: > 90% as compared with only 35% for
the unsubstituted reference. The C-terminal counterparts, peptides HP01
and HP06, were considerably less effective, whereas the disubstituted
peptides HP11 and HP66 were equally as potent as the N-terminal
monosubstituted peptides HP10 and HP60 (peptides are coded
HPij, where i and j refer to the acyl
moieties attached to the N and C termini, respectively;
N/C-terminally unmodified amino group is indicated by 0).
Therefore, for the second optimization step we shifted our attention to
the N-terminal substitution, thus obviating the introduction of a
potentially perturbing lysine group at the C-terminal end.
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Earlier observations already suggested that the N-terminal amide
function rather than the complete glutamic acid moiety is necessary for
potent P-selectin binding (16). Peptides KWVDV and AWVDV were equally
potent inhibitors of P-selectin binding, but the absence of an
N-terminal amide function (WVDV) led to a complete loss in binding
capacity (Table I). To conclusively demonstrate the involvement of the
amide group in P-selectin binding, we have synthesized Ac-WVDV (Peptide
11). Indeed, Ac-WVDV was found to inhibit P-selectin binding at a
similar potency as the core sequence EWVDV. Likewise, when gallic acid
(acyl moiety 6), the most potent substituent of the first library, was
attached directly to the -amine group of WVDV (peptide 12), this had
similar potency as when the longer EWVDV core was used instead (peptide 13) (IC50 = 37 versus 31 nM, respectively).
On the basis of the above findings, a new library of 42 substituted
WVDV peptides was designed (Fig.
4A, library 14).
This dedicated library served two purposes. First, the length and
flexibility of the linker between the N-terminal substituent group and
the WVDV motif were varied to optimize the spatial orientation of the
substituent. Carboxylic acids R3 were attached directly to the -amino group of the WVDV core or via a glycine or aminobutyric acid spacer (linkers R4). Second, to be able to pinpoint
the actual groups within 1,3,5-benzene carboxylic acid and gallic acid
responsible for the enhanced affinity of peptides HP10 and HP60,
several carboxylic acids resembling these carboxylic acids were
introduced at the N-terminal amine (carboxylic acids
R3).
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In addition, a range of other anionic substituents was introduced to mimic the negatively charged tyrosine sulfates and the neuraminic acid of sLeX of PSGL-1. These moieties have been shown to be crucial for high P-selectin binding, possibly through occupation of a second binding site on P-selectin (12, 21, 22). Because a number of peptides from library 10 could displace TM11-PO binding above 90% at a 5 µM concentration, the peptides from library 14 were tested at 1 µM. At this concentration, L-cysteic acid-derived (acyl moiety 15) and 5-sulfosalicyclic acid-derived (acyl moiety 16) peptides gave up to 40% inhibition of TM11-PO binding, which is comparable with the 1,3,5-benzenetricarboxylic acid-derivatized peptides (acyl moiety 1) (Fig. 4B). Attachment of nitroaryl (acyl moiety 17) or fluoroaryl groups (acyl moiety 18) resulted in peptides equally as potent as EWVDV, displaying a nonsignificant 5% inhibition at this concentration.
Removal of one of the carboxyl acids of substituent 1, by introduction of carboxylic acids 19-21, did not considerably reduce the affinity for P-selectin, regardless of the position and flexibility of the remaining groups (Fig. 4C). Replacement of the carboxylic acid by an hydroxyl group (carboxylic acid 1 by 22) did not influence P-selectin binding either, suggesting that the gain in affinity is mediated by hydrogen bridging rather than electrostatic interactions. Contrary to the effect of the carboxylic acids, the number of exposed hydroxyls appear to be critical for its affinity, because monobenzoic acid-derivatized (acids 23 and 24) and dihydroxybenzoic acid-derivatized (acid 25) peptides were much less effective than the trihydoxylated counterparts (1) (Fig. 4D). Importantly, P-selectin binding was completely abolished after conversion of the hydroxyls into methyl ethers (via introduction of acid 26).
The spacer length R4 between the core motif and the substituent was of little influence. IC50 values for the peptides lacking an intermediate spacer or having a glycyl or amino buryrate spacer (peptides 12, 27, and 28, respectively) ranged from 37.1 to 15.4 nM (Table II). Further elongation of the spacer, however, to an amino hexanoate (C-6) (peptide 29) caused a significant decrease in affinity (IC50 = 62.9 nM).
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Because flexible spacers confer the advantage of minimal conformational constraints but at the same time cause a maximal loss in entropy after binding, it is preferable to insert a more rigid spacer between the substituent and the core motif, when possible. To investigate the effect of spacer flexibility on the affinity of the substituted peptides for P-selectin, we therefore introduced a number of equally sized, more rigid analogues. A cyclic L-proline linker (peptide 30) led to a 5-fold reduction of the IC50 to 250 nM. Use of a linear 4-amino benzoate spacer, which is conformationally locked and only allows axial rotation of the gallic acid moiety (peptide 31), let to a complete loss in affinity (>1000 nM). Interestingly, binding is partially recovered when inserting an additional CH2 group between linker and gallic acid (peptide 32), regardless of whether the cyclohexyl group is plain aromatic (phenyl; peptide 32) or chair/boat configured (cyclohexyl; peptide 33).
Introduction of the gallic acid moiety did not influence the
specificity of the peptides. Peptide 28, the most potent antagonist of
this series, did not displace
biotin-PAA-Lea-SO3H binding to either mouse
P-selectin or human E- and L-selectin (Fig.
5). This PAA-based conjugate of sulfated
Lea was reported to bind with low nanomolar affinity to all
selectins (17).
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Finally, we investigated peptide 28 for its ability to
inhibit HL60 cell adhesion to P-selectin-transfected CHO cells (CHO-P cells) under static (Fig. 6) and flow
conditions (Fig. 7). Monocyte-derived HL60 cells have a high expression of PSGL-1 (10, 23) and are adherent
to CHO-P cells. Peptide 28 was found to inhibit HL60 cell adhesion with
an EC50 of 74 nM, indicating that it is an effective inhibitor of human P-selectin in a more physiological setting. Under flow conditions, the peptide significantly increased the
rolling velocity of HL60 cells at concentrations as low as 50 nM, indicating a reduced interaction between PSGL-1 and
P-selectin. Surprisingly, at 500 nM tethering to and
rolling of HL60 cells along P-selectin expressing cells could be
observed. This is in sharp contrast to the unmodified EWVDV peptide,
which was unable to affect the rolling velocity or cell adhesion at the
same concentration.
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DISCUSSION |
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The use of phage display in ligand discovery has been shown to be very effective over the last decade, in particular for ill-defined targets (24, 25). Despite its apparent promise for the identification of peptide motifs as initial leads, phage display-based drug design has a number of setbacks. Derived leads often display affinity in the micromolar to millimolar range, which precludes direct use in a therapeutic setting. In addition phage display does not allow the introduction of unnatural amino acid derivatives or post-translational modifications. A conventional strategy to increase the affinity of the peptide ligands involves the systematic replacement of amino acids after having identified a minimal effective motif via alanine scanning and truncation studies (26, 27). An integrated approach in which lead peptides are optimized using combinatorial organic chemistry on the other hand will pave the way for non-amino acid modifications of the peptide leads and will greatly increase the number of possible substituents.
The most convenient way to introduce these modifications and to generate large compound libraries involves the use of solid phase combinatorial chemistry. However, the synthesis of large peptide libraries puts serious demands on purification and screening of compounds to render the process viable. Small dedicated libraries of compounds with a stepwise approach may likely be equally effective for enhancing target affinity.
In this study we have taken a phage display-derived peptide (16) as a starting point for organic chemical optimization. This EWVDV pentapeptide was shown to specifically bind to P-selectin and antagonized HL60 adhesion to P-selectin-transfected cells. In a first library, seven different substituents were introduced by acylation of primary amine groups at either the N or C terminus. Affinity testing of the crude peptides, at a concentration just below the IC50 of the parental EWVDV peptide to reduce the number of hits (5 µM), revealed that N-terminal modification with 1,3,5-tricarboxybenzoic acid (carboxylic acid 1) or gallic acid (carboxylic acid 6) were most effective in inhibiting P-selectin binding (>90% inhibition versus 30% for the underivatized peptide). C terminus modifications had little to no influence on the affinity of the core peptide.
The core peptide could even be reduced to WVDV after identification that the N-terminal amide rather than the glutamic acid was imperative for P-selectin binding. However, when a negatively charged Glu or Asp before the WVDV was present, P-selectin binding was slightly improved compared with other uncharged amino acids like Ala and Lys. Negatively charged groups within PSGL-1, i.e. tyrosine sulfates and the neuraminic acid of sLeX, are found to be crucial for P-selectin binding (11-14). This might imply that negatively charged amino acids Glu and Asp interact with P-selectin at a site proximal to the actual sLeX-binding site. Indeed the existence of a second binding pocket has already been speculated upon in a number of reports (12, 21, 22), although solid evidence still remains to be provided. The derivatization of the core peptide with the gallic acid substituent, again the best substituent in our second library, would also allow occupation of both binding sites, thus explaining the considerably increased affinity.
Of the introduced spacers, the elongated aminobutyric acid spacer performed best (peptide 28, IC50 = 15.4 nM). Introduction of longer or more rigid spacers led to a considerable loss in affinity, indicating that the spatial orientation of the terminal gallic acid group with respect to the peptide is critical. Peptide 28 was also tested for its ability to antagonize HL60 adhesion to P-selectin under both static and dynamic conditions. PSGL-1-mediated adhesion to P-selectin was impaired at 50 nM and even completely blocked at 500 nM.
In conclusion, we show in this study that stepwise optimization of peptide leads through dedicated small peptide libraries is a very efficient strategy. The affinity of the P-selectin binding sequence (E)WVDV was increased almost 800-fold via the introduction of a gallic acid moiety at the N terminus, as was shown in different testing systems. Thus, the combined use of phage display and subsequent combinatorial chemistry led to the design of P-selectin antagonists with nanomolar affinity. These small synthetic antagonists, which are equally potent as the natural ligand P-selectin glycoprotein ligand-1, may be promising leads in atherothrombotic therapy.
For further in vivo use we plan to alter the pharmacokinetic
profile of these compounds. Shifting our attention from peptides to
peptidomimics would also decrease the susceptibility to proteases. This
work is currently in progress.
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FOOTNOTES |
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* 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.
§ Member of UNYPHAR, a collaboration between Yamanouchi and the Universities of Groningen, Leiden, and Utrecht.
To whom correspondence should be addressed: Div. of
Biopharmaceutics, Leiden/Amsterdam Center for Drug Research, Gorlaeus Laboratories, Leiden University, P.O. Box 9502, 2300 RA Leiden, The
Netherlands. Tel.: 31-71-5276040; Fax: 31-71-5276032;
E-mail: biessen@lacdr.leidenuniv.nl.
Published, JBC Papers in Press, January 13, 2003, DOI 10.1074/jbc.M209267200
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ABBREVIATIONS |
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The abbreviations used are: PSGL-1, P-selectin glycoprotein ligand-1; sLeX, sialyl Lewis X; Fmoc, N-(9-fluoroenyl)methoxy-carbonyl; HOBt, 1-hydroxybezotriazole; TBTU, 2-(1H-benzotriazole-1-yl)-1,1,3,3-tetramethyluronium tetrafluoroborate; BOP, benzotriazol-1-yloxytris(dimethylamino)phosphonium hexafluorophosphate; HMPA, 4-hydroxymethylphenoxyacetic acid; Dipea, N,N-diisopropylethylamine; DMF, N,N-dimethylformamide; TM11-PO, tetrameric complex of biotinylated TM11 with streptavidin peroxidase; HPLC, high performance liquid chromatography; Boc, N-(t-butoxycarbonyl); DDE, 4,4-dimethyl-2,6-dioxocyclohex-1-ylidene)ethyl; CHO, Chinese hamster ovary; CHO-P, CHO cells expressing P-selectin; PAA, polyacrylamide; Lea, Lewis A; AM, acetoxymethyl.
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REFERENCES |
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1. |
McEver, R. P.,
Moore, K. L.,
and Cummings, R. D.
(1995)
J. Biol. Chem.
270,
11025-11028 |
2. | Jacob, G. S., Welply, J. K., Scudder, P. R., Kirmaier, C., Abbas, S. Z., Howard, S. C., Keene, J. L., Schmuke, J. J., Broschat, K., and Steininger, C. (1995) Adv. Exp. Med. Biol. 376, 283-290[Medline] [Order article via Infotrieve] |
3. | Lasky, L. A. (1995) Annu. Rev. Biochem. 64, 113-139[CrossRef][Medline] [Order article via Infotrieve] |
4. |
Vestweber, D.,
and Blanks, J. E.
(1999)
Physiol. Rev.
79,
181-213 |
5. | Mayadas, T. N., Johnson, R. C., Rayburn, H., Hynes, R. O., and Wagner, D. D. (1993) Cell 74, 541-554[Medline] [Order article via Infotrieve] |
6. |
Andre, P.,
Hartwell, D.,
Hrachovinova, I.,
Saffaripour, S.,
and Wagner, D. D.
(2000)
Proc. Natl. Acad. Sci. U. S. A.
97,
13835-13840 |
7. | Blann, A. D., Noteboom, W. M., and Rosendaal, F. R. (2000) Br. J. Haematol. 108, 191-193[CrossRef][Medline] [Order article via Infotrieve] |
8. | Myers, D. D., Jr., Schaub, R., Wrobleski, S. K., Londy, F. J., III, Fex, B. A., Chapman, A. M., Greenfield, L. J., and Wakefield, T. W. (2001) Thromb. Haemostasis 85, 423-429[Medline] [Order article via Infotrieve] |
9. |
Merten, M.,
Chow, T.,
Hellums, J. D.,
and Thiagarajan, P.
(2000)
Circulation
102,
2045-2050 |
10. | Sako, D., Chang, X. J., Barone, K. M., Vachino, G., White, H. M., Shaw, G., Veldman, G. M., Bean, K. M., Ahern, T. J., and Furie, B. (1993) Cell 75, 1179-1186[Medline] [Order article via Infotrieve] |
11. |
Norgard, K. E.,
Moore, K. L.,
Diaz, S.,
Stults, N. L.,
Ushiyama, S.,
McEver, R. P.,
Cummings, R. D.,
and Varki, A.
(1993)
J. Biol. Chem.
268,
12764-12774 |
12. | Pouyani, T., and Seed, B. (1995) Cell 83, 333-343[Medline] [Order article via Infotrieve] |
13. |
Wilkins, P. P.,
Moore, K. L.,
McEver, R. P.,
and Cummings, R. D.
(1995)
J. Biol. Chem.
270,
22677-22680 |
14. |
Li, F.,
Wilkins, P. P.,
Crawley, S.,
Weinstein, J.,
Cummings, R. D.,
and McEver, R. P.
(1996)
J. Biol. Chem.
271,
3255-3264 |
15. | Simanek, E. E., McGarvey, G. J., Jablonowski, J. A., and Wong, C. H. (1998) Chem. Rev. 98, 833-862[CrossRef][Medline] [Order article via Infotrieve] |
16. |
Molenaar, T. J. M.,
Appeldoorn, C. C. M.,
de Haas, S. A. M.,
Michon, I. N.,
Bonnefoy, A.,
Hoylaerts, M. F.,
Pannekoek, H.,
van Berkel, T. J. C.,
Kuiper, J.,
and Biessen, E. A. L.
(2002)
Blood
100,
3570-3577 |
17. | Weitz Schmidt, G., Stokmaier, D., Scheel, G., Nifant'ev, N. E., Tuzikov, A. B., and Bovin, N. V. (1996) Anal. Biochem. 238, 184-190[CrossRef][Medline] [Order article via Infotrieve] |
18. |
Theilmeier, G.,
Lenaerts, T.,
Remacle, C.,
Collen, D.,
Vermylen, J.,
and Hoylaerts, M. F.
(1999)
Blood
94,
2725-2734 |
19. |
Yeh, R. H.,
Lee, T. R.,
and Lawrence, D. S.
(2001)
J. Biol. Chem.
276,
12235-12240 |
20. | Bycroft, B. W. (1993) J. Chem. Soc. Chem. Commun. 778-782 |
21. | Kansas, G. S., Saunders, K. B., Ley, K., Zakrzewicz, A., Gibson, R. M., Furie, B. C., Furie, B., and Tedder, T. F. (1994) J. Cell Biol. 124, 609-618[Abstract] |
22. | Needham, L. K., and Schnaar, R. L. (1993) Proc. Natl. Acad. Sci. U. S. A. 90, 1359-1363[Abstract] |
23. |
Wilkins, P. P.,
McEver, R. P.,
and Cummings, R. D.
(1996)
J. Biol. Chem.
271,
18732-18742 |
24. | Adda, C. G., Anders, R. F., Tilley, L., and Foley, M. (2002) Comb. Chem. High Throughput Screen. 5, 1-14[Medline] [Order article via Infotrieve] |
25. | Hoess, R. H. (2001) Chem. Rev. 101, 3205-3218[CrossRef][Medline] [Order article via Infotrieve] |
26. | Apletalina, E. V., Juliano, M. A., Juliano, L., and Lindberg, I. (2000) Biochem. Biophys. Res. Commun. 267, 940-942[CrossRef][Medline] [Order article via Infotrieve] |
27. | Blaber, M., Baase, W. A., Gassner, N., and Matthews, B. W. (1995) J. Mol. Biol. 246, 317-330[CrossRef][Medline] [Order article via Infotrieve] |