Synthetic Peptides Derived from the Variable Regions of an
Anti-CD4 Monoclonal Antibody Bind to CD4 and Inhibit HIV-1 Promoter
Activation in Virus-infected Cells*
Céline
Monnet
,
Daniel
Laune
,
Jeanny
Laroche-Traineau
,
Martine
Biard-Piechaczyk
§,
Laurence
Briant§,
Cédric
Bès
,
Martine
Pugnière
,
Jean-Claude
Mani
,
Bernard
Pau
,
Martine
Cerutti¶,
Gérard
Devauchelle¶,
Christian
Devaux§,
Claude
Granier
, and
Thierry
Chardès¶
From
CNRS UMR 9921, Faculté de Pharmacie, 15 Avenue Charles Flahault and § CNRS UPR 1086,
CRBM-Laboratoire Infections Rétrovirales et Signalisation
Cellulaire, 34060 Montpellier, France and ¶ INRA-CNRS URA 2209, Laboratoire de Pathologie Comparée,
30380 Saint-Christol-Lez-Alès, France
 |
ABSTRACT |
The monoclonal antibody (mAb) ST40, specific for
the immunoglobulin complementarity-determining region (CDR) 3-like loop
in domain 1 of the CD4 molecule, inhibits human immunodeficiency virus
type 1 (HIV-1) promoter activity and viral transcription in
HIV-infected cells. To design synthetic peptides from the ST40 paratope
that could mimic these biological properties, a set of 220 overlapping
12-mer peptides frameshifted by one residue, corresponding to the
deduced ST40 amino acid sequence, was synthesized by the Spot method
and tested for binding to recombinant soluble CD4 antigen. Several
peptides that included in their sequences amino acids from the CDRs of
the antibody and framework residues flanking the CDRs were found to
bind soluble CD4. Eleven paratope-derived peptides (termed CM1-CM11)
were synthesized in a cyclic and soluble form. All the synthetic
peptides showed CD4 binding capacity with affinities ranging from 1.6 to 86.4 nM. Moreover, peptides CM2, CM6, CM7, CM9,
and CM11 were able to bind a cyclic peptide corresponding to the
CDR3-like loop in domain 1 of CD4 (amino acids 81-92 of CD4). Peptide
CM9 from the light chain variable region of mAb ST40 and, to a lesser
extent, peptides CM2 and CM11 were able to inhibit HIV-1 promoter long
terminal repeat-driven
-galactosidase gene expression in the HeLa P4
HIV-1 long terminal repeat
-galactosidase indicator cell line
infected with HIV-1. The binding of mAb ST40 to CD4 was also
efficiently displaced by peptides CM2, CM9, and CM11. Our results
indicate that the information gained from a systematic exploration of
the antigen binding capacity of synthetic peptides from immunoglobulin
variable sequences can lead to the identification of bioactive
paratope-derived peptides of potential pharmacological interest.
 |
INTRODUCTION |
The CD4 molecule is a transmembrane glycoprotein (58 kDa) found on
thymocytes, mature T-cells, macrophages, monocytes, and Langerhans'
cells (1). This surface protein is required to shape the T-cell
repertoire during thymic development (2) and to permit appropriate
activation of mature T-cells through adhesion with class II major
histocompatibility complex molecules and the T-cell receptor (3).
Engaged CD4 subsequently plays a role in signal transduction by
association with the protein-tyrosine kinase p56lck (4).
Besides its physiological function, the CD4 surface glycoprotein, in
association with chemokine receptors, acts as a receptor for HIV-1 1 entry into cells
(5-7). CD4 is a member of the immunoglobulin gene superfamily and
consists of four extracellular domains (D1-D4) showing structural
homology to immunoglobulin variable regions, a membrane-spanning
region, and a cytoplasmic tail (8); in D1, there are three CDR-like
regions (9, 10). The CDR2-like loop of D1 has been identified as the
primary binding site for the HIV envelope glycoprotein gp120 (11-13),
whereas the CDR3-like region represents a CD4 target for inhibition of
the class II major histocompatibility complex-restricted immune
responses (14-18) and HIV replication (19-24). Previous studies have
shown that CDR3-like peptide analogs are strong inhibitors of these
functions (14, 16-18, 25-28), probably interfering with CD4
dimerization (29, 30). Similarly, mAbs such as ST40 that bind to the
CDR3-like loop in D1 of CD4 inhibit HIV-1 replication in infected cells at a post CD4/gp120 binding step (24).
Antibody paratopes result from the interactions between immunoglobulin
variable heavy (VH) and light (VL) chains. The
diversity of paratopes is mainly generated by the sequences of the CDRs found in VH and VL, which are exposed
hypervariable loop structures. Antigen binding by peptide sequences
from selected CDRs of mAbs has been demonstrated to have specificities
similar to those of the original antibody molecule (31-40). Our
previous results showed that the systematic exploration of the antigen
binding capacity of short peptides derived from an antibody sequence
leads to the identification of numerous paratope-derived peptides
(PDPs) that display significant affinity for the antigen (40).
Therefore, this approach could be useful to identify potentially
biologically active peptides from the sequence of a pharmacologically
active antibody.
In this study, we have established the nucleotide sequences of the
VH and VL regions of mAb ST40. A set of
immobilized overlapping dodecapeptides covering the deduced amino acid
sequences of mAb ST40 variable regions was prepared by the Spot method
(40, 41). The ability of biotinylated soluble CD4 (sCD4) to bind these
peptides was then investigated and led to the selection of peptides
with CD4 binding activity. All the selected PDPs prepared in a soluble cyclic form showed CD4 binding capacity, and three of them blocked HIV-1 promoter activity and efficiently competed with mAb ST40 for
binding to CD4.
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EXPERIMENTAL PROCEDURES |
Soluble CD4--
Recombinant purified sCD4, kindly provided by
Professor D. Klatzmann (Hopital de La Pitié, Paris), comprised
the four external domains of CD4 (42). sCD4 (280 µg in 600 µl of
bicarbonate buffer, pH 8.6) was biotinylated using a commercial reagent
(Amersham Pharmacia Biotech RPN2202) according to the manufacturer's
instructions. Biotinylated sCD4 was stored in PBS at
20 °C until use.
Cloning of mAb ST40 VH and VL
Genes--
The murine hybridoma cell line that produces mAb
ST40/F142-63 (IgG1,
) was a kind gift from Dr. D. Carrière
(Sanofi Recherche, Montpellier, France) (43). Total RNA was extracted
from 3 × 108 hybridoma cells using the
TRIzolTM technique (Life Technologies Inc., Paisley, United
Kingdom). The VL gene of the ST40 antibody was obtained by
polymerase chain reaction amplification. Briefly, reverse transcription
was performed with 2 µg of total RNA, the reverse transcriptase
Superscript (Life Technologies Inc.), and the primer
OPP-SoC
3' (5'-CGCGCAGATCTAACACTCATTCCTGTTGAAGC-3'), which contains the reverse complement of codons 208-214 of C
. One
µl of first strand cDNA was used as matrix for the polymerase chain reaction to amplify the ST40 VL/CL genes
using Vent DNA polymerase (New England Biolabs, Hitchin, UK) and the
primers OPP-SoC
3' and OPP-SoV
5'
(5'-GA(C/T/A)ATTGAGCTCAC(C/A)CAG(T/A)CTCCA-3'). These
primers contained restriction sites (underlined) for cloning. The
degenerate primer OPP-SoV
5' was chosen as the consensus sequence of
codons 5-8 in murine FR1 V
. The polymerase chain reaction-amplified DNA product was digested sequentially with BglII and
SacI (New England Biolabs) and purified on a 1.5%
low-melting temperature agarose gel (Life Technologies Inc.). This
digested DNA was ligated to pUC19 that was prepared in a similar
manner. The VL cDNA sequence was determined by
double-stranded sequencing using the dideoxy chain termination method
with the T7 sequencing kit (Amersham Pharmacia Biotech, Uppsala). The
VH gene of the ST40 antibody was isolated from a cDNA
library. Briefly, poly(A)+ RNAs were magnetically separated
from total RNAs by hybridization with a biotinylated oligo(dT) primer
and then captured by streptavidin coupled to paramagnetic beads as
described by the manufacturer (PolytractTM, Promega,
Madison, WI). A cDNA library was constructed from 10 µg of ST40
poly(A)+ RNA in the pSPORT1 vector using the
SuperscriptTM plasmid system (Life Technologies Inc.). This
library was screened by plaque hybridization with
32P-labeled primer Mu
1CH1
(5'-GAAATAGCCCTTGACCAGGCA-3'). This primer contains sequence
information for the reverse complement of the murine
1
constant region gene, which codes for amino acids 142-148. The dideoxy
chain termination sequencing of the VH cDNA from
selected clones was carried out on both strands using the T7 sequencing kit. The numbering of the amino acid sequences of variable regions was
that of Kabat et al. (44).
Peptide Synthesis on Cellulose Membranes--
The general
protocol has been described previously (45). Membranes were obtained
from Abimed (Langenfeld, Germany). Fmoc amino acids and
N-hydroxybenzotriazole were obtained from Novabiochem (Läufelfingen, Switzerland). The ASP222 robot (Abimed) was used for the coupling steps. Two-hundred twenty overlapping dodecapeptides frameshifted by one residue representing the VH and
VL sequences of the ST40 antibody were synthesized on
cellulose membranes. All peptides were acetylated at their N termini.
After the peptide sequences were assembled, the side chain-protecting
groups were removed by trifluoroacetic acid treatment (41).
Assay for sCD4 Interaction with Cellulose-bound
Peptides--
The technique was performed as described previously for
epitope analysis (41) and as adapted to paratope study (40). Briefly, the saturated membranes were incubated with a 1 µg/ml solution of
biotinylated sCD4 for 90 min at 37 °C. Bound sCD4 was detected by
incubation of the membrane at 25 °C for 30 min in a 1:3000 dilution
of an alkaline phosphatase-streptavidin conjugate (Sigma) and
subsequent addition of a phosphatase substrate
(5-bromo-4-chloro-3-indolyl phosphate and
3-(4,5-dimethylthiazol-2-yl)-2,5 diphenyltetrazolium bromide, Sigma). A
blue precipitate on the spots was indicative of binding. After scanning
the membrane, NIH software was used to measure the spots' intensities
(45). The membrane was further treated so as to remove precipitated dye
and bound CD4 and reused when necessary. Inhibition of sCD4 binding to
membrane-bound peptides was evaluated as described above, except that
biotinylated sCD4 (1 µg/ml) was preincubated with anti-CD4 mAb ST40
(10 µg/ml) for 18 h at 4 °C.
Synthesis of Soluble Peptides and Cyclization--
The 11 dodecapeptides, termed CM1-CM11 (see Table I), selected by the
immunoassay described above, two control peptides (see below), and a
CDR3-like peptide (TYICEVEDQKEE) corresponding to CDR3 loop 81-92 in
D1 of CD4 were prepared by Fmoc solid-phase synthesis on a AMS422
robot. To improve solubility and to allow cyclization of peptides,
Lys-Cys residues were added to both the carboxyl and amino termini of
peptides CM1, CM2, CM6, CM7, and CM9-CM11. For peptides CM3-CM5 and
CM8 and the CDR3-like peptide, the lysine residue was replaced by a
tyrosine residue. The peptides were deprotected and released from the
resin by trifluoroacetic acid treatment in the presence of appropriate
scavengers. They were lyophilized, and their purity was assessed by
HPLC. When necessary, the peptides were purified to >90% HPLC
homogeneity. The peptides were cyclized by formation of a disulfide
bond between the two extra cysteine residues as described by Tam
et al. (46): 10 mg of peptide was dissolved in a solution of
20% dimethyl sulfoxide in 50 mM ammonium acetate buffer,
pH 7.0, and stirred for 24 h at 20 °C. Peptide concentration
was adjusted to 0.5 mg/ml to avoid the formation of intermolecular
disulfide bonds. The efficiency of oxidation was assessed by
determination of free sulfhydryl groups in the peptides (47). To this
end, peptides (0.5 mg/ml, 10 µl) and 5,5'-dithiobis(2-nitrobenzoic
acid) (0.4 mg/ml, 50 µl) were added to 100 mM Tris, pH
9.0, and the absorbance at 412 nm was determined and compared with the
value obtained with the unoxidized peptides. Oxidation efficiency was
further assessed by analytical HPLC by the change in the retention time
of the oxidized peptide as compared with that of the linear form. The peptides showed >90% intramolecular disulfide bonding at the end of
this procedure.
Enzyme-linked Immunosorbent Assay Monitoring of sCD4 and
CDR3-like Peptide Interactions with Cyclic PDPs--
Enzyme
immunoassay plates (96-well; Nunc, Paisley) were coated overnight at
4 °C with 10-fold serial dilutions of the 11 cyclic PDPs (CM1-CM11)
in 100 mM sodium carbonate buffer, pH 9.6. Three replicates
were tested for each dilution with an initial peptide concentration of
100 µg/ml. An irrelevant cyclic peptide, 97026c (CKSSQSLLDSDGKTYLNWC), derived from the heavy chain CDR2 of an anti-p53
antibody was included as a control to verify that binding was
sequence-specific. Two cyclic peptides, Dig23c (KCLEWIGDIYSGGGCK) and
Dig97c (KCFGDYYCLQYASSCK), (derived from the heavy chain CDR2 and the
light chain CDR3 of anti-digoxin mAb 1C10, respectively) were used as
controls to verify the effect on antigen binding of adding Lys-Cys
residues to the peptide sequence. After four washes in 160 mM PBS, pH 7.2, containing 0.1% Tween 20 (PBS-T), plates
were saturated with a 1% nonfat powdered milk in PBS-T for 30 min at
37 °C. Biotinylated sCD4 (1 µg/ml) or biotinylated CDR3-like
peptide (100 µg/ml) was added after four washes in PBS-T, and plates
were incubated at 37 °C for 2 h. Following four washes in
PBS-T, 100 µl of an alkaline phosphatase-streptavidin conjugate was
added to each well. The conjugate was used at a 1:3000 dilution in
PBS-T. The plates were incubated at 37 °C for 30 min and then washed
four times in PBS-T. Finally, a 1 mg/ml 4-nitrophenyl phosphate disodium (Sigma) solution in 1 M diethanolamine, pH 9.8, was added for 20 min at 37 °C, and the absorbance was measured at
405 nm.
Real-time Analysis by BIAcoreTM--
The kinetic
parameters (association rate constant (ka) and
dissociation rate constant (kd)) were determined by
surface plasmon resonance analysis using a BIAcore instrument (BIAcore
AB, Uppsala). Using BIAevaluation 3.0 software, ka and kd were determined by the so-called global
method (48). The apparent equilibrium constant KD is
the ratio kd/ka. All experiments
were carried out at 25 °C. Free NH2 from the
extrasequence lysine residue in CM1, CM2, CM6, CM7, and CM9-CM11 and
from the intrasequence lysine residue in CM4 and free COOH from the
glutamic acid residue in CM5 were used to chemically immobilize
molecules on the sensor chip. Peptides CM3 and CM8 were chemically
immobilized by the hydroxyl groups of threonine and serine,
respectively, after activation by 1,1'-carbonyldiimidazole (Sigma-Aldrich). The surface plasmon resonance signal for immobilized peptides was found to be ~30-50 resonance units after completion of
the chip regeneration cycle, corresponding to 30-50 pg of
peptide/mm2. The binding kinetics for immobilized peptides
were determined by injecting sCD4 (20 µg/ml) in Hepes-buffered saline
buffer (running buffer) at a flow rate of 30 µl/min. For the
inhibition study, mAb ST40 (20 µg/ml) and PDP (20 or 200 µg/ml)
were co-injected onto the sensor chip-bound CD4 (30-50
pg/mm2). The kd increase was calculated
as the ratio of kd determined with inhibitor to that
obtained without inhibitor.
HIV-1 Promoter Activation Assay--
The HeLa P4 HIV-1 LTR
-galactosidase indicator cell line (49) was provided by O. Schwartz
(Institut Pasteur, Paris). HeLa P4 cells, which stably express the
-galactosidase reporter gene cloned downstream of the HIV-1 LTR
promoter, were plated in six-well plates at 5 × 105
cells/ml in Dulbecco's modified Eagle's medium containing a 1% penicillin/streptomycin mixture (Gibco), 1% Glutamax, 1 mg/ml Geneticin (G418), and 10% fetal calf serum. The cells were exposed to
1 ml of infectious HIV-1Lai at 1000 × 50% tissue
culture infective dose/ml prepared from the supernatant of chronically
infected CEM T-cells, as described previously (50). After incubation for 1 h at 4 °C, the cyclic PDPs CM1, CM2, CM6, CM7, and
CM9-CM11, at concentrations ranging between 12.5 and 200 µg/ml, were
added individually to the cell culture medium. Next, cell cultures were transferred at 37 °C in a 5% CO2 atmosphere to allow
infection (note that the HIV-1 infection provides the viral
transactivator Tat protein necessary for the HIV promoter in the target
cells). After 3 days in culture, cells were lysed, and
-galactosidase activity was determined by incubating 200 µl of
total cellular extracts for 1 h at 37 °C in 1.5 ml of buffer
containing 80 mM Na2HPO4, 10 mM MgCl2, 1 mM 2-mercaptoethanol,
and 6 mM o-nitrophenyl
-D-galactopyranoside.
-Galactosidase activity was
evaluated by measuring absorbance at 410 nm. Incubation of infected
HeLa P4 cells with anti-CD4 mAb ST40 at 20 µg/ml or anti-HLA class II
mAb B8-12 (kindly provided by M. Hirn, Immunotech-Coulter, Marseille,
France) at 20 µg/ml served as positive and negative controls,
respectively. Additional controls consisted of linear Lyso-3 peptide
(biotinyl-YKKSGTSPKRWIYDT), derived from the light chain CDR2 of
anti-lysozyme mAb HyHEL-5 (40), and the cyclized 97026c peptide
described above.
 |
RESULTS |
Sequence of Anti-CD4 mAb ST40--
The nucleotide sequences of the
VH and VL regions from anti-CD4 mAb ST40 were
established as described under "Experimental Procedures."
Nucleotide sequences of three individual clones were determined for
each chain type and shown to be similar. Comparison of this sequence
with other known antibody sequences showed that the VH
region of mAb ST40 belongs to subgroup IIA according to the
classification of Kabat et al. (44) and displays 95.5%
homology to the closest VGK2 germ line gene (51) from the
V-Gam 3.8 family. mAb ST40 used a member of the DSP2 DH gene
segment family, and the JH gene segment is homologous to the
JH2 germ line (44) except for a 3-nucleotide difference
probably accounted for by somatic mutation. Sequence analysis suggests
that the ST40 VL region results from the rearrangement of a
V
subgroup III gene with the J
1 gene segment (44).
More precisely, the ST40 VL region shows 88% homology to
the closest V
21G germ line gene (52) from the
V
21 family. Computer-assisted comparisons of these
variable regions with other sequenced genes from anti-CD4 mAbs
indicated that the ST40 VL region shows strong homology to the VL region of anti-CD4 mAb L71 (53). No significant
homology to the anti-CD4 heavy chain has been found for the
VH sequence of mAb ST40.
Systematic Evaluation of the Reactivity of Overlapping Peptides
from the ST40 Antibody Sequence with Biotinylated
sCD4--
Two-hundred twenty overlapping 12-mer peptides frameshifted
by one residue, corresponding to the deduced amino acid sequences of
VH and VL from mAb ST40, were synthesized
according to the Spot method (40). These membrane-bound peptides were
then probed with biotinylated sCD4. The results are described
qualitatively in Fig. 1A, in
which peptide spots showing at least one CDR residue are highlighted,
and quantitatively in Fig. 1B. Biotinylated sCD4 bound
mainly to peptides including amino acid(s) from the six CDRs of mAb
ST40 (peptides 20-29, 31, 39-47, 49-50, 56-60, 88-106, 108, 133, 152-158, 175-180, 212, and 215-220). The majority of peptides
containing only framework residues did not display any binding
activities. However, several peptides (peptides 16-19, 38, 87, 127-132, 159-160, and 181-182) that contained only framework residues, mainly flanking the CDRs, were able to bind the sCD4 antigen.
Little or no reactivity with sCD4 was observed with peptides comprising
amino acids from the middle of the CDR sequence (peptides 30, 32-35,
48, 51-55, 61-66, 107, 134-151, 163-174, 202-211, and 213-214).
As shown in Fig. 1B, this binding pattern was strongly affected by preincubating sCD4 with the parental anti-CD4 mAb ST40 (10 µg/ml). No binding was observed with the alkaline
phosphatase-streptavidin complex alone (data not shown). Taken together
and in accordance with previous observations (40), these results
indicate that the binding of sCD4 to immobilized peptides is specific.
Eleven peptides (peptides 19, 25, 49, 59, 89, 99, 105, 128, 154, 178, and 220, named CM1-CM11, respectively) showing the highest reactivity with sCD4 (color intensity of the corresponding spots between 119 ± 15 and 165 ± 14) were selected for further study in a soluble form. The selected peptides comprised either exclusively CDR (CM6) or
framework (CM1 and CM8) sequences or comprised amino acids from both
CDRs and framework sequences (CM2-CM5, CM7, and CM9-CM11).

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Fig. 1.
Reactivity of overlapping dodecapeptides
derived from the sequence of anti-CD4 mAb ST40 with biotinylated sCD4
(A) and quantitative analysis of the binding
(B). The membrane on which the peptides were
synthesized was incubated with 1 µg/ml biotinylated sCD4 or with 1 µg/ml biotinylated sCD4 preincubated with 10 µg/ml mAb ST40. In
A, CDRs are indicated (H1, H2, and
H3 and L1, L2, and L3
correspond to CDR1, CDR2, and CDR3 of the heavy and light chains,
respectively), and peptide spots are numbered from 1 to 220. In
B, shaded areas indicate the cellulose-bound
peptides that reacted with biotinylated sCD4 (cutoff taken at 80 arbitrary units). Boldface amino acids belong to the CDRs.
Results correspond to the mean ± S.D. of values obtained from
three independent experiments.
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CD4 and CDR3-like Loop Specificity of Soluble Cyclic Peptides
Derived from the ST40 Antibody Sequence--
The 11 peptides
(CM1-CM11), selected from the initial 220 overlapping peptides on the
basis of their reactivity with sCD4 in the form of membrane-bound
peptides, were synthesized by conventional solid-phase synthesis and N
to C terminus-cyclized through cysteine oxidation (Table
I). Their binding to whole CD4 and to a
CDR3-like loop peptide (corresponding to residues 81-92 in D1 of the
CD4 molecule) was assessed by enzyme-linked immunosorbent assay (Fig. 2). Soluble cyclic peptides reacted
specifically with sCD4 in a dose-dependent manner, which
was not the case for the three irrelevant cyclic peptides 97026c,
Dig23c, and Dig97c, the latter two including an extra lysine residue
like the CM peptides. Peptides selected from either the VH
region (Fig. 2A) or the VL region (Fig.
2B) displayed CD4 binding activity in a 1-100 µg/ml
concentration range. Peptides CM2, CM6, and CM7 (Fig. 2C),
derived from the ST40 VH region, and peptides CM9 and CM11
(Fig. 2D), derived from the ST40 VL region,
strongly recognized CDR3-like peptide 81-92, whereas other synthetic
peptides did not significantly bind this antigen. The linear forms of
peptide CM9 and several other PDPs were markedly less reactive than the
cyclic form (data not shown), indicating a beneficial effect of N- to
C-terminal cyclization on binding properties. Furthermore, the absence
of reactivity of the 12-mer Lys-Cys-cyclized peptides Dig23c and Dig97c
showed that the additional cysteine and lysine residues used for
cyclization/solubilization are not implicated in the CD4 and CDR3-like
binding. Taken together, these results indicate that the selected
soluble cyclic peptides derived from mAb ST40 have the capacity to
specifically bind the CD4 molecule, but only some of them also
demonstrated a specificity for the CDR3-like loop.
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Table I
BIAcore determination of the binding kinetics of the interaction
between sensor chip-bound peptides derived from the Vlt and
VL sequences of ST40 and biotinylated CD4
Boldface amino acids belong to the CDRs of mAb ST40.
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Fig. 2.
Enzyme-linked immunosorbent assay binding
curves of biotinylated sCD4 or CDR3-like peptide 81-92 on adsorbed
cyclic peptides derived from the sequence of mAb ST40. Plates were
coated with various concentrations of the cyclic peptides synthesized
from the VH sequence (A and C) and
from the VL sequence (B and D).
Probing was performed either with biotinylated sCD4 (1 µg/ml)
(A and B) or biotinylated CDR3-like peptide (100 µg/ml) (C and D). Irrelevant peptides (Dig23c,
Dig97c, and 97026c) were used as negative controls. Each value
represents the mean ± S.D. of triplicate determinations.
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The results of the BIAcore study, in which the kinetic parameters
ka and kd of the interaction
between immobilized peptides and soluble CD4 were measured, are
summarized in Table I. All 11 peptides exhibited measurable binding to
sCD4. No measurable binding was obtained with the irrelevant cyclic
peptide. The calculated KD values ranged from 1.6 to
86.4 nM. Peptides CM2 and CM5-CM7, derived from the CDR1
and CDR3 VH regions of mAb ST40, showed the highest
affinity. The KD values obtained with the peptides
showed a 4-8-fold increase in value as compared with the value
obtained with the parental ST40 mAb (0.37 nM). This increase is mainly due to a lower dissociation rate of the mAb (0.33 × 10
4 s
1) in comparison with
that obtained with the PDPs.
Inhibition of HIV-1 Promoter Activation in Virus-infected Cells by
PDPs--
The ability of the PDPs to inhibit HIV-1 promoter activity
was measured in HeLa P4 cells stably transfected with the
-galactosidase reporter gene under the control of the
HIV-1Lai LTR promoter. Infection of the indicator cell line
with HIV-1Lai strongly stimulated the HIV-1 promoter
activity (mean A410 nm increased from 0.014 to
0.548). As shown in Fig. 3A,
no inhibition of the HIV-1 LTR-driven
-galactosidase gene expression
was observed when HIV-1Lai-infected indicator cells were
cultured with anti-HLA class II mAb B8-12, whereas 65% inhibition was
found following incubation with mAb ST40. Irrelevant linear and cyclic
peptides did not affect the
-galactosidase gene expression. In
contrast, treatment with the cyclic PDPs CM2, CM9, and CM11
significantly inhibited the HIV-1 LTR-driven
-galactosidase gene
expression induced by HIV-1Lai. Several other cyclic PDPs
(CM1, CM6, CM7, and CM10) showed no effect. Peptide CM9, corresponding
to the sequence 30DSYMNWYQQKPG41 of the CDR1
framework-2 light chain region, was the strongest inhibitor. As shown
in Fig. 3B, peptide CM9 inhibited, in a
dose-dependent manner, the HIV-1 LTR-driven
-galactosidase gene expression induced by HIV-1Lai. At a
concentration of 63 µg/ml, peptide CM9 showed ~50% of the effect
of the parental antibody used at 20 µg/ml. Taken together, these
results indicate that the PDPs CM2, CM9, and CM11, initially selected
among all the overlapping dodecapeptides of the VH and
VL domains of anti-CD4 mAb ST40, are able to inhibit the
HIV-1 promoter, a property previously ascribed to mAb ST40 (24).

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Fig. 3.
Inhibition of HIV LTR-driven
-galactosidase gene expression induced by
HIV-1Lai following incubation with cyclic PDPs
synthesized from the ST40 sequence (A) and with different
concentrations of peptide CM9 (B). Irrelevant linear
Lyso-3 and cyclic 97026c peptides were used as negative controls.
Results correspond to the mean ± S.D. of inhibition values
obtained from at least four independent experiments. Mean absorbances
at 410 nm varied from 0.014 for uninfected indicator cells to 0.548 for
HIV-1Lai-infected indicator cells. -gal,
-galactosidase.
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Inhibition of ST40 Binding to CD4 by Three Paratope-derived
Peptides--
Competitive binding assays were performed to examine the
ability of peptides CM2, CM9, and CM11 to block the binding of the parental ST40 mAb to sensor chip-bound CD4 (Table
II). The three PDPs competed with the
anti-CD4 antibody for binding to sensor chip-bound CD4, as determined
by BIAcore analysis. This competition led to the enhancement of the
dissociation rate of the antibody to the CD4 molecule. A
1000-2000-fold kd increase was obtained when
peptides were used at a concentration of 200 µg/ml. This inhibitory
effect was dose-dependent since a peptide concentration of
20 µg/ml caused only a 30-50-fold increase in the dissociation rate.
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Table II
Increase in the dissociation rate of the binding between sensor
chip-bound CD4 and the anti-CD4 mAb co-injected with PDPs derived from
the sequence of the antibody
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DISCUSSION |
The identification, by using multiple peptide synthesis, of PDPs
able to bind antigen was recently described by our group; several of
these peptides display a significant fraction of the affinity of the
whole antibody (40). Therefore, this approach could conceivably be used
to screen peptide ligands mimicking the biological effect of a given
antibody. With this perspective in mind, we have studied an anti-CD4
mAb (ST40) that shows interesting pharmacological activities. The ST40
antibody binds to the CDR3-like loop in D1 of CD4 and has been
described as a strong inhibitor of HIV promoter activity and provirus
transcription (24). We have established the VH and
VL amino acid sequences of this antibody and assessed the
reactivity of sCD4 with overlapping 12-mer peptides derived from these
sequences by the Spot method (40, 41). Eleven peptides were found to
react strongly and specifically with the CD4 antigen. We demonstrated
that soluble cyclic peptides derived from peptides reactive in the Spot
assay were able to recognize the CD4 molecule and a cyclic CDR3-like
loop peptide corresponding to region 81-92 of CD4. Among the CDR3-like
loop-specific PDPs, three (CM2, CM9, and CM11) were found to block HIV
promoter activity and to compete efficiently with the parental mAb for binding to CD4.
An interesting feature was that PDPs showing the strongest reactivity
with CD4 in the Spot assay included both residues from the CDRs and
residues from the framework flanking the hypervariable regions,
extending our previous observations (40). Antibody variable domains
comprise a framework of
-sheets surmounted by antigen-binding loops.
We can postulate that critical residues, identified in the Spot assay
and confirmed by preliminary Alascan analysis (data not shown), located
in the
-sheet framework closely underlying the CDRs, probably do not
participate in direct interaction with CD4, but could induce a binding
conformational state mimicking some of the structural features of the
ST40 paratope. Three points argue in favor of this hypothesis. First,
some framework amino acids that modulate the peptide/CD4 interaction
(i.e. Tyr27, Trp47,
Gly49, and Arg94 in the ST40 VH
sequence and Tyr36 in the ST40 VL segment)
belong to the vernier zone, which contains residues that adjust the CDR
structure and fine-tune the fitting to the antigen (54). Second, some
residues possess an aromatic structure (i.e.
Tyr27 and Trp47 in the heavy chain and
Tyr36 in the light chain) characterized as protruding into
the antigen-binding site surface to stabilize the antigen/antibody
interaction (55, 56). Third, framework arginine residues
(i.e. Arg94 in VH and
Arg18 in VL) modulate the peptide/CD4 binding,
in keeping with previous work demonstrating the critical role of
Arg94 in the interaction of a CDR3 VH peptide
with phosphatidylserine (36). These six critical residues from the
framework regions of the ST40 antibody possess one or several of these
characteristics, in agreement with previous results obtained in our
laboratory on the interactions of mAb HyHEL-5/lysozyme (40) and mAb
Tg10/thyroglobulin and mAb 4D8/angiotensin
II.2
Based on the observations that CDR3-like synthetic peptides can bind
CD4, Langedijk et al. (30) have proposed that the putative dimerization of CD4 involves the CDR3-like loop in D1. Moreover, electrostatic potential contours calculated for a putative CD4 dimerization occurring in D1 predicted that the negative electrostatic potentials of the CDR3-like region were completely compensated for by
positive charges on the opposite CD4 molecule in the dimer (30). Recent
results (29) suggest that Glu87, Asp88,
Glu91, and Glu92 in the CDR3-like loop are
essential for CD4 dimerization and that these four negatively charged
amino acids are involved in the ST40 epitope. These observations may
have important implications for understanding how mAb ST40 interacts
with CD4. We can speculate that positively charged residues from the
CDRs of mAb ST40 could participate in the paratope. The cyclic peptides
CM2, CM6, and CM7 from the VH region and CM9 and CM11 from
the VL domain have been demonstrated to bind strongly to
the CDR3-like loop of CD4 domain 1, and Lys-Cys residues added for
cyclization/solubilization are not implicated in this binding.
Positively charged residues, like Arg100G and
Arg100H found in the sequence of the PDPs CM6 and CM7 from
the CDR3 VH region, Lys39 belonging to the
sequence of peptide CM9 from the CDR1 VL domain, and
Lys107 in the PDP CM11, could conceivably interact with the
negatively charged residues of the ST40 epitope. In agreement with this
hypothesis, Arg100H and Lys39 have been found
to be critical amino acids by the Spot method in the peptide/CD4
interactions. Moreover, preliminary results obtained by Alascan
analysis of PDPs confirm the contribution of these positively charged
residues in CD4 binding (data not shown). However, positively charged
amino acids probably reflect only a part of the interaction between
ST40 and CD4 since other contributor residues in the CDRs were found by
using Alascan analysis.
With regard to the measured binding kinetics of the interaction between
soluble linear peptides from the HyHEL-5 paratope and lysozyme (40), a
1-log decrease in the kd was observed in the
peptide/CD4 binding, whereas association rates were in the same order
of magnitude in the two models. In the case of anti-reovirus mAb
87.92.6 (34), it has been reported that the increased conformational
stability of cyclic CDR peptides could increase the binding affinity.
In addition, other reports (26, 57) suggest that cyclization helps
peptides to mimic the CDR conformation. From these observations and
from the results obtained with the CM peptide series, it seems that
constraining the PDPs improves their affinity for antigen through a
decrease in the dissociation rate of the equilibrium reaction between
ligands. All the selected PDPs were able to bind sCD4 with
KD values ranging from ~2 to 90 nM,
the best values being 4-8-fold higher than those obtained with the
parental mAb.
mAb ST40 has been previously shown to inhibit HIV-1 LTR-driven
chloramphenicol acetyltransferase gene expression induced by HIV-1Lai (24). The PDP CM9, derived from region 30-41 of
the ST40 CDR2 VL domain, blocks HIV promoter activity
through the inhibition of
-galactosidase gene expression in a
dose-dependent manner. The biological effect of CM9 was
corroborated by further BIAcore experiments, in which this peptide was
shown to displace the binding of ST40 to CD4 by increasing the rate of
the dissociation reaction. Numerous bioactive peptides corresponding to
the CDR3-like loop have been used to modulate the T-cell response (14,
17, 18) or to exert anti-HIV activity (26, 28). Disruption of CD4
dimerization by CDR3-like analogs has been proposed as a major mechanism by which cell activation could be inhibited following treatment of CD4-positive cells by CDR3-like analogs (18, 26, 29, 30).
Furthermore, negatively charged residues in amino acid region 87-92 of
CD4 can potentially be involved in the binding of a CDR3-like analog to
CD4 (29). The facts that (i) the PDP CM9 interacts with CDR3-like
region 81-92 and inhibits HIV-1 promoter activity and that (ii)
residues 87/88 and 91/92 are involved in the epitope of the ST40
antibody, from which peptide CM9 has been designed, suggest that this
PDP could act as an inhibitor of CD4 dimerization. Such an effect needs
to be confirmed by additional experiments, even though we cannot rule
out the fact that other CD4 regions might contribute to the
oligomerization. Our results clearly demonstrate that the systematic
exploration of sets of short cellulose-bound synthetic overlapping
peptides derived from the sequences of immunoglobulin variable regions
is a valuable strategy for identifying bioactive PDPs.
 |
ACKNOWLEDGEMENTS |
The skillful assistance of N. Domergue in the
synthesis and purification of peptides is acknowledged. We thank Dr.
S. L. Salhi for editorial revision of the manuscript. We also
gratefully acknowledge Professor D. Klatzmann and Drs. D. Carrière and O. Schwartz for providing reagents and cells.
 |
FOOTNOTES |
*
This work was supported by institutional funds from CNRS and
by grants from ELF and from the Biotechnology Program of the Ministère de l'Enseignement Supérieur et de la Recherche.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.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) AJ005354 and AJ005355.
To whom correspondence should be addressed. Tel.:
33-4-67-54-86-04; Fax 33-4-67-54-86-10; E-mail:
chardes{at}pharma.univ-montp1.fr.
The abbreviations used are:
HIV-1, human
immunodeficiency virus type 1; D1, domain 1; CDR, complementarity-determining region; mAb, monoclonal antibody; VH, variable region of the heavy chain; VL, variable region of the light chain; PDP, paratope-derived peptide; sCD4, soluble CD4; PBS, phosphate-buffered saline; Fmoc, N-(9-fluorenyl)methoxycarbonyl; HPLC, high pressure liquid
chromatography; LTR, long terminal repeat.
2
D. Laune, F. Molina, G. Ferrières, J.-C.
Mani, P. Cohen, D. Simon, T. Bernardi, M. Piechaczyk, B. Pau, and C. Granier, unpublished data.
 |
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