EP1003851A2 - Syncytial respiratory virus epitopes and antibodies comprising them, useful in diagnosis and therapy - Google Patents

Abstract

The invention concerns a polyclonal or monoclonal antibody directed against an epitope of the protein G of the syncytial respiratory virus corresponding to a sequence selected among one of the peptide sequences included respectively between the aminoacid residues 150-159, 176-189, 194-207 and 155-176 of the entire sequence of the protein G of the syncytial respiratory virus A or B, or of sequences having at least 98 % homology.

Description

 EPITOPES OF RSV AND ANTIBODIES COMPRISING SAME, USEFUL IN DIAGNOSIS AND THERAPY.

The present invention relates to respiratory syncytial virus, and. more particularly to the identification of new epitopes and to the corresponding antibodies, useful in particular in the field of treatment, prophylaxis and diagnosis of the conditions caused by this virus.

Respiratory syncytial virus (RSV) is one of the most common etiological agents encountered in infants and the elderly. Bronchiolitis is often severe in children and requires hospitalization. Currently, there are no means of prevention against RSV disease, the first RSV infection does not prevent against the next. Treatment of severe cases with antibiotic therapy (Ribavirin) and / or combined with immunotherapy (human immunoglobulins) cannot reduce the worsening of the disease. However, this type of treatment is still very expensive. Recent clinical trials with ORAVAX HNK20 monoclonal antibodies (directed against RSV F protein) have not shown efficacy compared to placebo against RSV infection in children. In the 1960s, attempts to immunize children with a formalin-inactivated RSV vaccine resulted in worsening of the disease rather than providing protection to the lungs against natural RSV infection. Associated with this problem, current diagnoses do not reliably identify RSV infection, at least in adults.

RSV is classified in the family of Paramyxoviridae, genus pneumovirus comprising a non-segmented RNA genome, of negative polarity, coding for 10 specific proteins. Application WO 87/04185 proposed using RSV structural proteins for a vaccine, such as the envelope proteins called protein F (fusion protein) or protein G, a 22 Kd glycoprotein, a protein of 9.5 Kd, or the major capsid protein (protein N).

Application WO 89/02935 describes the protective properties of the entire F protein of RSV, which may be modified in monomeric or deglycosylated form.

A series of fragments of the F protein have been cloned in order to search for their neutralizing properties.

In application WO 95/27787, it has been shown that the RSV protein G can be useful in the preparation of products intended for the treatment and / or prevention of disorders caused by RSV, subgroup A or B. In the context of the present invention, it has now been found that fragments of the RSV protein G, containing specific epitopes, have particularly advantageous properties. New peptide fragments of the RSV protein G can thus be prepared, in particular for the following applications: (i) said peptide fragment coupled or fused, by chemical methods or by genetic engineering, to a carrier, constitutes an effective vaccine against RSV infection, regardless of the mode of administration;

(ii) the same peptide fragments can be used to generate polyclonal and monoclonal antibodies which are very effective in the prophylactic or therapeutic treatments of the host infected with RSV;

(iii) these peptide fragments and the monoclonal antibodies can be used as reagents in a diagnostic kit allowing assert and identify infection in the host infected with RSV-Λ or RSV-B.

The subject of the invention is therefore polyclonal or monoclonal antibodies directed against an epitope of the G protein of RSV corresponding to a sequence chosen from one of the peptide sequences included respectively between the amino acid residues 150-159, 176-189 , 194-207 and 155-176 of the total sequence of protein G of RSV A or B, or of sequences having at least 80%, and preferably at least 98% of homology. These antibodies will recognize peptides carried by the sequence between amino acid residues 130 and 230 of protein G of RSV, subgroup A or subgroup B.

This region corresponding to amino acids 130-230 of protein G of RSV A is hereinafter designated G2Na. G2Na was produced in a bacterium such as E. coli, therefore not glycosylated. It confers, in particular when it is coupled to a carrier such as an OmpA of gram negative bacteria, for example of Klebsiella (protein p40, described in WO 96/14415) or a protein derived from streptococcus (such as the protein binding to serum albumin human, hereinafter called BB, described in WO 96/14416), an immune protection against RSV infections. Unexpectedly, a series of peptides prepared according to the invention has been shown to confer cross-protection against RSV subgroup A or subgroup B.

In particular, a recombinant protein BBG2al, a derivative of BBG2Na where only four residues have been modified on G2Na: the residues Asn (aal91), Lys (aal92), Gly (195) and Thr (aal98) have been replaced by the residues Ser , Asn, Lys and Pro respectively, confers VRS-A or VRS-B cross-protection in BALB / c mice. For the same purpose of strengthening cross-protection, two new molecules have been produced: BBG2a2 where the residues Asn (aal 57), Asn (aal60), Λsn (aal61) and Phe (aal63) have been substituted by the residues Lys, Lys, Λsp and Tyr respectively; BBG2a3 contains the eight modified residues of BBG2a l and BBG2a2. Particularly advantageous peptides according to the invention present in particular one of the sequences chosen from the sequences ID No. 1, ID No. 2, ID No. 3, ID No. 4, ID No. 5, ID No. 6, ID n ° 7, ID n ° 8, ID n ° 9, ID n ° 10, ID n ° 1 1, ID n ° 12, ID n ° 13, ID n ° 14, ID n ° 15, ID n ° 16, ID n ° 17, ID n ° 18, ID n ° 19, ID n ° 20, ID n ° 21 and / or ID n ° 22, appearing in appendix; such a peptide can, in addition, comprise at least one cysteine residue in the N-terminal or C-terminal position.

The reactivity of the peptides is demonstrated by mono or polyclonal probes. Four regions of G2Na were revealed by this technique: G5a (aal44-159), G1a (aal64-176), G4a (aal72-187) and G9a (aal90-204).

The invention therefore also relates to antibodies, monoclonal or polyclonal, directed against a peptide having at least one of the sequences ID No. 1 to ID No. 22.

Peptides having one or more units corresponding to epitopes 150-159, 176-189, 194-207 and 155-176 of the GRS protein G sequence will be very useful for the various embodiments of the invention.

Peptides according to the invention, coupled to a carrier protein, are useful as immunogens. The carrier protein is advantageously chosen from the OmpA of gram negative bacteria and their fragments, the TT protein (tetanus toxoid), the human serum albumin binding protein of Streptococcus and its fragments and the B subunit of cholera toxin. (CTB); preferably, the carrier protein is an OmpA of a bacterium of the genus Klebsiella.

According to one aspect of the invention, the peptide is conjugated to the carrier protein by a binding protein; this binding protein can in particular be chosen from a receptor for serum mammalian albumin and the receptors present on the surface of mucosal cells.

The coupling is preferably a covalent coupling, which can be carried out chemically or by recombinant DNA techniques.

According to another of its aspects, the invention therefore relates to a nucleotide sequence coding for a peptide or an immunogenic agent as defined above. It may in particular be a hybrid DNA molecule produced by insertion or fusion into the DNA molecule coding for the carrier protein, DNA coding for a peptide according to one of claims 4 or 5 or l 'one of their fragments, fused with a promoter; it can also be an RNA molecule.

The peptides, antibodies, immunogens and nucleotide sequences according to the invention can be used as a medicament, and more particularly for the preparation of a composition intended for the preventive or curative treatment of conditions caused by RSV, group A or B.

For example, monoclonal antibodies specifically recognizing the peptides G5a and G l ia and G lΔCa were generated. Passive transfer of monoclonal antibodies 5C2 (anti-G5a) and 18D 1 (anti-G lΔCa) to naive mice on the one hand prevents infection with RSV-A. And on the other hand, the same 5C2 monoclonal rapidly eliminates a chronic RSV-A infection in immunocompromised mice.

The subject of the invention is therefore also a pharmaceutical composition, characterized in that it contains at least one mono or polyclonal antibody, a peptide or an epitope according to the invention, an agent immunogen, or a nucleotide sequence as defined above, and pharmacologically acceptable excipients.

The monoclonal antibodies are preferably humanized and produced by the recombinant route. According to another aspect of the invention, they are obtained by the phage library method.

The peptides, immunogens, antibodies and nucleotide sequences according to the invention can, according to an embodiment of the invention, enter into the composition of a diagnostic kit.

As indicated above, the immunogens can be prepared by recombinant DNA technology, by the introduction of a nucleotide sequence according to the invention in a host cell. This nucleotide sequence can be a fusion gene which is introduced via a DNA vector which comes from a plasmid, a bacteriophage, a virus and / or a cosmid. This fusion gene can, in one embodiment of the preparation process, be integrated into the genome of the host cell.

The vector may be a viral vector, known to those skilled in the art.

The host cell can be a prokaryote, in particular chosen from the group comprising: E. coli, Bacillus, Lactobacillus, Staphylococcus and Streptococcus.

However, the host cell can also be a yeast, a mammalian cell, a cell of plant origin or an insect cell.

According to one aspect of the method according to the invention, the fusion protein is expressed: secreted, localized in the cytoplasm, or else exposed to the membrane of the host cells.

The following examples are intended to illustrate the invention. In these examples, reference is made to the following figures. Figures 1 and 2: Principle of cloning the genes G2a l, G2a2 and G2a3 in vectors.

Figure 3: A-SDS-PΛGE 20% Gel, staining with Comassie Blue. M = Standards of molecular sizes, tracks 1 and 2 proteins BBG2a l (theoretical mass 38.7 Kd) purified by affinity on HSA-Sepharose.

B- Immunoblot of the BBG2a l proteins with an 18 D l monoclonal antibody. Figure 4: A-Immunogenicity of peptides G5a and G9 a.

B- Protective efficacy of peptides G5a and G9a on the lungs.

Figure 5: A- Immunogenicity of peptides G7a and G8a.

B- Protective efficacy of the peptides G7a and G8a on the lungs.

Figure 6: Immunogenicity of BBG2al to RSV A (Figure 6A) and RSV B (6B) and protective efficacy against RSV A (6C) and RSV B (6D). Figure 7: Curative effect of monoclonal antibodies 18D 1 and 5C2. Figure 8: A- Prophylactic efficacy of the 18D 1 monoclonal antibody.

B- Prophylactic efficacy of the monoclonal antibody 5C2. Figure 9: Identification of G2Na B epitopes represented in a serum of mice immunized with BBG2Na. A: total revelation; B: absence of revelation of the region 155-176.

Figure 10: Determination of the recognition zone of the 5B7 monoclonal antibody by the Pepscan B method.

EXAMPLES

Example 1: Synthesis of peptides.

• Example of the synthesis of the peptides G5aCys and CysG5a. Abbreviations:

AA: amino acid

Boc: tert Butoxycarbonyl

BHA: Bromo hydrosuccimidyl acid CE: Capillary Electrophoresis

ES-MS: Electrospray - Mass spectrometry

FMOC: Ωuorenylmethoxycarbonyl

FZCE: Free Zone Capillary Electrophoresis

HBTU: 2- (l H-Benzotriazole- l-yl) - l, l, 3,3-tetramethyluronium hexafluorophosphate

HMP: p-Hydroxymethylphenoxymethyl polystyrene

MBHA: methylbenzhydrylamine

NMP: N-methyl-2-pyrrolidone

Pmc: 2,2,5,7,8-Pentamethylchroman-6-sulfonyl RP-HPLC: Reverse Phase - High Performance Liquid Chromatography

SPPS: Solid Phase Peptide Synthesis tBOC: t-butyloxycarbonyl tBu: tertio Butyl

TFA: trifluoroacetic acid Trt: trityle

The peptide G5a is a peptide of 16 amino acids which corresponds to the fragment of the protein G (144-159) of the VRS-A. It is obtained by chemical synthesis on solid phase from the C side to the N-terminal side. The peptides CysG5a and G5aCys correspond respectively to this peptide with an additional Cysteine on the N or C-terminal side which is intended for unequivocal coupling on a carrier protein. These 2 peptides make it possible to study the influence that the orientation of the peptide conjugated to a carrier protein on the immunological response observed.

The peptides were synthesized using an automatic solid phase peptide synthesizer from the C side to the N-terminal side (FMOC chemistry on the scale of 0.1, 0.25 or 1.0 mmol). The synthesis of the CysG5a peptide is carried out from a Proline preloaded on a resin of HMP type, which allows after cleavage to obtain a free acid function on the C-terminal side or a resin of Rink amide MHBA type, which allows after cleavage to obtain an amide function on the C-terminal side. That of the G5aCys peptide begins with a Cysteine preloaded on one or the other of the resins. The reactive functions of the side chains of the amino acids used are protected by groups compatible with chemistry

FMOC [Cys (Trt); Arg (Pmc); Asn (Trt); Gin (Trt); Lys (Boc); Ser (tBu);

Thr (tBu)]. A coupling cycle takes place as follows: deprotection of the N-terminal amino function of the first amino acid using piperidine, activation of the acid function of the second amino acid to be coupled using HBTU / HMP and coupling. At the end of the synthesis, the peptide 'is cleaved from the resin and the side chains are deprotected by reaction with a water / TFA mixture. The peptide is precipitated with ether cooled beforehand to -40 ° C and the mixture is centrifuged. The pellet is washed three times with ether and then dried with nitrogen. The pellet is taken up with water containing 0.1% TFA. The suspension is again centrifuged and the supernatant which contains the peptide is separated from the pellet, which contains the resin. The crude peptide is purified by semi-preparative reverse phase HPLC. The homogeneity of the purified peptide is verified by reverse phase HPLC and by capillary electrophoresis (FZCE). The theoretical structure is confirmed by comparison of the compatibility of the mass measured by ES-MS type mass spectrometry, with the mass calculated from the theoretical amino acid sequence. . CysG5aNH2 peptide

Summary:

Theoretical weight peptidc-resin at the end of synthesis: 593 mg Weight measured after drying with nitrogen: 619 mg

Peptide-resin cleavage and analysis of the crude peptide: 200 mg (1/3 of the batch) Mass of crude peptide cleaved after lyophilization: 84 mg (75% of net amount of peptide, ie 97% yield) Homogeneity of the crude peptide: 97% (RP-HPLC; UV 2 10 nm) 97% (FZCE / Microcoat ^I )

Purification:

Mass of purified peptide after lyophilization: 50 mg (75% net amount of peptide or 58% yield) Characterization:

Homogeneity of the purified peptide:> 99% (RP-HPLC; UV 210 nm)

> 99% (FZCE / Microcoaf ^M ; UV 200 nm)

Mass spectrometry (ES-MS) Calculated mass: 1951.29 Da

Measured mass: 1950.80 Da ± 0.31

Example 2: Coupling of peptides G5a, G7a, G8a, G9a, Gl la and Gl lΔCa on a carrier protein (P40, BB, TT, KLH).

• Example of the coupling of the peptide Gl lΔCa on the protein P40.

The peptide Gl lΔCa (Seq ID No. 14) is a peptide of 13 amino acids derived from protein G of the RSV. It corresponds to the sequence 164-176 of this protein. During the synthesis, the Cys residue at position 173 was replaced by a Ser residue in order to keep only one Cys residue in position 176 and avoid the formation of a disulfurc bridge 1 -2 which does not exist in natural protein G (apparently 1 -4 / 2-3).

This peptide was coupled using glutaraldehyde (homobifunctional reagent, coupling on the amino and thiol functions) or unequivocally using BHΛ (heterobi onctional reagent, coupling on the thiol function of Cysteine in position C- terminal).

• Unique coupling by BHA • Solubilization of the peptide Gl lΔCa.

2 mg of G l lΔCa are dissolved in 2 ml of 0.1 M phosphate buffer pH 7 + 0.1% Zwittergent 3-14.

• Unique coupling to the P40 protein using a heterobifunctional reagent (BHA).

3 mg of BHA in solution in 25 μl of DMF are added to 2.5 mg of P40 protein previously dialyzed against a 0.1 M phosphate buffer pH7 + 0.1% Zwittergent 3-14 and stirred for 1 hour at room temperature. After desalting on a PD 10 column and elution with a 0.1 M phosphate buffer, pH 7 + 0.1% Zwittergent 3-14, 500 μl fractions are collected and the tubes containing the bromoacetylated protein are collected (OD reading at 280 nm ) in tubes containing 0.95 ml of solution of the peptide Gl lΔCa are added. The reaction medium is saturated with nitrogen and stirred in the dark for 2 hours at room temperature. The solution is then dialyzed using a 0.1 M phosphate buffer, pH 7 + 0.1% Zwittergent 3-14, overnight at + 4 ° C. with stirring and the solution obtained is stored frozen. • Coupling to the P40 protein using a homobifunctional reagent (glutaraldehyde).

10 mg of P40 are dialyzed against a phosphate buffer 0.1 M pl i 7 + 0.1% Zwittergent 3- 14. The concentration is adjusted to 2 mg / ml using a carbonate buffer 0.1 M pH 9 + 0.1% Zwittergent 3-14. 200 mg of SDS of a 4% solution are added.

55.5 μl of 2.5% glutaraldehyde are added to 2.5 ml of a solution of peptide G l lΔCa at 1 mg / ml in a 0.1 M carbonate buffer pH 9 + 0.1% Zwittergent 3- 14 at a pH between 9 and 10. The reaction medium is stirred at + 4 ° C for 24 hours and then brought to room temperature. 25 μl of 1 M lysine are added to block the reaction. The solution is dialyzed against 0.1 M phosphate buffer pH 7 + 0.1% Zwittergent 3-14 for 24 hours at + 4 ° C. with stirring. The dialysate is recovered and the SDS eliminated by precipitation using a 0.02 M KC1 solution 6 times. The last supernatant which contains the P40-G conjugate lΔCa glutaraldehyde is stored in frozen form at -20 ° C.

• Sterilization of conjugates The conjugates are thawed, sterile filtered (0.22 μm), aliquoted and stored at + 4 ° C to avoid problems of precipitation.

• Analytical characterization of conjugates

The conjugates are characterized by assaying the proteins by the Lowry method, electrophoresis of the SDS-PAGE type (development with Coomassie blue) and by assaying the amino acids after acid hydrolysis in the gas phase, derivation by PITC and analysis by HPLC.

Example 3: Cloning of G2al, G2a2 gene in expression vector pvaBB308 and production of BBG2al and BBG2a2 fusion proteins in E. coli The principle of cloning of G2al gene (Seq ID No. 15), G2a2 (Seq ID No. 16 ) and G2a3 (Seq ID No. 17) in the vectors is explained in Figures 1 and 2.

3.1 Construction of G2al The gene coding for the protein G2al (Seq ID No. 15) is constructed by site-directed mutagenesis using the plasmid pRIT28G2Na as starting material. For this, two PCR reactions (Polymerase chain reaction) are carried out with the pairs of oligonucleotides RIT29 / TH 137 (PCR 1) on the one hand and RIT30 / TH 136 (PCR 2) on the other hand under the following conditions:

PCR (94 ° C 15 seconds

25 cycles (55 ° C 30 seconds

(72 ° C 30 seconds

• Attachment to magnetic beads

The fragments obtained, respectively 262 bp and 208 bp for reactions 1 and 2 are fixed on magnetic beads. 25 μl of DYNAL® M-280 magnetic beads coupled to streptavidin are rinsed twice beforehand with TE buffer (10 mM Tris; EDTA ImM, pH 7.5) and then incubated for 20 minutes at 37 ° C with 90 μl of amplification reactions 1 and 2. After fixing, the fragments are denatured by incubating the magnetic beads with 50 μl of 0.15 M NaOH for 10 minutes at room temperature. The two supernatants are recovered, precipitated with absolute ethanol and resuspended in 50 μl of I ^ O.

• Extension reaction

This is carried out by PCR taking 10 μl of each of the amplification reactions under the conditions below: (95 ° C 15 seconds 5 cycles (35 ° C 30 seconds

(72 ° C 30 seconds The fragment generated is amplified by PCR with the oligonucleotides RIT27 and RIT28:

(95 ° C 15 seconds 25 cycles (55 ° C 30 seconds

(72 ° C 30 seconds The amplified fragment of 509 bp is digested with the restriction enzymes Psû and HindIII. The generated fragment of 169 bp is cloned in the vector pRIT28 digested with the same enzymes. The plasmid obtained pRIT28G2al down is sequenced with the Dye Deoxy Terminator chemistry according to the protocol described by Applied Biosystem (Perkin Elmer).

The plasmid pRIT28G2al is obtained by cloning the PstI / Hindlll fragment from pRIT28G2aldown (fragment downstream of the Pst 1 site) into the vector pRIT28G2Na.

The G2al gene is then cloned into the expression vector pvaBB308 at the EcoRI / HindIII restriction sites generating the vector pvaBBG2al.

The oligonucleotide sequence list is shown below: RIT27: 5 '- GCTTCCGGCTCGTATGTTGTGTG - 3'

RIT28: 5 '- ΛAAGGGGGΛTGTGCTGCΛΛGGCG - 3'

TH 136: 5'- CCGΛΛGAΛΛAAACCGΛCGACCΛΛACCGΛCC - 3 'τι-1137: 5' - TTTITΓCTTCGGTITGTTGJCTCGGG - 3 'RIT29: RIT27 biotinylated in 5' RIT30: RIT28 biotinylated in 5 '

3.2 Construction of G2a2 (Seq ID n ° 161

The principle of cloning is shown diagrammatically at the bottom of FIG. 2. The pairs of oligonucleotides used in this construction are the following: RIT29 / TNG 193 (PCR 1) on the one hand and TNG 192 / RIT30 (PCR 2) on the other go. The sequences of the oligonucleotides are described below:

TNG 192: 5'- CCGCCGAAAAAACCGAAAGACGAT - 3 '

TNG 193: 5 '- CGAAATGGTAATCGTCTTTCGG - 3'

3.3 Construction of G2a3 (Seq ID n ° 17)

The two fragments upstream and downstream of the unique Pst1 site were combined on the same vector to give pRIT28G2a3.

The three insert fragments G2al, G2a2 and G2a3 were cloned into different expression vectors in E. coli, in particular in our examples the vectors pvaBB308 where BB is the gene coding for the albumin receptor. The fusion proteins obtained BBG2al, BBG2a2 and BBG2a3 can be easily purified by affinity on an HSA-Sepharose column (Human serum Albumin).

3.4 Fermentation and purification of BBG2al and BBG2a2 fusion proteins

In two Erlenmeyer flasks containing 250 ml of TSB medium (Tryptic Soy Broth, Difco) with Ampicillin (100 μg / ml, Sigma) and Tetracycline (8 μg / ml, Sigma), inoculate with E. coli RV308 transformed with the plasmids pvaBBG2a l and pvaBBG2a2 respectively. Incubate for 16 hours at T ° = 37 ° C with shaking. 200 ml of this culture are inoculated in a fermenter (CHEMAP CF3000, ALFA LAVAL) containing 2 liters of culture medium. The medium contains (g / 1) = glycerol, 5; ammonium sulfate, 2.6; potassium dihydrogen phosphate, 3; dipotassium hydrogen phosphate, 2; sodium citrate 0.5; yeast extract, 1; Ampicillin, 0, 1; Tetracycline 0.008; Thiamine, 0.07; magnesium sulfate, 1 and 1 ml / 1 of trace element solution and 0.65 ml / 1 of vitamin solution. The parameters controlled during fermentation are: pH, agitation, temperature, oxygenation rate, feeding of combined sources (glycerol or glucose). The pH is regulated at 7.0. The temperature is set at 37 ° C. Growth is controlled by feeding glycerol (87%) at a constant rate (12 ml / h) to maintain the voltage signal of dissolved oxygen at 30%. When the turbidity of the culture (measured at 580 nm) reaches the value of 80 (after approximately 24 hours of culture), the production of the proteins is induced by the addition of indole acrylic acid (IAA) to the final concentration of 25 mg / 1. About 4 hours after induction, the cells are harvested by centrifugation. The biomass yields obtained are approximately 200gr of wet biomass. The production yields of BBG2al and BBG2a2 are approximately 4 to 6 mgr of protein per gr of biomass.

A 30 g fraction of wet biomass is resuspended in 70 ml of TST solution (50 mM Tris-HCl pH 8.0, 200 mM NaCl, 0.05% Tween 20 and 0.5 mM EDTA). The cells are disintegrated by sonication (Vibracell 72401, Sonics & Materials). After centrifugation of the cell lysate, the supernatant is filtered (1.2 μm) and diluted in 500 ml of TST. The fusion proteins thus obtained in soluble form are purified on an affinity column: HSA-Sepharose (human serum albumin) according to the protocol described by (Stahl et al, J. Immunol. Methods, 1989; 124: 43-52).

The insoluble lysate, after centrifugation, is washed once with a buffer (50 mM Tris-HCl pH 8.5; 5 mM MgCl ₂ ). After washing, the pellet is dissolved in 30 ml of 7 M guanidine hydrochloride, 25 mM Tris-HCl (pH 8.5), 10 mM Dithiotreitol (DTT), followed by incubation at 37 ° C for 2 hours. The solubilized proteins are added to a renaturation buffer (25 mM Tris-HCl (pH 8.5); 150 mM NaCl and 0.05% Tween 20). The concentration of guanidine hydrochloride is adjusted to the final concentration of 0.5 M in the renaturation buffer before the addition of the solubilized fusion proteins. The mixture is incubated at room temperature, with moderate shaking, for 16 hours. After centrifugation, the soluble products in the supernatant are purified on an HSA-Sepharose column. The purified fusion proteins are analyzed on SDS-PAGE gel (12%), on the MINI PROTEAN II SYSTEM device (BIORADS). Proteins are visualized with Coomassie brilliant blue R250. In addition, the analysis of the recombinant proteins by Immunoblot with antibodies specific for RSV shows that the proteins are antigenic (see example of SDS gel and BBG2al immunoblot in FIG. 3).

Example 4: Immunogenicity and protective efficacy of peptides G5a and G9a coupled to P40.

Materials and methods.

Groups of 7 mice were immunized twice ip with 20 μg of P40-G9aCys, P40-CysG5a, or P40-G5aCys. Control mice were immunized with PBS. Alhygrogel (20% v / v) was used as an adjuvant for all immunizations. The mice were taken from the retro-orbital sinus 2 weeks after the last immunization to confirm their seroconvcrsion against VRS-V, challenged a week later with 10 ⁵ TCID ₅₀ VRS-Λ by the in route, and sacrificed 5 days post-challenge . The lungs were removed and the titer of virus in the lungs determined.

Results

Humoral immune responses.

As shown in Fig. 4A, the immunogenicity of the G5a peptide is dependent on the orientation of the coupling to P40. After coupling by the C-terminal part of the peptide, low to moderate anti-RSV-A antibody titers were induced in the serum. On the other hand, after coupling by the N-terminal part, G5a did not induce such antibodies. In general, the G9a peptide, coupled in C-terminal to P40, was weakly immunogenic in terms of induction of anti-RSV-A antibodies. One in seven mice immunized with P40-G9acys developed a high anti-RSV-A antibody titer.

Protective efficiency of the lungs of peptides G5a and G9a. As shown in Fig. 4B, and in direct correlation with the detection of anti-RSV-A antibodies, the peptide G5a induced protective immune responses when it was coupled at the C-terminal, but not after coupling at the N-terminal. Indeed, 6 mice out of 7 immunized with P40-G5acys (C-terminal coupling) were protected without evidence of virus in the lungs, the last one had the virus only at the limit of detection of the test. In contrast, mice immunized with P40-cysG5a (N-terminal coupling) had virus titers in the lungs as high as control mice, immunized with PBS. These results confirm that the orientation of the coupling of this peptide to a carrier protein is essential. for its protective efficacy. The correlation between the protection and the induction of anti-RSV-anticorps antibodies suggests that the pulmonary protection observed is mediocre, at least in part, by the antibodies.

Despite the fact that P40-G9aCys was weakly immunogenic in mice in terms of induction of serum anti-RSV-Λ antibodies, the lungs of 5 of 7 mice were protected against a challenge by the

VRS-A. In fact, 1 in 7 mice showed no evidence of a virus in the lungs, or even of anti-RSV-A antibodies in the serum.

Conclusions.

The peptides G5a and G9a contain protective epitopes against an RSV-A infection of the lungs. The orientation of the coupling of G5a to a carrier protein is crucial for its protective efficacy.

Example 5: Immunogenicity and protective efficacy of peptides G7a and G8a.

Materials and methods.

Groups of 3 to 4 mice were immunized twice ip with 20 μg of G7a, G8a, BB-G7a, or BB-G8a. Control mice were immunized with PBS. Alhygrogel (20% v / v) was used as an adjuvant for all immunizations. The mice were removed from the retro-orbital sinus 2 weeks after the last immunization to confirm their seroconversion vis-à-vis VRS-A, challenged a week later with 10 TCID ₅₀ VRS-A by the inhalation route, and sacrificed for 5 days. post-challenge. The lungs were removed and the nasal passages washed. The virus titers in the lungs and nasal passages were determined. Results - Humoral immune responses.

As shown in Fig. 5Λ, the peptides G7a and G8a are both immunogenic vis-à-vis the RSV-Λ coupled or not coupled to 1313. If we consider the titers of serum antibodies, the unlinked peptides seem to be a little more immunogenic than the coupled peptides.

Protective efficacy of the G7a and G8a peptides in the lungs.

As shown in Fig. 5B, the lungs of all the mice immunized with the peptides G7a or G8a, whether or not coupled to BB, are protected against a challenge with VRS-A, without the presence of virus or only at the limit of detection of the test.

Conclusions. The G7a and G8a peptides contain protective epitopes against the lungs. The peptides are effective whether or not coupled to BB.

Example 6: Immunogenicity and protective efficacy of the BBG2al fusion protein.

Materials and methods.

In order to determine the immunogenicity and the protective efficacy of BBG2al against RSV-A and B, groups of 3 mice were immunized 2 and 3 times, respectively, by ip route with 20 μg of protein 2 weeks apart . Control mice were immunized with PBS. Alhygrogel (20% v / v) was used as an adjuvant for all immunizations. The mice were removed from the retro-orbital sinus 2 weeks after the last immunization to confirm their seroconversion with RSV-A, challenged a week later with 10 ⁵ TCID ₅₀ VRS-Λ by in route, and sacrifices 5 days post-challenge. The lungs were removed and the titer of virus in the lungs determined.

Results. Immunogenicity of BBG2a l to RSV-Λ and B.

The results presented in Figs. 6Λ and B demonstrate that the

BBG2al is capable of inducing anti-RSV-Λ and B antibodies. As expected, the anti-RSV-Λ antibody titer is much higher than the anti-RSV-B antibody titer. Nevertheless, antibody titers against the two strains of RSV are high.

Protective efficacy of BBG2al against VRS-A and VRS-B.

As shown in Figs. 6C and D, immunization of mice with BBG2al induced immune responses capable of protecting the lungs against a challenge with VRS-A and against a challenge with VRS-B. The mice challenged with VRS-Λ were protected without evidence of virus in the lungs (2 mice / 3) or only at the detection limit (1 mouse / 3). The mice challenged with VRS-B were protected, either without evidence of virus in the lungs (1 mouse / 3) or with virus only at the detection limit (1 mouse / 3) or just above this detection limit (1 mouse / 3).

Conclusions.

The BBG2al fusion protein is very immunogenic vis-à-vis VRS-A and vis-à-vis VRS-B. BBG2al is capable of inducing responses which protect the lungs against a challenge with the 2 subgroups of RSV. EXAMPLE 7 Obtaining the Antibodies 18D1, 5C2 and 5B7

Immunization peptide: (i) G lΔCa coupled to KLI I (Kcyhole Lempct Haemocyanin), (ii) G2ΛCa and (iii) BBG2Na.

The mice were immunized at OJ with 50 μg of CFΛ antigen (complete Freund Adjuvant) in ip, on D 14 with 10 μg of each antigen in IFA (Incomplete Freund Adjuvant) in ip, then on D38 in iv with 10 μg of each peptide without adjuvant. The spleens are removed and fused with the myeloma cells SP2-O at D42 in a 1/1 ratio. The hybridomas positive against each antigen are kept. These hybridomas were injected into mice to obtain ascites and then the different antibodies obtained were selected on different peptides in order to determine the specificity of the antibodies obtained. The 18D 1, 5C2 monoclonal antibodies selected by their specificity against the peptides G lΔCa, G5a, specifically recognize VRS-Λ. The monoclonal antibody 5B7 obtained from BBG2Na and recognizing the peptide G 1 recognizes it VRS-A.

Example 8 Curative effect of the 18D 1 and 5C2 monoclonal antibodies on chronic RSV-A infection obtained in SCID mice.

Materials and methods.

C.B-17 scid / scid mice were challenged i.n. with

10 ⁵ TCID ₅₀ of VRS-A, under 50 μl. Twenty-six days later, the mice received 50 μl of an 18D 1 antibody or 5C2 antibody preparation with an anti-RSV-A ELISA titre of 10 ^4, in and at the rate of 7 mice per group. . Control mice received anti-BB serum with an anti-BB ELISA titer of 10. The mice were sacrificed 5 days later and their lungs were removed for virus titration. Results.

The results presented in Fig. 7 demonstrate that the 18D 1 and 5C2 monoclonal antibodies are capable of eliminating a chronic infection with VRS-A in SCID mice and this in a sterilizing manner. No traces of virus were detected in the lungs at the time of the sacrifice. The results obtained in the lungs of the mice treated with 5C2 correspond to the average of the detection limits of the test, a higher limit due to the lack of sample availability, and not to the presence of virus.

Conclusions.

The monoclonal antibodies 5C2 and 18D 1 could be used as a therapeutic treatment in the context of pulmonary infections with RSV-A.

Example 9: Prophylactic effect of the 18D 1 monoclonal antibody on RSV-A infection in mice.

Materials and methods. A group of naive BALB / c mice, seronegative towards

VRS-A, received by intraperitoneal injection 200 μl of an 18D 1 antibody preparation adjusted for the anti-VRS-A ELISA titre of 10 ^. A group of ip transfer control mice received in parallel 200 μl of an anti-P40 serum preparation (irrelevant serum) adjusted to the anti-P40 ELISA titre of 10%. All the mice are infected the following day by the in route with 50 μl of a viral suspension containing 10 ^ TCID50 of VRS-A. They are sacrificed 5 days later for assay of virus in the lungs. Results.

As shown in Fig. 8Λ, the antibody 18 1 is capable after ip transfer of inducing protection in the lungs of naive mice during a challenge with VRS-Λ. All the mice are protected after injection of 200 μl of 18D 1 as 10 ⁵ . Three out of 7 mice are protected without evidence of virus in the lungs. The others show traces of virus only at the detection limit of the trial (3 mice / 7), or just above this limit (1 mouse / 7). Control mice have titers between log i Q 3.70 and 4.45 per gram of lungs.

Conclusion.

The 18D 1 antibody is capable of preventing a RSV-V pulmonary infection in BΛLB / c mice. It demonstrates significant prophylactic efficacy.

Example 10: Prophylactic effect of 5C2 monoclonal antibody on RSV-A infection in mice.

Materials and methods.

Naive mice seronegative vis-à-vis VRS-A receive by transfer in, 50 μl of a preparation of 5C2 adjusted to the ELISA anti-VRS-A title of 10 ⁴ . Control mice receive in parallel anti-BB serum adjusted to the anti-BB ELISA titer of 10 ⁴ . All mice are infected the next day by the in route with

50 μl of a viral suspension containing 10 ⁵ TCID50 of VRS-A. They are sacrificed 5 days later for titration of virus in the lungs. Results.

As shown in Fig. 8B, all the mice treated with 5C2 at 10 ⁴ were protected at the pulmonary level. Only 1 mouse out of 7 shows traces of virus. Control mice have titers between log i _Q 3.70 and 4.70 per gram of lungs.

Conclusion.

The 5C2 antibody is capable of preventing an RSV-Λ pulmonary infection in BALB / c mice. It demonstrates significant prophylactic efficacy.

Example 11: Pepscan: example of the multiple synthesis of 94 octapeptides covering the sequence of aa 130-230 of G2Na and overlapping with an amino acid. A "PEPSCAN" plate of 96 octapeptides synthesized in parallel

(2 control peptides + 94 peptides covering the 130-230 sequence of protein G of VRS-A) is prepared according to the MULTIPIN ^{1 M} technique described by Geysen et al, Proc. Natl. Acad. Sri., 1984, 81, 3998-4002.

These peptides are synthesized on a solid support at the end of 96 "pins" (8 x 12) complementary to an ELISA microtiter plate in which the screening of monoclonal or polyclonal antibodies (sera) will be carried out directly.

• Pin and well position tracking system The numbering system used is as follows: position Al (l) = Plate n ° A, line 1 (12 lines) column 1 (position H l in

ELISA) position A2 (l) = Plate n ° A, line 2, column 1 (position H2 in ELISA)

Al (l): control peptide # 1: PLAQGGGG A2 (l): control peptide # 2: GLΛQGGGG

Λ3 (l): octapcptide # 1: TVKTKNTT

A4 (l): octapcptide # 2: VKTKNTIT etc. A 12 (8): octapcptide # 94: EVPTTKP

• Summary

The synthesis corresponds to several cycles of deprotection, washing and coupling until the desired peptide sequences are obtained. At the end of the synthesis, the peptides are N-acetylated, before the step of deprotection of the side chains.

The amino acids used for synthesis on pins are protected by an Fmoc group (9-Fluorenylmethoxycarbonyl) and the following side chain protecting groups: t-Butyl ether (tBu) for Serine, Threonine and Tyrosine, t-Butyl ester (OtBu) for Aspartic and Glutamic Acids, t-Butoxycarbonyl (Boc) for Lysine, Histidine and Tryptophan, 2,2,5,7,8-pcntamethylchroman-6-sulfonyl (Pmc) for Arginine, Trityle (Trt) for Cysteine, Asparagine and Glutamine. The activation of the acid function is carried out with Diisopropylcarbodiimide (DIC) and 1-hydroxybenzotriazole (HOBt) dissolved in DMF.

• Fmoc-deprotection and washes: The pine plate is immersed in a bath containing 200 ml of a 20% piperidine solution in DMF (40/160 ml) for 20 min. at room temperature with stirring. The pines are then removed from the bath. Excess solvent is removed by hitting the block of pins on paper towel. The pins are washed in 200 ml of DMF for 2 min. at room temperature with stirring. The block is struck on tissue paper and completely immersed in a bath of MeOH for 2 min. without agitation. The pines are immersed in 200 ml of MeOH then (3 baths of 2 minutes, 200 ml / bath). The plate is dried for 30 min.

• Coupling of Fmoc-amino acids: Fmoc-amino acids undergo an activation step before they can be coupled. The duration of a coupling step is 2 hours for a concentration of 100 mM with 1.5 equivalent of HOBt and 1.2 equivalent of DIC. Software is used to calculate the quantities of reagents required for the coupling step. The weighings are carried out in tubes classified in alphabetical order of the letter code of amino acids. The tubes are filled outside the balance on a sheet of paper-linen, then weighed until a mass close to that indicated on the weighing sheet is obtained. The mass must not be less than 0.2 mg nor more than 0.9 mg compared to the theoretical quantity.

• Coupling step: The pins are gently introduced into the wells. The box is closed carefully and left in a hood for the duration of the coupling for 2 hours for an amino acid concentration of 100 mM. A 2 hour coupling allows 3 couplings per day.

• Treatment of the blocks of pins after coupling: The pins are removed from the plate containing the coupling solutions and washed with 200 ml of MeOH with stirring for 5 min. The block is struck on paper tissue and left to dry for 2 min. The block is placed in 200 ml of DMF and washed for 5 min. with stirring before performing the next deprotection cycle. The plate is conventionally washed and undergoes the step of cleavage of the Fmoc groups as described above after the last coupling. • Acetylation of terminal amines: the pine heads are incubated in the wells of a plate containing 150 μl of the following reactive mixture: DMF / acetic anhydride / trietylamine 50/5/1 (v / v / v). The block is enclosed in a box for 90 min. at room temperature. The block is then washed with 200 ml of MeOH for 15 min. then dried for 15 min.

• Deprotection of the side chains: the protective groups of the side chains are eliminated by immersing the pins in 200 ml of a TFA / anisole / Ethanedithiol 190/5/5 ml mixture for 2 h 30 at room temperature. After this deprotection step, the block of pins is removed from the acid solution. The box is rinsed once with MeOH, then filled with MeOH to completely immerse the block of pins in it for 10 min. The block is then struck on tissue paper and then immersed in 200 ml of a MeOH / water / acetic acid mixture (100/100/1 ml) for 1 hour and struck again on tissue paper. The block is placed under vacuum in a desiccator overnight.

Example 12: ELISA The plate carrying the pins is saturated for 1 hour at 37 ° C. in saturation buffer (PBS, Tween 0, 1%, gelatin 1%), washed for 10 min in PBS and incubated overnight at 4 ° C. with shaking. with the diluted serum to be analyzed. The plate is then washed 4 times 10 min in PBS and incubated for one hour at room temperature with a secondary antibody labeled with peroxidase, diluted to 1/5000 e. After 4 washes in PBS, the TMB substrate is added. The reaction is stopped by adding sulfuric acid.

The summary of the data resulting from the analysis of a murine anti BBG2Na serum by the Pepscan B method is shown in FIG. 9. FIGS. 9Λ and 9B show a reactivity of the anti-BBG2Na mouse serum against 4 regions of the G2Na molecule (the residues in bold lines represent the amino acids playing an important role in Λc / Ag recognition): - region 1 located between residues 150 and 159 whose sequence is QRQNKPPNKP. This region is included in the peptide G5a (144-159) and corresponds to the reactivity zone of the 5C2 monoclonal antibody;

- Region 2 located between residues 176 and 189 whose sequence is CSNNPTCWAICKRI. It is a region located at the level of the peptide G lΔCa (174-187) and corresponding to the reactivity of the monoclonal antibodies 18D 1 and 5D3;

- Region 3 located between residues 194 and 207 whose sequence is PGKKTTTKPTKKPT. This sequence corresponds to a reactivity at the level of the G9 peptide (194-204), reactivity already demonstrated during the production of monoclonal antibodies directed against BBG2Na;

- Region 4 which extends over a large area from residue 155 to residue 176 seems to be the result of different reactivities. One of these reactivities which covers a very hydrophobic region of the G2Na molecule (G l la) corresponds to the recognition zone of the monoclonal antibody 5B7 (obtained after immunization of BALB / c mice by the vaccine candidate BBG2Na) whose pepsean B is shown below in Figure 10.

This monoclonal antibody recognizes the sequence FEVFNFVP (165-172).

All of the above four reactivities have also been confirmed by titration of the anti-BBG2Na serum using different

ELISA developed for each of the reactivities. Table I shows that the anti-BBG2Na serum indeed exhibits "anti-G4a, G5a cys, G9a cys and Gl1a" activities. Table I: Anti-G4a, G5aCys, G9aCys and Gl lΔCa Titers Expressed in Logio ^{of the} Anti-BBG2Na Serum Ref. BE-02.

Conclusion:

The study of an anti-BBG2Na serum by the Pepscan technique shows that the immunization of mice with BBG2Na generates antibodies against 4 B epitopes located respectively in regions 150-159, 176-189, 194-207 and 155- 176. This technique therefore makes it possible to confirm the importance of the region 164-176 (G l lΔCa).

These results are, moreover, in perfect agreement with the ELISA data concerning the reactivity of an anti-BBG2Na serum on the peptides G4a, G5aCys, G9aCys and G l lΔCa.

Claims

1. Polyclonal or monoclonal antibodies directed against an epitope of the G protein of RSV corresponding to a sequence chosen from one of the peptide sequences included respectively between the amino acid residues 150-159, 176-189, 194-207 and 155 176 of the total sequence of protein G of RSV A or B, or of sequences having at least 80% homology.

2. Antibodies according to claim 1, characterized in that they are directed against a peptide carried by the sequence between amino acid residues 130 and 230 of protein G of RSV, subgroup A or subgroup B .

3. Antibody according to one of claims 1 or 2, characterized in that it is directed against a peptide having at least one of the sequences ID No. 1, ID No. 2, ID No. 3, ID No. 4, ID # 5, ID # 6, ID # 7, ID # 8, ID # 9, ID # 10, ID # 1 1, ID # 12, ID # 13, ID # ° 14, ID n ° 15, ID n ° 16, ID n ° 17, ID n ° 18, ID n ° 19, ID n ° 20, ID n ° 21 and / or ID n ° 22.

4. Peptide capable of generating an antibody according to one of claims 1 to 3, characterized in that it has at least one of the sequences chosen from the sequences ID No. 1, ID No. 2, ID No. 3, ID # 4, ID # 5, ID # 6, ID # 7, ID # 8, ID # 9, ID # 10, ID # 11, ID # 12, ID # 13, ID # 14, ID # 15, ID # 16, ID # 17, ID # 18, ID # 19, ID # 20, ID # 21 and / or ID # 22.

5. Peptide according to claim 4, characterized in that it further comprises at least one cysteine residue in the N-terminal or C-terminal position.

6. Immunogenic agent, characterized in that it comprises at least one peptide according to one of claims 4 or 5, coupled to a carrier protein.

REPLACEMENT SHEET (RULE 26)

7. Immunogenic agent according to claim 6, characterized in that the carrier protein is chosen from OmpΛ of gram negative bacteria and their fragments, the TT protein, the protein for binding to human serum albumin of Streptococcus and its fragments and the sub- cholera toxin (CTB) unit B.

8. Immunogenic agent according to one of claims 6 or 7, characterized in that the carrier protein is an OmpA of a bacterium of the genus Klebsiella.

9. Immunogenic agent according to one of claims 6 to 8, characterized in that the peptide is conjugated to the carrier protein by a binding protein.

10. Immunogenic agent according to claim 9, characterized in that the binding protein is chosen from a receptor for mammalian serum albumin and the receptors present on the surface of mucosal cells.

1 1. Agent according to one of claims 6 to 10, characterized in that the coupling is a covalent coupling.

12. Nucleotide sequence coding for an immunogenic agent according to one of claims 6 to 11.

13. Nucleotide sequence according to claim 12, characterized in that it is a hybrid DNA molecule produced by insertion or fusion into the DNA molecule coding for the carrier protein, DNA coding for a peptide according to one of claims 4 or 5 or one of their fragments, fused with a promoter.

14. Nucleotide sequence according to claim 12, characterized in that it is an RNA molecule.

15. As medicament, antibody according to one of claims 1 to 3, peptide according to one of claims 4 or 5, immunogenic agent according to one of claims 6 to 1 1, or nucleotide sequence according to one of claims 12 to 14.

16. Pharmaceutical composition, characterized in that it contains at least one antibody according to one of claims 1 to 3, a peptide according to one of claims 4 or 5, an immunogenic agent according to one of claims 6 to 11 , or a nucleotide sequence according to one of claims 12 to 14, and pharmaceutically acceptable excipients.

17. Use of at least one antibody according to one of claims 1 to 3, of at least one peptide according to one of claims

4 or 5, immunogenic agent according to one of claims 6 to 11, or nucleotide sequence according to one of claims 12 to 14, for the preparation of a composition intended for the preventive or curative treatment of conditions caused by RSV, subgroup A or B.

18. Diagnostic kit, characterized in that it comprises an antibody according to one of claims 1 to 3, a peptide according to one of claims 4 or 5, an agent according to one of claims 6 to 1 1 or a nucleotide sequence according to one of claims 12 to 14.

19. Method for preparing an immunogenic agent according to one of claims 6 to 11, characterized in that the coupling between the peptide and the carrier protein is carried out chemically.

20. Process for preparing an immunogenic agent according to one of claims 6 to 11, characterized in that the coupling is carried out by recombinant DNA technology.

21. Preparation process according to claim 19, characterized in that it comprises a step during which a nucleotide sequence according to one of claims 12 to 14 is introduced into a host cell.

22. Method according to claim 21, characterized in that the nucleotide sequence is a fusion gene which is introduced via a DNA vector which comes from a plasmid, a bacteriophage, a virus and / or cosmid.

23. Method according to one of claims 21 or 22, characterized in that the fusion gene is integrated into the genome of the host cell.

24. Method according to one of claims 21 to 23, characterized in that the host cell is a prokaryote.

25. The method as claimed in claim 24, characterized in that the host cell is chosen from the group comprising: E. coli, Bacillus,

Lactobacillus, Staphylococcus and Streptococcus.

26. Method according to claims 21 to 23, characterized in that the host cell is a yeast.

27. Method according to claims 21 to 23, characterized in that the host cell is a mammalian cell.

28. Method according to claims 21 to 23, characterized in that the host cell is a cell of plant origin.

29. Method according to claims 21 to 23, characterized in that the host cell is an insect cell.

30. Method according to claims 21 to 23, characterized in that a viral vector is used.

31. Method according to one of claims 20 to 27, characterized in that the fusion molecule is expressed, anchored and exposed to the membrane of the host cells.

32. A composition useful according to claim 16 in that the monoclonal antibodies are humanized and produced by the recombinant route.

33. Composition useful according to claim 16 in that the monoclonal antibodies are obtained by the phage library method.