The present invention relates to a mutated polypeptide which derives from the gp41 protein, and also to a vaccine comprising it.
The development of a method for immunizing against HIV is, today, one of the priorities of scientific research.
The major obstacles represented by the great genetic variability of the virus and the poor exposure, to the immune system, of neutralizing viral epitopes considerably slow down the production of neutralizing immunity.
The HIV envelope glycoprotein which is required in order to confer on the virus its infectious nature represents the target for neutralizing antibodies. These characteristics have made the latter a subject of intense investigation.
The glycoprotein envelope (ENV) of the human immunodeficiency virus-1 (HIV-1) is synthesized from the gp160 precursor which, under the action of a protease, gives the gp120 and gp41 subunits.
The attachment of gp120/gp41 to the cellular receptors (CD4 or a receptor for chemokines, such as CCR5 or CXCR-4) induces a change of conformation of gp41 from a latent state (nonfusogenic) to a fusion-active state (fusogenic). Between these two states, a transient, termed “intermediate”, state exists, during which gp41 has the appearance of a trans-membrane protein in both the viral and cell membranes (Weissenhorn et al Nature (1997), 387 (6631), 426-30).
Binding experiments have made it possible to establish that the nonfusogenic latent state is characterized by the inaccessibility of large portions of the ectodomaine of gp41. gp120 in fact interacts in such a way as to mask the epitopes. It has, moreover, been shown that the inhibition of the structural change from the intermediate state toward the fusogenic state by peptides used as competitors can affect viral infection (Weissenhorn W. et al, Molecular Membrane Biology, 1999, 16, 3-9).
The use of the fusogenic state of gp41 for immunization purposes is disclosed in WO 00/140616. According to that application, N-helices can be used alone or in combination with C-helices in order to reproduce, in the latter case, the fusogenic conformation of gp41.
The applicant provides a novel immunization antigen which can be used in immunization against HIV. The applicant has, in fact, demonstrated, for the first time, that the intermediate state of gp41 is capable of inducing antibodies which neutralize primary isolates of HIV.
The present invention therefore relates to a polypeptide capable of forming a structure corresponding to or mimicking the intermediate state of gp41 comprising at least one mutation selected in the group consisting of T35I or L; W49I or L; Q56I or L; I101D or S; I108D and W94D.
Acording to one particular embodiment, the polypeptide comprises at least another mutation selected in the group comprising the following mutations: G13A, L, M, I, W or K; Q17A or E; Q18A or E; A24Q, E, S or R; Q28A; T35I or L; V36Q or E; W37S or D; G38A, V, L, I, M or E; Q39A, V, L, I, M or E; K40E, A, V, L, I or M; Q41A, V, L, I, M or E; Q43A, V, L, I, M or E; L47A or D; V491 or L; R51A, N or E; Q561; C64S; C70S; or L; W94D; D98A, V, L, I, M or K; R99A, N or E; I101D or S; Y104M or E; I108D; Q119A, V, L, I, M, S, N or R; E120A; K121A; E123A; E125A; R153N or A et R173N or A.
According to prefered embodiment, the polypeptide of the present invention comprises the following mutations: T35I; I101D; T35I+Q28I+I101D; T35I+Q28I+I101D+Q119N; I101D+I108D+Q131N+W37A; I101D+I108D+Q142N+L126D; W37A+I101D+I108D+Q119N or I101D+I108D+Q119N+L126D.
According to another aspect, the present invention relates to a conjugate comprising a polypeptide according to the invention conjugated to a carrier protein or peptide.
According to another aspect, the present invention relates to a DNA sequence encoding a polypeptide according to the invention or encoding a conjugate according to the invention.
The present invention also relates to an expression vector comprising said DNA sequence, and also to a host cell containing said vector.
A subject of the present invention is also a vaccine against HIV, comprising at least one polypeptide as defined above, at least one conjugate as defined above or at least one expression vector as defined above, a pharmaceutically acceptable support and, optionally, an adjuvant.
A subject of the present invention is also a method of induction of antibodies neutralizing HIV comprising administration to mamal of an efficient amount of a polypeptide of the invention.
Another subject of the present invention relates to the process for preparing a polypeptide as defined above, comprising the expression of said polypeptide using a host cell as defined above.
The invention is described in greater detail in the description which follows.
The phenomenon of conformational change in gp41 preceding the fusion of cell and viral membranes is illustrated in FIG. 1.
The applicant has demonstrated, surprisingly, that the intermediate state of gp41 induces antibodies which neutralize primary isolates of HIV. Induction of antibodies which neutralize primary isolates can be easily determined using the neutralization assay as described in the article by C. Moog et al (AIDS Research and human retroviruses, vol. 13(1), 13-27, 1997). In the context of the present invention, it is considered that neutralizing antibodies have been induced by the antigen assayed when the serum diluted to ⅕th causes a 10-fold decrease in the amount of p24 present in the culture supernatant. The present polypeptide is thus particularly appropriate as a vaccine antigen usable for treatment and prevention of an HIV infection.
In the context of the present invention, the expression “polypeptide corresponding or mimicking the intermediate state of gp41” is intended to mean a polypeptide, preferably a trimeric polypeptide, which, under physiological conditions, has an open conformation. In this open conformation, at least one of the C-helices is not paired around the N-helices in the anti-paralleled orientation as present in the fusogenic form. Preferably, the three C-helices are not paired with the N-helices in the anti-parallel orientation as present in the fusogenic form. In such a conformation, it is probable that the C-helix which is not paired with the central trimer consisting of the N-helices adopts a free (“coil”) conformation. In the open conformation according to the invention, the N-helices are paired with one another in the parallel orientation, preferably forming a trimer. In the case of the monomer, in the open conformation according to the invention, the C-helix is not paired with the N-helix.
The production of an open conformation can be demonstrated using the technique of measuring the intrinsic fluorescence of the polypeptide, as described by Schmid, F. X. (1989) “Spectral methods of characterising protein conformation and conformational changes” Creighton, T. E. Protein structure—a practical approach. pp251-284, IRL, Oxford University Press. In summary, the polypeptide will be excited at 295 nm and the fluorescence emission spectrum will be recorded at 310-380 nm. There is a correlation between the emission maximum of these wavelengths and the environment of the tryptophans in the structure. A tryptophan residue which is totally exposed to the solvent (i.e. a hydrophilic environment) has an emission maximum of approximately 355 nm, whereas a tryptophan residue which is protected from the solvent (i.e. present on the inside of the polypeptide) has an emission maximum of approximately 325 nm. In its trimeric form, the polypeptide according to the invention has 9 tryptophan residues at the N/C interfaces. The production of an open conformation will therefore result in an increase in the emission maximum recorded at 310-380 nm.
The polypeptide according to the invention has the particularity of being stable, i.e. it conserves it intermediate conformation under physiological conditions. The stability of the peptide according to the invention can easily be controlled using the differential scanning calorimetry (DSC) technique which is well known to those skilled in the art. Reference may be made, for example, to the articles by A. Cooper et al, Phil Trans. R. Soc. Lon. A (1993) 345, 23-25, and by V. V. Plotnikov et al. Analytical Biochemistry 250, 237-244 (1997).
The applicant has also surprisingly demonstrated that the open conformation of the polypeptide of the present invention is maintained in a strongly acid medium. The polypeptide of the present invention is thus particularly appropriate as an antigen usable in an oral vaccine. The applicant has indeed shown that gp41 ectodomain has a very high thermostability at pH=2.5 and that the polypeptide of the invention shows the same feature.
The polypeptide according to the invention consists of the sequence corresponding to the gp41 protein lacking all or part, preferably all, of the sequence corresponding to the transmembrane domain. The polypeptide according to the invention also lacks all or part, preferably all, of the sequence corresponding to the fusion peptide. According to a preferred embodiment, all or part of the sequence corresponding to the intracytoplasmic domain is also deleted.
In the context of the present invention, the term “gp41” is intended to mean a gp41 protein derived from any strain of HIV1 or of HIV2, preferably of HIV1, including laboratory strains and primary isolates. By way of illustration, mention may be made of MN and BX08 strains.
The nucleotide sequence and peptide sequence of a large number of gp41 proteins are known and available for example, over the internet or in the corresponding Los Alamos compendia. It is clear that any sequence into which one or more conservative mutations has been introduced is also included in the context of the present invention.
The various constituent domains of gp41, identified above, are defined herein with reference to the sequence of gp41 LAI as represented in
Although deletion of the sequence 1-23 is preferred, in particular because of the presence of a methionine at position 24, deletion of the sequence 1-32 is also suitable in the context of the present invention.
Regarding the transmembrane domain, some authors consider that the latter begins at residue 154. Although deletion of the sequence 173-194 is preferred, deletion of the sequence 154-194 is also envisaged in the context of the present invention.
The polypeptide according to the invention can be obtained by mutation of the natural sequence of gp41.
According to a preferred embodiment, the polypeptide according to the invention is prepared from the sequence of gp41 LAI in which the transmembrane domain and the fusion peptide, and also part of the intracytoplasmic domain, have been deleted. This sequence is represented in FIG. 3.
The mutations identified in the subsequent text are numbered with reference to the sequence in
The applicant has demonstrated a certain number of mutations which destabilize the structure of the latent state and/or of the fusogenic state of gp41 (in the monomeric and/or trimeric state) and/or stabilize the intermediate state of gp41 (in the monomeric and/or trimeric state), and/or promote the transconformation from the latent state to the intermediate state and/or hinder the transconformation from the intermediate state to the fusogenic state. These mutations make it possible to stabilize the polypeptide according to the invention in an open conformation.
The applicant has demonstrated that the polypeptide according to the present invention, and more particularly the N- and C-helices identified in the structure in the fusogenic state, may be divided into four regions (numbered with reference to the sequence of
The introduced modifications can be evaluated using conventional methods which are well known to those skilled in the art. By way of a method which may be used, mention may be made, for example, of the method of Eisenberg, which allows measurement of the mean-hydrophobicity and of the mean hydrophobic moment along the sequence; and the analysis of hydrophobic clusters, of molecular hydrophobicity potentials or of molecular electrostatic potentials. The structural modifications can be evaluated, for example, with studies of molecular dynamics and also with software for predicting secondary structures, such as PHD, NPSA, etc. These methods are described in the following articles: Method of Eisenberg: D., Schwarz, E., Komaromy, M. and Wall, R. 1984 Journal of Molecular Biology, 179:123-142; Analysis of hydrophobic clusters: Gaboriaud, C., Bissery, V., Benchetrit, T. and Mornon, J P. 1987, FEBS Letters. 224 (1): 149-55; Molecular Hydrophobicity Potential: Brasseur, R. 1991, Journal of biological chemistry, 266:16120-16127; Molecular Electrostatic Potential: Delleers, M. and Brasseur, R. 1989 Biochemical Pharmacology, 38 (15): 2441-2447; Molecular Dynamics (study of stability): Berendsen, H. J. C., van der Spoel, D. and van Drunen, R. 1995 GROMACS, Computer Physics Communications, 95:43-56; Molecular Dynamics (transconformation): Guilbert, C., Perahia, D. and Mouawad, L. 1995, Computer Physics Communications, 91:263-273; PHD: Rost, B. and Sander, C. 1994 Proteins, 19: 55-72; NPSA: Combet, C., Blanchet, C., Geourjon, C. and Deléage, G. 2000 Trends in biochemical sciences, 25 (3): 147-150.
The applicant has shown that the mutations as defined above which are related to the amino acids of region 1 hinder the interactions of this region with regions 3 and 4 in the latent state and/or with region 4 in the fusogenic state, and/or promote the multimerization of this region in the fusogenic state. The mutations as defined above which relate to the amino acids of region 2 promote an α-helical structure for this region and/or the transconformation to such a structure, and/or hinder the interactions of this region with regions 3 and 4 in the latent state and/or with region 4 in the fusogenic state, and/or promote the multimerization of this region in the fusogenic state. The mutations as defined above which relate to the amino acids of region 3 promote the multimerization in the latent state and/or in the fusogenic state, and/or hinder the interactions of this region with regions 1 and 2 in the latent state and/or with region 4 in the fusogenic state. The mutations as defined above which relate to the amino acids of region 4 promote the multimerization of this region in the latent state, and/or hinder the interactions with this region with regions 1 and 2 in the latent state and/or with regions 1, 2 or 3 in the fusogenic state.
Regions 1 to 4 of the polypeptide according to the invention and also the function of the mutations are summarized in
In the subsequent text, the amino acids are represented by their international code, and the code L1NNL2 indicates that the amino acid which is represented by L1 and which is located at position NN is mutated at the amino acid represented by L2.
The present invention thus provides a polypeptide comprising at least one mutation, preferably two mutations, selected in the group consisting of: T35I or L; V49I or L; Q56I or L; I101D or S; I108D and W94D. These mutations are preferably selected in the group consisting of T35I and I101D or S. This first mutation is preferably combined with at least one other mutation, preferably with 1 to 3 mutations, which are located preferably in at least of the regions 1 to 4. When two mutations are selected in the group identified above, these mutations are combined with at least one other mutation, preferably with 1 to 2 mutations, located preferably in at least of the regions 1 to 4.
The polypeptide according to the present invention preferably comprises at least two mutations which hinder the interactions between the N/C helices. According to a particularly preferred aspect, these two mutations are combined with at least one mutation, preferably at least two mutations, which promote the interactions between the N helices in a parallel orientation. The polypeptide thus obtained may also advantageously comprise one or more of the other mutations having the effects identified in FIG. 4 and in particular at least one of the mutations identified in table 1 in columns 3 to 6.
These additional mutations are preferably selected in the group comprising the following mutations: G13A, L, M, I, W or K; Q17A or E; Q18A or E; A24Q, E, S or R; Q28A; T35I or L; V36Q or E; W37S or D; G38A, V, L, I, M or E; Q39A, V, L, I, M or E; K40E, A, V, L, I or M; Q41A, V, L, I, M or E; Q43A, V, L, I, M or E; L47A or D; V49I or L; R51A, N or E; Q56I; C64S; C70S; or L; W94D; D98A, V, L, I, M or K; R99A, N or E; I101D or S; Y104M or E; I108D; Q119A, V, L, I, M, S, N or R; E120A; K121A; E123A; E125A; R153N or A et R173N or A.
Preferably, positions K40 and D98 are not simultaneously mutated.
Examples of combination of additional mutations which can be used in the present invention are: Q17A+Q18A; Q17A+Q18A+Q28A; Q41E+Q43E; C64S+C70S; E120A,+K121A; E120A+E123A and K121A+E125A.
According to a preferred embodiment, the polypeptide of the invention comprises the mutation(s): T35I; V49I; Q56I; T35I+Q28I+I101D; T35I+Q28I+I101D+Q119N; V49I+Q28I+I101D; V49I+Q28I+I101D+Q119N; Q56I+Q28I+I101D; Q56I+Q28I+I101D+Q119N; I101D; I101S; I108D; W94D; I101D+Q28I+V49I; I101D+Q281I+Q56I; I101S+Q28I+T35I; I101S+Q28I+V49I; I101S+Q28I+Q56I; I108D+Q28I+T35I; I108D+Q28I+V49I; I108D+Q28I+Q56I; W94D+Q28I+T35I; W94D+Q28I+V49I; W94D+Q28I+Q56I; I101D+I108D+Q131N+W37A; I101S+I108D+Q131N+W37A; W94D+I108D+Q131N+W37A; I101D+W94D+Q131N+W37A; I101S+W94D+Q131N+W37A; I101D+I108D+Q142N+L126D; I101S+I108D+Q142N+L126D; W94D+I108D+Q142N+L126D; I101D+W94D+Q142N+L126D; I101S+W94D+Q142N+L126D; T35I+Q28I+I101S+Q119N; V49I+Q28I+I101S+Q119N; Q56I+Q28I+I101S+Q119N; T35I+Q28I+I108D+Q119N; V49I+Q28I+I108D+Q119N; Q56I+Q28I+I108D+Q119N; T35I+Q28I+W94D+Q119N; V49I+Q28I+W94D+Q119N; Q56I+Q28I+W94D+Q119N; T35L; V49L; Q56L; T35L+Q28I+I101D; T35L+Q28I+I101D+Q119N; V49L+Q28I+I101D; V49L+Q28I+I101D+Q119N; Q56L+Q28I+I101D; Q56L+Q28I+I101D+Q119N; I101D+Q28I+following V49L; I101D+Q28I+Q56L; I101S+Q28I+T35L; I101S+Q28I+V49L; I101S+Q28I+Q56L; I108D+Q28I+T35L; I108D+Q28I+V49L; I108D+Q28I+Q56L; W94D+Q28I+T35L; W94D+Q28I+V49L; W94D+Q28I+Q56L; T35L+Q28I+I101S+Q119N; V49L+Q28I+I101S+Q119N; Q56L+Q28I+I101S+Q119N; T35L+Q28I+I108D+Q119N; V49L+Q28I+I108D+Q119N; Q56L+Q28I+I108D+Q119N; T35L+Q28I+W94D+Q119N; V49L+Q28I+W94D+Q119N; or Q56L+Q28I+W94D+Q119N; W37A+I101D+I108D+Q119N or I101D+I108D+Q119N+L126D.
These polypeptides preferably correspond to a polypeptide of sequence SEQ ID NO 2 in which the above-mentioned mutations have been introduced.
Examples of polypeptides of the present invention which are particularly preferred are polypeptides of sequence SEQ ID NO 2 in which the following mutation(s) have been introduced: T35I; I101D; T35I+Q28I+I101D; T35I+Q28I+I101D+Q119N; I101D+I108D+Q131N+W37A or I101D+I108D+Q142N+L126D; W37A+I101D+I108D+Q119N or I101D+I108D+Q119N+L126D.
Other modifications may be introduced into the polypeptide of the invention, for example in order to facilitate expression and promote better solubility. Advantageously, one or both cysteine at position 64 and position 69 may be replaced, for example, with serine.
Although the polypeptide according to the invention has an open conformation which is stable under physiological conditions, this conformation can be reinforced by adding cysteine residues to the ends of the polypeptide. To this end, two additional cysteine residues can be added at the N-terminal or at the C-terminal, preferably at the N-terminal, of the polypeptide according to the invention so as to covalently fix the trimer in an open conformation. In this case, the amino acids Q17 and Q18 are preferably mutated to cysteine.
The mutations proposed may be combined in order to obtain a synergistic effect or, at the very least an additive effect. The polypeptide according to the present invention preferably comprises at least two mutations which hinder the interactions between the N/C helices. According to a particularly preferred aspect, these two mutations are combined with at least one mutation, preferably at least two mutations, which promote the interactions between the N helices in a parallel orientation. The said polypeptide thus obtained may also advantageously comprise one or more of the other mutations having the effects identified in FIG. 4 and in particular at least one of the mutations identified in Table 1 in columns 3 to 6.
The mutations proposed in the context of the present invention are summarized in Table 1.
The polypeptide according to the invention can be obtained using any conventional technique of chemical synthesis or of genetic engineering.
When the polypeptide is produced by chemical synthesis, the polypeptide according to the invention can be synthesized even in the form of a single sequence or in the form of several sequences which are then attached to one another. The chemical synthesis can be carried out in solid phase or in solution, these two techniques for synthesis being well known to those skilled in the art. These techniques are in particular described by Atherton and Shepard in “solid phase peptide synthesis” (IRL press Oxford, 1989) and by Houbenweyl in “method der organischen chemie” edited by E. Wunsch vol, 15-I and II thieme, Stuttgart, 1974, and also in the following articles: Dawson P E et al (Synthesis of proteins by native chemical ligation Science 1994;266(5186): 776-9); Kochendoerfer G G et al (Chemical protein synthesis. Curr Opin Chem Biol 1999;3(6): 665-71); and Dawson P E et al Synthesis of native proteins by chemical ligation, Annu Rev Biochem 2000;69:923-60.
The polypeptide according to the invention can also be produced using genetic engineering techniques which are well known to those skilled in the art. These techniques are described in detail in Molecular Cloning: a molecular manual, by Maniatis et al. (Cold Spring Harbor, 1989). Conventionally, the DNA sequence encoding the polypeptide according to the invention is inserted into an expression vector, which is mutated by site-directed mutagenesis. When several mutations must be introduced, a first mutagenesis reaction is carried out and then the resulting mutated plasmid is used as a matrix for carrying out the second mutagenesis reaction in order to obtain the plasmid comprising the double mutation. When two mutations are separated by less than 5 amino acids, these two mutations are carried out simultaneously with a single oligonucleotide which carries the two mutations.
The expression vector containing the mutated sequence is then used to transform a host cell which allows expression of the sequence of interest. The polypeptide produced is then isolated from the culture medium using conventional techniques which are well known to those skilled in the art, such as ethanol precipitation or ammonium sulfate precipitation, acid extraction, anion/cation exchange chromatography, phosphocellulose chromatography, hydrophobic interaction chromatography, affinity chromatography, hydroxyapatite chromatography and lectin chromatography. Preferably, high performance liquid chromatography (HPLC) is used in the purification.
The purified polypeptide may be in various forms depending on the expression system used (secreted or nonsecreted protein) and the purification process. It may be in a denatured or nondenatured, monomeric or multimeric form. When it is in a denatured form, it is possible to return it to its open conformation according to the invention using the process described in Example 1. In order to obtain multimeric forms and in particular trimers, the purified polypeptide molecules must be placed in a medium in which the molecules are completely soluble, have no interactions with one another and preferably have no secondary structure. For this, detergents such as sodium dodecyl sulfate, N lauryl sarcosine, guanidinium chloride, urea, sodium thiocyanate or chaotropic agents may be used. The desired conditions may be promoted by using organic solvents or acids. Once this first condition is satisfied, the sample is placed in a dialysis cassette in order to remove some of the chaotropic agents, in such a way as to promote the interactions between the polypeptide monomers while maintaining sufficient solubility for the molecules. In a second step, the formation of the trimers having been promoted, the sample is thoroughly dialyzed in a physiological medium which maintains the polypeptide solution or in suspension. Trimers of the polypeptide according to the invention, in an open conformation, are then obtained. Such a technique is described in detail in WO 00/08167.
Any expression vector conventionally used for expressing a recombinant protein may be used in the context of the present invention. This term therefore encompasses both “living” expression vectors, such as viruses and bacteria, and expression vectors of the plasmid type.
Use is preferably made of vectors in which the DNA sequence of the polypeptide according to the invention is under the control of a strong promoter which may be inducible or noninducible. By way of example of a promoter which may be used, mention may be made of the T7 RNA polymeraze promoter.
The expression vectors preferably include at least one selection marker. Such markers include, for example, dihydrofolate reductase or neomycin resistance, for culturing eukaryotic cells, and kanamycin, tetracycline or ampicillin resistance genes for culturing in E. coli and other bacteria.
By way of an expression vector which may be used in the context of the present invention, mention may be made of the plasmids pET28 (Novagen) or pBAD (Invitrogen) for example; and viral vectors such as: baculoviruses, pox viruses, in particular the pox viruses described in U.S. Pat. Nos. 5,942,235, 5,756,103 and 5,990,091, or recombinant vaccinia viruses, in particular the recombinant viruses described in patents EP 83286, U.S. Pat. No. 5,494,807 and U.S. Pat. No. 5,762,938.
The site-directed mutagenesis is carried out according to the conventional techniques commonly employed by those skilled in the art, for example using the Pfu polymerase (Quick Change Mutagenesis Kit, Stratagene) or the bio rad mutagenesis kit. The mutations are confirmed by sequencing in the usual manner. This type of method is described in detail in Maniatis et al. (Molecular cloning, a laboratory manual, cf. above).
In order to promote the expression and purification of the polypeptide, the latter may be expressed in a modified form, such as a fusion protein, and may include not only secretion signals but also additional heterologous functional regions. For example, a region containing additional amino acids, particularly charged amino acids, may be added to the N-terminal of the polypeptide in order to improve stability and persistence in the host cell.
Any host cell conventionally used in combination with the expression vectors described above may be used for the expression of the polypeptide.
By way of nonlimiting example, mention may be made of the E. coli cells BL21 (λDE3), HB101, Top 10, CAG 1139, Bacillus and eukaryotic cells such as CHO or Vero.
In the context of the present invention, the following expression vector/cell system: pET(Cer)/BL21LamdaDE3 or BL21lamdaDE3(RIL) will preferably be used.
The polypeptides of the present invention may be glycosylated or nonglycosylated, depending on the host employed in the procedure for production via the recombinant pathway. In addition, the polypeptides of the invention may also include an additional N-terminal methionine residue.
A subject of the present invention is also the conjugates comprising a polypeptide according to the invention and a carrier protein or a carrier peptide. The carrier protein (or peptide) reinforces the immunogenicity of the polypeptide according to the invention, in particular by increasing the production of specific antibodies. Said carrier protein (or peptide) preferably comprises one or more helper-T epitope(s). The term “helper-T epitope” is intended to mean an amino acid chain which, in the context of one or more class II MHC molecules, activates helper T lymphocytes. According to an advantageous embodiment, the carrier protein (or peptide) used improves the water-solubility of the polypeptide according to the invention.
As a carrier protein, use may be made, for example, of phage surface proteins, such as the pIII or pVIII of the protein M13 phage, bacterial surface proteins, such as the LamB, OmpC, ompA, ompF and PhoE proteins of E. coli, the CotC or CotD protein of B. Subtilis, bacterial porines, such as porine P1 of Neisseria gonorrheae, porine P1 or P2 of H. influenzae B, the class I porine of N. meningitidis B or porine P40 of K. pneumoniae, lipoproteins, such as OspA of B. bugdorfi, PspA of S. pneumoniae, TBP2 of N. meningitidis B, TraT of E. coli and also adhesin A of S. pneumoniae, and the heat shock proteins, such as Hsp65 or Hsp71 of M. tuberculosis or bovis, or Hin 47 of H. influenzae type B. Detoxified bacterial toxins, such as tetanus or diphtheria toxoid, the B subunit of cholera toxin, or the B subunit of endotoxin A of P. aeruginosa or exotoxin A of S. aureus, are also particularly suitable in the context of the present invention.
In the context of the present invention, carrier peptides which may be used include, for example, the p24E, p24N, p24H and p24M peptides described in WO 94/29339, and also the PADRE peptides as described by Del guercio et al (Vaccine (1997); vol 15/4, p441-448).
The carrier protein (or peptide) is linked to the N- or C-terminal end of the polypeptide according to the invention using any conjugation process which is well known to those skilled in the art. In addition, the sequence encoding the carrier protein (or peptide) may advantageously be fused to the sequence encoding the polypeptide according to the invention, and the resulting sequence may be expressed in the form of a fusion protein using any conventional process. All the genetic engineering techniques which can be used to do this are described in Maniatis et al. Said conjugates can be isolated using any conventional purification process which is well known to those skilled in the art.
A subject of the present invention is also the DNA sequences encoding the polypeptides and the conjugates according to the invention, and also the expression vectors comprising said sequences and the host cells transformed with said vectors.
Rather than extracting and purifying the polypeptide or the conjugate expressed by the expression vector, it is often easier and sometimes more advantageous to use the expression vector itself in the vaccine according to the invention. A subject of the present invention is therefore also any expression vector as defined above.
A host cell as defined above which is transformed with such an expression vector is included in the context of the present invention.
A subject of the present invention is also the antibodies directed against the polypeptides and conjugates as described above. Such antibodies are prepared using the conventional techniques for producing polyclonal and monoclonal antibodies, which are well known to those skilled in the art.
These antibodies are particularly suitable for use in a passive immunization scheme.
A subject of the present invention is also vaccines which can be used for therapeutic and prophylactic purposes. The vaccines according to the present invention comprise at least one polypeptide, at least one conjugate or at least one expression vector as defined above, a pharmaceutically acceptable support or diluent and, optionally, an adjuvant.
The amount of polypeptide, conjugate or of vector in the vaccine according to the present invention depends on many parameters, as will be understood by those skilled in the art, such as the nature of the carrier protein, the vector used or the route of administration. A suitable amount is an amount such that a humoral immune response capable of neutralizing primary isolates of HIV is induced after administration of the latter. The amount of polypeptide to be administered is about 10 to 100 micrograms. The amount of conjugate to be administered will be deduced from the amounts indicated above, taking into account the MW of the carrier protein. The amount of expression vector to be administered is about 10 to 5000 micrograms in the case of a nonviral vector and about 10E4 to 10E8 TCID50 in the case of a viral vector.
The vaccines according to the present invention may also contain an adjuvant. Any pharmaceutically acceptable adjuvant or mixture of adjuvants may be used for this purpose. By way of example, mention may be made of aluminum salts, such as aluminum hydroxide or aluminum phosphate. Conventional auxiliary agents, such as wetting agents, fillers, emulsifiers, buffers etc., may also be added to the vaccine according to the invention.
The vaccines according to the present invention can be prepared using any conventional process which is known to those skilled in the art. Conventionally, the antigens according to the invention are mixed with a pharmaceutically acceptable support or diluent, such as water or phosphate buffered saline solution. The support or diluent will be selected as a function of the pharmaceutical form chosen, of the mode and route of administration and of pharmaceutical practice. Suitable supports or diluents and the requirements concerning pharmaceutical formulation are described in detail in Remington's Pharmaceutical Sciences, which represents a reference work in this field.
The vaccines mentioned above may be administered by any conventional route normally used in the field of vaccines, such as the parenteral (intravenous, intramuscular, subcutaneous, etc.) route. In the context of the present invention, intramuscular administration will preferably be used. Such an administration can advantageously be carried out in the muscles of the thigh or of the arm. Administration via the nasal, oral, vaginal or rectal mucous membrane route may also be recommended in the context of the present invention. The administration can be carried out by administering a single dose or repeat doses, for example on D0, at 1 month, at 3 months, at 6 months and at 12 months. Injections on D0, at 1 month and at 3 months, with a booster, the frequency of which may be easily determined by the treating physician, will preferably be used.
The vaccine according to the present invention may advantageously be administered according to a posology scheme comprising the co-administration of an expression vector according to the invention and of a polypeptide according to the invention, or according to a prime-boost scheme in which the vector according to the invention is administered first and the polypeptide is administered as a booster injection. In these two posology schemes, the expression vector according to the invention may be replaced with any expression vector expressing one or more HIV antigens or epitopes other than the polypeptide according to the invention, and in particular with an ALVAC or NYVAC vector.
The present invention is also understood to cover a polypeptide, conjugate or a vector as defined above and the vaccine containing these compounds, for their use in inducing antibodies which neutralize primary isolates of HIV.
The applicant has demonstrated, surprisingly, that the polypeptide according to the invention is capable, after administration, of inducing antibodies which are capable of neutralizing primary isolates of HIV. These antigens therefore represent valuable candidates for developing a vaccine which can be used for the protection and/or treatment of a great number, or even all, of the individuals at risk or infected with HIV.
The present invention therefore also relates to a method for inducing an immune response in a host individual, including humans, comprising the administration of a vaccine according to the invention. The term “an immune response” is intended to mean a response comprising the production of antibodies directed specifically against the polypeptide according to the invention. The production of specific antibodies can be easily determined using conventional techniques which are well known to those skilled in the art, such as ELISA, IRA or Western blot. The present invention thus also provides a method of induction of antibodies neutralizing HIV comprising administratioon to a mammal of an efficient amount of a polypeptide of the invention. An efficient amount is an amount which is sufficient to induce the formation of neutralizing antibodies. The person ssskilled in the art can easily determined the amount appropriate for each patient.
A subject of the invention is also a diagnostic method comprising bringing a polypeptide according to the invention into contact with a biological sample and detecting the antibody/polypeptide complexes formed.
The polypeptide of the present invention can indeed be used in ELISA assays to detect anti-gp41 antibodies present in the serum of patients. The polypeptide of the present invention is thus useful as a diagnostic tool since the presence of anti-gp41 antibodies is a reliable marker of an HIV infection.
In such a case the polypeptide of the invention is coated on an ELISA plate, contacted with serial dilutions of the patient serum to be tested and then contacted with a enzyme-linked anti-human antibody. The anti-human antibody/anti-gp41 antibody/polypeptide complex thus formed is then detected by colorimetric detection.
The present invention will be described in greater detail in the examples which follow, with reference to the attached figures in which:
The examples described below are given purely by way of illustration of the invention and cannot in any way be considered as limiting the scope of the latter.
The DNA sequence encoding the polypeptide identified in
The vector used is pET-CER, which is constructed from the vector pET28 from Novagen. The commercial vector pET28c was amplified by PCR using 2 primers located on either side of the region corresponding to the origin F1, in such a way that the amplified product corresponds to virtually the entire vector of origin, less the region comprising the origin F1. The unique AscI and Pacd restriction sites are provided, respectively, by the two primers which have been used for the amplification. In parallel, the CER fragment is amplified using two primers which make it possible to obtain this fragment bordered by AscI and Pacd sites.
The CER fragment and vector are digested with the AscI and Pacd enzymes and then ligated to one another. This vector in particular comprises an expression cassette under the control of the T7 promoter, a polylinker downstream of the T7 promoter, for cloning the gene of interest, the CER fragment located downstream of the polylinker, making it possible to decrease the multimerization of the plasmids, a T7 term transcription terminator and the kanamycin resistance gene.
Positive regulation of the promoter is obtained in the presence of T7 RNA polymeraze.
The site-directed mutagenesis for producing the mutated polypeptides according to the invention is carried out using the QuickChange site-directed mutagenesis kit from Stratagene.
For each mutation, two mutagenesis oligonucleotides which border the amino acid to be mutated are defined. For example, for the R51A mutation, the following oligonucleotides are used:
The 2 oligonucleotides will hybridize to the same sequence on the complementary strands of the plasmid containing the sequence to be mutated. The mutation is located at the center of the oligonucleotides and it is bordered by 12 nucleotides on each side.
The mutagenesis reaction is carried out on the plasmid of Example 1 under the following conditions: a mixture containing: 5 μl 10× reaction buffer; 1 μl plasmid to be mutated, 100 ng/μl; 1 μl 5'Oligo (125 ng/μl); 1 μl 3'Oligo (125 ng/μl); 1 μl 10 mM dNTP Mix; 40 μl UF H2O; and 1 μl Pyrococcus furiosus heat-stable polymeraze, 2.5 U/μL, is subjected to a PCR according to the cycles defined below: 95° C., 30″; 95° C., 30″; 55° C., 1′; 68° C., 2′/kpb of plasmid; 12 cycles; temperatures at the end of the reaction: 20° C.
Using the protocol above, the various mutants identified in Table 1 were prepared.
The expression of the plasmids derived from step 2 above is carried out in E. coli.
To do this, a modified E. coli strain is used: BL21 IRLλDE3.
This strain is enriched in rare tRNAs (ARG, ILE, LEU); it contains the gene encoding T7 RNA polymerase, which gene is under the control of the lac UV5 promoter which can be induced by adding IPTG at a concentration of 1 mM. Initially, the strain is transformed with the mutated plasmid according to the protocol comprising the following steps: 3 colonies are subcultured in 10 ml of LB+ANTIBIOTIC; they are incubated overnight at 37° C.; the preculture is re-seeded at 1:100 in 15 ml of LB+ANTIBIOTIC; it is allowed to grow until an OD600 of 0.5 is obtained; 1 ml is removed in order to verify the OD600; 7 ml are removed for the noninduced sample; the other 7 ml are induced with 1 mM of IPTG and induction carried out for 3H at 37° C.
The same protocol was carried out on several liters of culture in order to produce a large amount of bacteria for purifying the mutated polypeptide.
The cell pellet made up of the bacteria harvested from one liter of culture medium is thawed and taken up in 2×100 ml of 30 mM Tris buffer at pH8 in the presence of a protease inhibitor (Pefabloc, Interchim) at a concentration of 100 μM. Lysozyme is added at the concentration of 100 μg/ml and the mixture is incubated for 30 minutes at room temperature. The cells are then ruptured by sonication (4 cycles of two minutes) with an approximate power of 150 watts. The gp41 is in the form of inclusion bodies. They are washed in a PBS-0.05% tween 20 buffer at 4° C. and centrifuged for 15 minutes at 10,000 g. After removing the supernatant, the centrifugation pellet composed essentially of the inclusion bodies is solubilized over one hour at room temperature with gentle stirring in the presence of 50 ml of CAPS buffer at pH 10.4 containing 3% of N-lauryl sarcosine.
The solubilized fraction is then dialyzed at 4° C. against a 30 mM Tris buffer at pH 8 containing 8 M urea (5 bars), filtered through a filter with a porosity of 0.45 μm and then loaded onto a 1 ml high Hi-Trap column (Pharmacia). These affinity chromatography supports chelate nickel atoms to which the histidine residues of the C-terminal end of the protein attach.
After washing, the protein is eluted in the 30 mM Tris buffer at pH 8 containing 8M urea and 500 mM imidazole. The eluted fractions are dialyzed in a 30 mM Tris buffer at pH8 containing 8M urea, but with no imidazole, and with decreasing amounts of urea, ranging down to 2M. This technique makes it possible to purify all the mutant or native gp41 molecules in the presence or absence of the fusion peptide.
The tested immunogen corresponds to the polypeptide according to the present invention of sequence SEQ ID NO2 in which the I101D mutation has been introduced by directed mutagenesis and which comprises a C terminal HIS tag sequence in order to facilitate the purification. Preparation of the immunogen was done according to the processes described in the preceding examples.
Groups of 5 guinea-pigs were immunized 3 times by the intramuscular route (into the thigh, in the biceps femoris muscle) at 3 week intervals (days 1, 22 and 43) with 20 μg per dose of either native gp41 or polypeptide I101D in the presence of 6 mg of aluminium phosphate. The immunogen was administered under a volume of 0.5 ml, ie 0.25 ml in each thigh. Serum samples were taken at D1, D43 and D57. Individual immune sera (D43) and pools per group of preimmune sera (D1) were tested by ELISA for their IgG antibody titers induced against native gp41 and gp 160 MN/LAI-2.
Individual immune sera (D57) and pools of 2 groups of preimmune sera (D1) were evaluated for their seroneutralizing activity against primary HIV-1 isolate Bx08.
The results thus obtained clearly demonstrated that the polypeptide of the invention is as immunogen as the native gp41. Furthermore, the neutralization assay of C. Moog et al has shown that the polypeptide of the invention induces neutralizing antibodies (% of reduction>of a factor 10).
This application claims the benefit of U.S. Provisional Application No. 60/267,165, filed Feb. 7, 2001.
Number | Date | Country |
---|---|---|
WO 00 08167 | Feb 2000 | WO |
WO 00 40616 | Jul 2000 | WO |
WO 01 44286 | Jun 2001 | WO |
WO 01 70262 | Sep 2001 | WO |
Number | Date | Country | |
---|---|---|---|
20030082521 A1 | May 2003 | US |
Number | Date | Country | |
---|---|---|---|
60267165 | Feb 2001 | US |