Avian polynucleotide formula

Abstract

The avian vaccine formula comprises at least three polynucleotide vaccine valencies each comprising a plasmid integrating, so as to express it in vivo in the host cells, a gene with one avian pathogen valency, these valencies being selected from the group consisting of Marek's disease virus, Newcastle disease virus, infectious bursal disease virus, infectious bronchitis virus, infectious anaemia virus, the plasmids comprising, for each valency, one or more of the genes selected from the group consisting of gB and gD for the Marek's disease virus, HN and F for the Newcastle disease virus, VP2 for the infectious bursal disease virus, S, M and N for the infectious bronchitis virus, C+NS1 for the infectious anaemia virus.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

All of the above-mentioned applications, as well as all documents cited herein and documents referenced or cited in documents cited herein, are hereby incorporated herein by reference. Vectors of vaccines or immunological compositions of the aforementioned applications, as well as of documents cited herein or documents referenced or cited in documents cited herein or portions of such vectors (e.g., one or more or all of regulatory sequences such as DNA for promoter, leader for secretion, terminator), may to the extent practicable with respect to the preferred host of this application, also be employed in the practice of this invention; and, DNA for vectors of vaccines or immunological compositions herein can be obtained from available sources and knowledge in the art, e.g., GeneBank, such that from this disclosure, no undue experimentation is required to make or use such vectors.

The present invention relates to a vaccine formula allowing the vaccination of avian species, in particular chickens. It also relates to a corresponding method of vaccination.

2. Description of Related Art Including Information Disclosed Under 37 C.F.R. §1.97 and 37 C.F.R. §1.98

Associations of vaccines against a number of viruses responsible for pathologies in chicken have already been proposed in the past.

The associations developed so far were prepared from inactivated vaccines or live vaccines. Their use poses problems of compatibility between valencies and of stability. It is indeed necessary to ensure both the compatibility between the different vaccine valencies, whether from the point of view of the different antigens used from the point of view of the formulations themselves. The problem of the conservation of such combined vaccines and also of their safety especially in the presence of an adjuvant also exists. These vaccines are in general quite expensive.

Patent applications WO-A-90 11092, WO-A-92 19183, WO-A-94 21797 and WO-A-95 20660 have made use of the recently developed technique of polynucleotide vaccines. It is known that these vaccines use a plasmid capable of expressing, in the host cells, the antigen inserted into the plasmid. All the routes of administration have been proposed (intraperitoneal, intravenous, intramuscular, transcutaneous, intradermal, mucosal and the like). Various vaccination means can also be used, such as DNA deposited at the surface of gold particles and projected so as to penetrate into the animal's skin (Tang et al., Nature, 356, 152-154, 1992) and liquid jet injectors which make it possible to transfect at the same time the skin, the muscle, the fatty tissues and the mammary tissues (Furth et al., Analytical Biochemistry, 205, 365-368, 1992). (See also U.S. Pat. Nos. 5,846,946, 5,620,896, 5,643,578, 5,580,589, 5,589,466, 5,693,622, and 5,703,055; Science, 259:1745-49, 1993; Robinson et al., seminars in IMMUNOLOGY, 9:271-83, 1997; Luke et al., J. Infect. Dis. 175(1):91-97, 1997; Norman et al., Vaccine, 15(8):801-803, 1997; Bourne et al., The Journal of Infectious Disease, 173:800-7, 1996; and, note that generally a plasmid for a vaccine or immunological composition can comprise DNA encoding an antigen operatively linked to regulatory sequences which control expression or expression and secretion of the antigen from a host cell, e.g., a mammalian cell; for instance, from upstream to downstream, DNA for a promoter, DNA for a eukaryotic leader peptide for secretion, DNA for the antigen, and DNA encoding a terminator.)

The polynucleotide vaccines may also use both naked DNAs and DNAs formulated, for example, inside lipids or cationic liposomes.

BRIEF SUMMARY OF THE INVENTION

The invention therefore proposes to provide a multivalent vaccine formula which makes it possible to ensure vaccination against a number of pathogenic avian viruses.

Another objective of the invention is to provide such a vaccine formula combining different valencies while exhibiting all the criteria required for mutual compatibility and stability of the valencies.

Another objective of the invention is to provide such a vaccine formula which makes it possible to combine different valencies in the same vehicle.

Another objective of the invention is to provide such a vaccine which is easy and inexpensive to use.

Yet another objective of the invention is to provide a method for vaccinating Gallinaceans which makes it possible to obtain protection, including multivalent protection, with a high level of efficiency and of long duration, as well as good safety and an absence of residues.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows plasmid pVR1012.

FIG. 2 shows plasmid pAB045.

FIG. 3 shows plasmid pAB080.

FIG. 4 shows the sequence of the NDV HN gene, Texas GB strain (SEQ ID NO:7).

FIG. 5 shows plasmid pAB046.

FIG. 6 shows the sequence of the NDV F gene, Texas GB strain (SEQ ID NO:10).

FIG. 7 shows plasmid pAB047.

FIG. 8 shows sequence of the IBDV VP2 gene, Faragher strain (SEQ ID NO:13).

FIG. 9 shows plasmid pAB048.

FIG. 10 shows the sequence of the IBV S gene, Massachusetts 41 strain (SEQ ID NO:16).

FIG. 11 shows plasmid pAB049.

FIG. 12 shows the sequence of the IBV M gene, Massachusetts 41 strain (SEQ ID NO: 19).

FIG. 13 shows plasmid pAB050.

FIG. 14 shows the sequence of the IBV N gene, Massachusetts 41 strain (SEQ ID NO:22).

FIG. 15 shows plasmid pAB051.

FIG. 16 shows plasmid pAB054.

FIG. 17 shows plasmid pAB055.

FIG. 18 shows plasmid pAB076.

FIG. 19 shows plasmid pAB089.

FIG. 20 shows plasmid pAB086.

FIG. 21 shows plasmid pAB081.

FIG. 22 shows plasmid pAB082.

FIG. 23 shows plasmid pAB077.

FIG. 24 shows plasmid pAB078.

FIG. 25 shows plasmid pAB088.

FIG. 26 shows plasmid pAB079.

DETAILED DESCRIPTION OF THE INVENTION

The subject of the present invention is therefore an avian vaccine formula comprising at least three polynucleotide vaccine valencies each comprising a plasmid integrating, so as to express it in vivo in the host cells, a gene with one avian pathogen valency, these valencies being selected from the group consisting of Marek's disease virus (MDV), Newcastle's disease virus (NDV), infectious bursal disease virus (IBDV), infectious bronchitis virus (IBV), infectious anaemia virus (CAV), infectious laryngotracheitis virus (ILTV), encephalomyelitis virus (AEV or avian leukosis virus ALV), pneumovirosis virus, and avian plague virus, the plasmids comprising, for each valency, one or more of the genes selected from the group consisting of gB and gD for the Marek's disease virus, HN and F for the Newcastle disease virus, VP2 for the infectious bursal disease virus, S, M and N for the infectious bronchitis virus, C+NS1 for the infectious anaemia virus, gB and gD for the infectious laryngotracheitis virus, env and gag/pro for the encephalomyelitis virus, F and G for the pneumovirosis virus and HA, N and NP for the avian plague virus.

Valency in the present invention is understood to mean at least one antigen providing protection against the virus for the pathogen considered, it being possible for the valency to contain, as subvalency, one or more natural or modified genes from one or more strains of the pathogen considered.

Pathogenic agent gene is understood to mean not only the complete gene but also the various nucleotide sequences, including fragments which retain the capacity to induce a protective response. The notion of a gene covers the nucleotide sequences equivalent to those described precisely in the examples, that is to say the sequences which are different but which encode the same protein. It also covers the nucleotide sequences of other strains of the pathogen considered, which provide cross-protection or a protection specific for a strain or for a strain group. It also covers the nucleotide sequences which have been modified in order to facilitate the in vivo expression by the host animal but encoding the same protein.

Preferably, the vaccine formula according to the invention comprises three valencies chosen from Marek, infectious bursal, infectious anaemia and Newcastle. The infectious bronchitis valency can also preferably be added thereto.

On this basis of 3, 4 or 5 valencies, it will be possible to add one or more of the avian plague, laryngotracheitis, pneumovirosis and encephalomyelitis valencies.

As regards the Marek valency, two genes may be used encoding gB and gD, in different plasmids or in one and the same plasmid. The use of the gB gene alone is however preferred.

For the Newcastle valency, the two HN and F chains, integrated into two different plasmids or into one and the same plasmid, are preferably used.

For the infectious bronchitis valency, the use of the S gene is preferred. Optionally, but less preferably, S and M can be associated in a single plasmid or in different plasmids.

For the infectious anaemia valency, the two C and NS1 genes are preferably associated in the same plasmid.

For the infectious laryngotracheitis valency, the use of the gB gene alone is preferred. Optionally, but less preferably, the two gB and gD genes can be associated in different plasmids or in one and the same plasmid.

For the pneumovirosis valency, the use of the two F and G genes, in a single plasmid or in different plasmids, is preferred

For the avian plague valency, the use of the HA gene is preferred. Optionally, but less preferably, it is possible to use the associations HA and NP or HA and N in different plasmids or in one and the same plasmid. Preferably, the HA sequences from more than one influenza virus strain, in particular from the different strains found in the field, are preferably associated in the same vaccine. On the other hand, NP provides cross-protection and the sequence from a single virus strain will therefore be satisfactory.

For the encephalomyelitis valency, the use of env is preferred.

The vaccine formula according to the invention can be presented in a dose volume of between 0.1 and 1 ml and in particular between 0.3 and 0.5 ml.

The dose will be generally between 10 ng and 1 mg, preferably between 100 ng and 500 μg and preferably between 0.1 μg and 50 μg per plasmid type.

Use will be preferably made of naked plasmids, simply placed in the vaccination vehicle which will be in general physiological saline and the like. It is of course possible to use all the polynucleotide vaccine forms described in the prior art and in particular formulated in liposomes.

Each plasmid comprises a promoter capable of ensuring the expression of the gene inserted, under its control, into the host cells. This will be in general a strong eukaryotic promoter and in particular a cytomegalovirus early CMV-IE promoter of human or murine origin, or optionally of another origin such as rats, pigs and guinea pigs.

More generally, the promoter may be either of viral origin or of cellular origin. As viral promoter other than CMV-IE, there may be mentioned the SV40 virus early or late promoter or the Rous sarcoma virus LTR promoter. It may also be a promoter from the virus from which the gene is derived, for example the gene's own promoter.

As cellular promoter, there may be mentioned the promoter of a cytoskeleton gene, such as, for example, the desmin promoter (Bolmont et al., Journal of Submicroscopic Cytology and Pathology, 1990, 22, 117-122; and Zhenlin et al., Gene, 1989, 78, 243-254), or alternatively the actin promoter.

When several genes are present in the same plasmid, these may be presented in the same transcription unit or in two different units.

The combination of the different vaccine valencies according to the invention may be preferably achieved by mixing the polynucleotide plasmids expressing the antigen(s) of each valency, but it is also possible to envisage causing antigens of several valencies to be expressed by the same plasmid.

The subject of the invention is also monovalent vaccine formulae comprising one or more plasmids encoding one or more genes from one of the viruses above, the genes being those described above. Besides their monovalent character, these formulae may possess the characteristics stated above as regards the choice of the genes, their combinations, the composition of the plasmids, the dose volumes, the doses and the like.

The monovalent vaccine formulae may also be used (i) for the preparation of a polyvalent vaccine formula as described above, (ii) individually against the actual pathology, (iii) associated with a vaccine of another type (live or inactivated whole, recombinant, subunit) against another pathology, or (iv) as booster for a vaccine as described below.

The subject of the present invention is in fact also the use of one or more plasmids according to the invention for the manufacture of an avian vaccine intended to vaccinate animals first vaccinated by means of a first conventional vaccine (monovalent or multivalent) of the type in the prior art, in particular selected from the group consisting of a live whole vaccine, an inactivated whole vaccine, a subunit vaccine, a recombinant vaccine, this first vaccine having (that is to say containing or capable of expressing) the antigen(s) encoded by the plasmids or antigen(s) providing cross-protection.

Remarkably, the polynucleotide vaccine has a potent booster effect which results in an amplification of the immune response and the acquisition of a long-lasting immunity.

In general, the first-vaccination vaccines can be selected from commercial vaccines available from various veterinary vaccine producers.

The subject of the invention is also a vaccination kit grouping together a vaccine formula according to the invention and a first-vaccination vaccine as described above. It also relates to a vaccine formula according to the invention accompanied by a leaflet indicating the use of this formula as a booster for a first vaccination as described above.

The subject of the present invention is also a method of avian vaccination, comprising the administration of an effective vaccine formula as described above. This vaccination method comprises the administration of one or more doses of the vaccine formula, it being possible for these doses to be administered in succession over a short period of time and/or in succession at widely spaced intervals.

The vaccine formulae according to the invention can be administered in the context of this method of vaccination, by the different routes of administration proposed in the prior art for polynucleotide vaccination and by means of known techniques of administration.

The intramuscular route, the in ovo route, the intraocular route, nebulization and drinking water will be targeted in particular.

The efficiency of presentation of the antigens to the immune system varies according to the tissues. In particular, the mucous membranes of the respiratory tree serve as barrier to the entry of pathogens and are associated with lymphoid tissues which support local immunity. In addition, the administration of a vaccine by contact with the mucous membranes, in particular the buccal mucous membrane, the pharyngeal mucous membrane and the mucous membrane of the bronchial region, is certainly of interest for mass vaccination.

Consequently, the mucosal routes of administration form part of a preferred mode of administration for the invention, using in particular neubilization or spray or drinking water. It will be possible to apply the vaccine formulae and the vaccination methods according to the invention in this context.

The subject of the invention is also the method of vaccination consisting in making a first vaccination as described above and a booster with a vaccine formula according to the invention.

In a preferred embodiment of the process according to the invention, there is administered in a first instance, to the animal, an effective dose of the vaccine of the conventional, especially inactivated, live, attenuated or recombinant, type, or alternatively a subunit vaccine so as to provide a first vaccination, and, after a period preferably of 2 to 6 weeks, the polyvalent or monovalent vaccine according to the invention is administered.

The invention also relates to the method of preparing the vaccine formulae, namely the preparation of the valencies and mixtures thereof, as evident from this description.

The invention will now be described in greater detail with the aid of the embodiments of the invention taken with reference to the accompanying drawings.

EXAMPLE 1

Culture of the viruses

The viruses are cultured on the appropriate cellular system until a cytopathic effect is obtained. The cellular systems to be used for each virus are well known to persons skilled in the art. Briefly, the cells sensitive to the virus used, which are cultured in Eagle's minimum essential medium (MEM medium) or another appropriate medium, are inoculated with the viral strain studied using a multiplicity of infection of 1. The infected cells are then incubated at 37° C. for the time necessary for the appearance of a complete cytopathic effect (on average 36 hours).

EXAMPLE 2

Extraction of the viral genomic DNAs

After culturing, the supernatant and the lysed cells are harvested and the entire viral suspension is centrifuged at 1000 g for 10 minutes at +4° C. so as to remove the cellular debris. The viral particles are then harvested by ultracentrifugation at 400,000 g for 1 hour at +4° C. The pellet is taken up in a minimum volume of buffer (10 mM Tris, 1 mM EDTA). This concentrated viral suspension is treated with proteinase K (100 μg/ml final) in the presence of sodium dodecyl sulphate (SDS) (0.5% final) for 2 hours at 37° C. The viral DNA is then extracted with a phenol/chloroform mixture and then precipitated with 2 volumes of absolute ethanol. After leaving overnight at −20° C., the DNA is centrifuged at 10,000 g for 15 minutes at +4° C. The DNA pellet is dried and then taken up in a minimum volume of sterile ultrapure water. It can then be digested with restriction enzymes.

EXAMPLE 3

Isolation of the viral genomic RNAs

The RNA viruses were purified according to techniques well known to persons skilled in the art. The genomic viral RNA of each virus was then isolated using the “guanidium thiocyanate/phenol-chloroform” extraction technique described by P. Chromczynski and N. Sacchi (Anal. Biochem., 1987. 162, 156-159).

EXAMPLE 4

Molecular biology techniques

All the constructions of plasmids were carried out using the standard molecular biology techniques described by J. Sambrook et al. ( Molecular Cloning: A Laboratory Manual, 2nd Edition, Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y., 1989). All the restriction fragments used for the present invention were isolated using the “Geneclean” kit (BIO 101 Inc. La Jolla, Calif.).

EXAMPLE 5

RT-PCR technique

Specific oligonucleotides (comprising restriction sites at their 5′ ends to facilitate the cloning of the amplified fragments) were synthesized such that they completely cover the coding regions of the genes which are to be amplified (see specific examples). The reverse transcription (RT) reaction and the polymerase chain reaction (PCR) were carried out according to standard techniques (Sambrook J. et al., 1989). Each RT-PCR reaction was performed with a pair of specific amplimers and taking, as template, the viral genomic RNA extracted. The complementary DNA amplified was extracted with phenol/chloroform/isoamyl alcohol (25:24:1) before being digested with restriction enzymes.

EXAMPLE 6

Plasmid pVR1012

The plasmid pVR1012 ( FIG. 1 ) was obtained from Vical Inc., San Diego, Calif., USA. Its construction has been described in J. Hartikka et al. (Human Gene Therapy, 1996, 7, 1205-1217).

EXAMPLE 7

Construction of the plasmid pAB045 (MDV gB gene)

A PCR reaction was carried out with the Marek's disease virus (MDV) (RB1B strain) (L. Ross et al., J. Gen. Virol., 1989, 70, 1789-1804) genomic DNA, prepared according to the technique in Example 2, and with the following oligonucleotides:

AB062 (37 mer) (SEQ ID No. 1) 5′ AAAACTGCAGACTATGCACTATTTTAGGCGGAATTGC 3′

AB063 (35 mer) (SEQ ID No. 2) 5′ GGAAGATCTTTACACAGCATCATCTTTCTGAGTCTG 3′

so as to isolate the gene encoding the gB glycoprotein from the MDV virus in the form of a PstI-BglII fragment. After purification, the 2613 bp PCR product was digested with PstI and BglI in order to isolate a 2602 bp PstI-BglII fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with PstI and BglII, to give the plasmid pAB045 (7455 bp) (FIG. 2 ).

EXAMPLE 8

Construction of the plasmid pAB080 (MDV gD gene)

A PCR reaction was carried out with the Marek's disease virus (MDV) (RB1B strain) (L. Ross et al., J. Gen. Virol., 1989, 72, 949-954) genomic DNA, prepared according to the technique in Example 2, and with the following oligonucleotides:

AB148 (29 mer) (SEQ ID No. 3) 5′ AAACTGCAGATGAAAGTATTTTTTTTTAG 3′

AB149 (32 mer) (SEQ ID No. 4) 5′ GGAAGATCTTTATAGGCGGGAATATGCCCGTC 3′

so as to isolate the gene encoding the gD glycoprotein from the MDV virus in the form of a PstI-BglII fragment. After purification, the 1215 bp PCR product was digested with PstI and BglII in order to isolate a 1199 bp PstI-BglII fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with PstI and BglII, to give the plasmid pAB080 (6051 bp) (FIG. 3 ).

EXAMPLE 9

Construction of the plasmid pAB046 (NDV HN gene)

An RT-PCR reaction according to the technique of Example 5 was carried out with the Newcastle disease virus (NDV) (Texas GB strain) genomic RNA, prepared according to the technique of Example 3, and with the following oligonucleotides:

AB072 (39 mer) (SEQ ID No. 5) 5′ AGAATGCGGCCGCGATGGGCTCCAGATCTTCTACCAG 3′

AB094 (34 mer) (SEQ ID No. 6) 5′ CGCGGATCCTTAAATCCCATCATCCTTGAGAATC 3′

so as to isolate the gene encoding the HN glycoprotein from the NDV virus, Texas GB strain (FIG. 4 and SEQ ID No. 7) in the form of an NotI-BamHI fragment. After purification, the 1741 bp RT-PCR product was digested with NotI and BamHI in order to isolate a 1723 bp NotI-BamHI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with NotI and BamHI, to give the plasmid pAB046 (6616 bp) (FIG. 5 ).

EXAMPLE 10

Construction of the plasmid pAB047 (NDV F gene)

An RT-PCR reaction according to the technique of Example 5 was carried out with the Newcastle disease virus (NDV) (Texas GB strain) genomic RNA, prepared according to the technique of Example 3, and with the following oligonucleotides:

AB091 (37 mer) (SEQ ID No.8) 5′ AGAATGCGGCCGCGATGGGCTCCAGATCTTCTACCAG 3′

AB092 (34 mer) (SEQ ID No. 9) 5′ TGCTCTAGATCATATTTTTGTAGTGGCTCTCATC 3′

so as to isolate the gene encoding the F glycoprotein from the NDV virus, Texas GB strain (FIG. 6 and SEQ ID No. 10) in the form of an NotI-XbaI fragment. After purification, the 1684 bp RT-PCR product was digested with NotI and XbaI in order to isolate a 1669 bp NotI-XbaI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with NotI and XbaI, to give the plasmid pAB047 (6578 bp) (FIG. 7 ).

EXAMPLE 11

Construction of the plasmid pAB048 (IBDV VP2 gene)

An RT-PCR reaction according to the technique of Example 5 was carried out with the infectious bursal disease virus (IBDV) (Faragher strain) genomic RNA, prepared according to the technique of Example 3, and with the following oligonucleotides:

AB093 (33 mer) (SEQ ID No. 11) 5′ TCAGATATCGATGACAAACCTGCAAGATCAAAC 3′

AB094 (38 mer) (SEQ ID No. 12) 5′ AGAATGCGGCCGCTTACCTCCTTATAGCCCGGATTATG 3′

so as to isolate the sequence encoding the VP2 protein from the IBDV virus, Faragher strain (FIG. 8 and SEQ ID No. 13) in the form of an EcoRV-NotI fragment. After purification, the 1384 bp RT-PCR product was digested with EcoRV and NotI in order to isolate a 1367 bp EcoRV-NotI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with EcoRV and NotI, to give the plasmid pAB048 (6278 bp) (FIG. 9 ).

EXAMPLE 12

Construction of the plasmid pABO49 (IBV S1 gene)

An RT-PCR reaction according to the technique of Example 5 was carried out with the chicken infectious bronchitis virus (IBV) (Massachusetts 41 strain) genomic RNA, prepared according to the technique of Example 3, and with the following oligonucleotides:

AB095 (32 mer) (SEQ ID No. 14) 5′ ACGCGTCGACATGTTGGTAACACCTCTTTTAC 3′

AB096 (35 mer) (SEQ ID No. 15) 5′ GGAAGATCTTCATTAACGTCTAAAACGACGTGTTC 3′

so as to isolate the sequence encoding the Si subunit of the S glycoprotein from the IBV virus, Massachusetts 41 strain (FIG. 10 and SEQ ID No. 16) in the form of a SalI-BglII fragment. After purification, the 1635 bp RT-PCR product was digested with SalI and BglII in order to isolate a 1622 bp SalI-BglII fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with SalI and BglII, to give the plasmid pAB049 (6485 bp) (FIG. 1 ).

EXAMPLE 13

Construction of the plasmid pAB050 (IBV M gene)

An RT-PCR reaction according to the technique of Example 5 was carried out with the chicken infectious bronchitis virus (IBV) (Massachusetts 41 strain) genomic RNA, prepared according to the technique of Example 3, and with the following oligonucleotides:

AB097 (37 mer) (SEQ ID No. 17) 5′ ATAAGAATGCGGCCGCATGTCCAACGAGACAAATTGTAC 3′

AB098 (38 mer) (SEQ ID No. 18) 5′ ATAAGAATGCGGCCGCTTTAGGTGTAAAGACTACTCCC 3′

so as to isolate the gene encoding the M glycoprotein from the IBV virus, Massachusetts 41 strain (FIG. 12 and SEQ ID No. 19) in the form of a NotI-NotI fragment. After purification, the 710 bp RT-PCR product was digested with NotI in order to isolate a 686 bp NotI-NotI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with NotI, to give the plasmid pAB050 (5602 bp) which contains the IBV M gene in the correct orientation relative to the promoter (FIG. 13 ).

FIG. 14 : Construction of the plasmid pAB051 (IBV N gene)

An RT-PCR reaction according to the technique of Example 5 was carried out with the chicken infectious bronchitis virus (IBV) (Massachusetts 41 strain) genomic RNA, prepared according to the technique of Example 3, and with the following oligonucleotides:

AB099 (34 mer) (SEQ ID No. 20) 5′ AAAACTGCAGTCATGGCAAGCGGTAAGGCAACTG 3′

AB100 (33 mer) (SEQ ID No. 21) 5′ CGCGGATCCTCAAAGTTCATTCTCTCCTAGGGC 3′

so as to isolate the gene encoding the N protein from the IBV virus, Massachusetts 41 strain (FIG. 14 and SEQ ID No. 22) in the form of a PstI-BamHI fragment. After purification, the 1250 bp RT-PCR product was digested with PstI and BamHI in order to isolate a 1233 bp PstI-BamHI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with PstI and BamHI, to give the plasmid pAB051 (6092 bp) (FIG. 15 ).

EXAMPLE 15

Construction of the plasmid pAB054 (VAC VP1 gene)

A PCR reaction was carried out with the chicken anaemia virus (CAV) (Cuxhaven-1 strain) genomic DNA (B. Meehan et al., Arch. Virol., 1992, 124, 301-319), prepared according to the technique of Example 2, and with the following oligonucleotides:

CD064 (39 mer) (SEQ ID No. 23) 5′ TTCTTGCGGCCGCCATGGCAAGACGAGCTCGCAGACCGA 3′

CD065 (38 mer) (SEQ ID No. 24) 5′ TTCTTGCGGCCGCTCAGGGCTGCGTCCCCCAGTACATG 3′

so as to isolate the gene encoding the CAV VP1 capsid protein in the form of an NotI-NotI fragment. After purification, the 1377 bp PCR product was digested with NotI in order to isolate a 1359 bp NotI-NotI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with NotI, to give the plasmid pAB054 (6274 bp) which contains the CAV VP1 gene in the correct orientation relative to the promoter (FIG. 16 ).

EXAMPLE 17: Construction of the plasmid pAB055 (CAV VP2 gene)

A PCR reaction was carried out with the chicken anaemia virus (CAV) (Cuxhaven-1 strain) genomic DNA (B. Meehan et al., Arch. Virol., 1992, 124, 301-319), prepared according to the technique of Example 2, and with the following oligonucleotides:

CD066 (39 mer) (SEQ ID No. 25) 5′ TTCTTGCGGCCGCCATGCACGGGAACGGCGGACAACCGG 3′

AB105 (32 mer) (SEQ ID No. 26) 5′ CGCGGATCCTCACACTATACGTACCGGGGCGG 3′

so as to isolate the gene encoding the CAV virus VP2 protein in the form of an NotI-BamHI fragment. After purification, the 674 bp PCR product was digested with NotI and BamHI in order to isolate a 659 bp NotI-BamHI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with NotI and BamHI, to give the plasmid pAB055 (5551 bp) (FIG. 17 ).

EXAMPLE 18

Construction of the plasmid pAB076 (ILTV gB gene)

A PCR reaction was carried out with the chicken infectious laryngotracheitis virus (ILTV) (SA-2 strain) genomic DNA (K. Kongsuwan et al., Virology, 1991, 184, 404-410), prepared according to the technique of Example 2, and with the following oligonucleotides:

AB140 (38 mer) (SEQ ID No. 27) 5′ TTCTTGCGGCCGCATGTCTTGAAAATGCTGATC 3′

AB141 (36 mer) (SEQ ID No. 28) 5′ TTCTTGCGGCCGCTTATTCGTCTTCGCTTTCTTCTG 3′

so as to isolate the gene encoding the ILTV virus gB glycoprotein in the form of an NotI-NotI fragment. After purification, the 2649 bp PCR product was digested with NotI in order to isolate a 2631 bp NotI-NotI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with NotI, to give the plasmid pAB076 (7546 bp) which contains the ILTV gB gene in the correct orientation relative to the promoter (FIG. 18 ).

EXAMPLE 20

Construction of the plasmid pAB089 (ILTV gD gene)

A PCR reaction was carried out with the chicken infectious laryngotracheitis virus (ILTV) (SA-2 strain) genomic DNA (M. Johnson et al., 1994, Genbank sequence accession No. =L31965), prepared according to the technique of Example 2, and with the following oligonucleotides:

AB164 (33 mer) (SEQ ID No. 29) 5′ CCGGTCGACATGGACCGCCATTTATTTTTGAGG 3′

AB165 (33 mer) (SEQ ID No. 30) 5′ GGAAGATCTTTACGATGCTCCAAACCAGTAGCC 3′

so as to isolate the gene encoding the ILTV virus gD glycoprotein in the form of an SalI-BglII fragment. After purification, the 1134 bp PCR product was digested with SalI and BglII in order to isolate a 1122 bp SalI-BglII fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with SalI-BglII, to give the plasmid pAB089 (5984 bp) (FIG. 19 ).

EXAMPLE 21

Construction of the plasmid pAB086 (AEV env gene)

An RT-PCR reaction according to the technique of Example 5 was carried out with the avian encephalomyelitis virus (AEV) (Type C) genomic RNA (E. Bieth et al., Nucleic Acids Res., 1992, 20, 367), prepared according to the technique of Example 3, and with the following oligonucleotides:

AB160 (54 mer) (SEQ ID No. 31) 5′TTTGATATCATGGAAGCCGTCATTAAGGCATTTCTGACTGGATACCCTGGGAA G3′

AB161 (31 mer) (SEQ ID No. 32) 5′TTTGGATCCTTATACTATTCTGCTTTCAGGC 3′

so as to isolate the sequence encoding the AEV virus Env glycoprotein in the form of an EcoRV-BamHI fragment. After purification, the 1836 bp RT-PCR product was digested with EcoRV and BamHI in order to isolate a 1825 bp EcoRV-BamHI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with EcoRV and BamHI, to give the plasmid pAB086 (6712 bp) (FIG. 20 ).

EXAMPLE 22

Construction of the plasmid pAB081 (AEV gag/pro gene)

An RT-PCR reaction according to the technique of Example 5 was carried out with the avian encephalomyelitis virus (AEV) (Type C) genomic RNA (E. Bieth et al., Nucleic Acids Res., 1992, 20, 367), prepared according to the technique of Example 3, and with the following oligonucleotides:

AB150 (31 mer) (SEQ ID No. 33) 5′ACGCGTCGACATGGAAGCCGTCATTAAGGTG 3′

AB151 (32 mer) (SEQ ID No. 34) 5′TGCTCTAGACTATAAATTTGTCAAGCGGAGCC 3′

so as to isolate the sequence encoding the AEV virus Gag and Pro proteins in the form of an SalI-XbaI fragment. After purification, the 2125 bp RT-PCR product was digested with SalI-XbaI in order to isolate a 2111 bp SalI-XbaI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with SalI and XbaI, to give the plasmid pAB081 (6996 bp) (FIG. 21 ).

EXAMPLE 23

Construction of the plasmid pAB082 (Pneumovirus G gene)

An RT-PCR reaction according to the technique of Example 5 was carried out with the turkey rhinotracheitis virus (TRV) (2119 strain) genomic RNA (K. Juhasz et al., J. Gen. Virol., 1994, 75. 2873-2880), prepared according to the technique of Example 3, and with the following oligonucleotides:

AB152 (32 mer) (SEQ ID No. 35) 5′AAACTGCAGAGATGGGGTCAGAGCTCTACATC 3′

AB153 (31 mer) (SEQ ID No. 36) 5° CGAAGATCTTTATTGACTAGTACAGCACCAC 3′

so as to isolate the gene encoding the TRV virus G glycoprotein in the form of a PstI-BglII fragment. After purification, the 2165 bp RT-PCR product was digested with PstI and BglII in order to isolate a 1249 bp PstI-BglII fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with PstI and BglII, to give the plasmid pAB082 (6101 bp) (FIG. 22 ).

EXAMPLE 24

Construction of the plasmid pAB077 (avian plague HA gene, H2N2 strain)

An RT-PCR reaction according to the technique of Example 5 was carried out with the avian plague virus (AIV) (H2N2 Postdam strain) genomic RNA (J. Schäfer et al., Virology, 1993, 194, 781-788), prepared according to the technique of Example 3, and with the following oligonucleotides:

AB142 (33 mer) (SEQ ID No. 37) 5′ AAACTGCAGCAATGGCCATCATTTATCTAATTC 3′

AB143 (31 mer) (SEQ ID No. 38) 5′ CGAAGATCTTCATATGCAGATTCTGCATTGC 3′

so as to isolate the gene encoding the HA glycoprotein from the avian plague virus (H2N2 strain) in the form of a PstI-BglII fragment. After purification, the 1709 bp RT-PCR product was digested with PstI and BglII in order to isolate a 1693 bp PstI-BglII fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with PstI and BglII, to give the plasmid pAB077 (6545 bp) (FIG. 23 ).

EXAMPLE 25

Construction of the plasmid pAB078 (avian plague RA gene, H7N7 strain)

An RT-PCR reaction according to the technique of Example 5 was carried out with the avian plague virus (AIV) (H7N7 Leipzig strain) genomic RNA (C. Rohm et al., Virology, 1995, 209, 664-670), prepared according to the technique of Example 3, and with the following oligonucleotides:

AB144 (31 mer) (SEQ ID No. 39) 5′AAACTGCAGATGAACACTCAAATCCTGATAC 3′

AB145 (31 mer) (SEQ ID No. 40) 5′ TTTGGATCCTTATATACAAATAGTGCACCGC 3′

so as to isolate the gene encoding the HA glycoprotein from the avian plague virus (H7N7 strain) in the form of a PstI-BamHI fragment. After purification, the 1707 bp RT-PCR product was digested with PstI and BamHI in order to isolate a 1691 bp PstI-BamHI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with PstI and BamHI, to give the plasmid pAB078 (6549 bp) (FIG. 24 ).

EXAMPLE 26

Construction of the plasmid pAB088 (avian plague NP gene, H1N1 strain)

An RT-PCR reaction according to the technique of Example 5 was carried out with the avian influenza. virus (AIV) (H1N1 Bavaria strain) genomic RNA (M. Gammelin et al., Virology, 1989, 170, 71-80), prepared according to the technique of Example 3, and with the following oligonucleotides:

AB156 (32 mer) (SEQ ID No. 41) 5′ CCGGTCGACATGGCGTCTCAAGGCACCAAACG 3′

AB158 (30 mer) (SEQ ID No. 42) 5′ CGCGGATCCTTAATTGTCATACTCCTCTGC 3′

so as to isolate the gene encoding the avian influenza virus NP nucleoprotein in the form of a SalI-BamHI fragment. After purification, the 1515 bp RT-PCR product was digested with SalI and BamHI in order to isolate a 1503 bp SalI-BamHI fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with SalI and BamHI, to give the plasmid pAB088 (6371 bp) (FIG. 25 ).

EXAMPLE 27

Construction of the plasmid pAB079 (avian plague N gene, H7N1 strain)

An RT-PCR reaction according to the technique of Example 5 was carried out with the avian plague virus (AIV) (H7N1 Rostock strain) genomic RNA (J. McCauley, 1990, Genbank sequence accession No.=X52226), prepared according to the technique of Example 3, and with the following oligonucleotides:

AB146 (35 mer) (SEQ ID No. 43) 5′ CGCGTCGACATGAATCCAAATCAGAAAATAATAAC 3′

AB147 (31 mer) (SEQ ID No. 44) 5′ GGAAGATCTCTACTTGTCAATGGTGAATGGC 3′

so as to isolate the gene encoding the N glycoprotein from the avian plague virus (H7N1 strain) in the form of an SalI-BgIII fragment. After purification, the 1361 bp RT-PCR product was digested with SalI and BglII in order to isolate a 1350 bp Sall-BglII fragment. This fragment was ligated with the vector pVR1012 (Example 6), previously digested with SallI and BglII, to give the plasmid pAB079 (6212 bp) (FIG. 26 ).

EXAMPLE 28

Preparation and purification of the plasmids

For the preparation of the plasmids intended for the vaccination of animals, any technique may be used which makes it possible to obtain a suspension of purified plasmids predominantly in the supercoiled form. These techniques are well known to persons skilled in the art. There may be mentioned in particular the alkaline lysis technique followed by two successive ultracentrifugations on a caesium chloride gradient in the presence of ethidium bromide as described in J. Sambrook et al. ( Molecular Cloning: A Laboratory Manual, 2nd edition, Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y., 1989). Reference may also be made to patent applications PCT WO 95/21250 and PCT WO 96/02658 which describe methods for producing, on an industrial scale, plasmids which can be used for vaccination. For the purposes of the manufacture of vaccines (see Example 17), the purified plasmids are resuspended so as to obtain solutions at a high concentration (>2 mg/ml) which are compatible with storage. To do this the plasmids are resuspended either in ultrapure water or in TE buffer (10 mM Tris-HCl; 1 mM EDTA, pH 8.0).

EXAMPLE 29

Manufacture of the associated vaccines

The various plasmids necessary for the manufacture of an associated vaccine are mixed starting with their concentrated solutions (Example 16). The mixtures are prepared such that the final concentration of each plasmid corresponds to the effective dose of each plasmid. The solutions which can be used to adjust the final concentration of the vaccine may be either a 0.9% NaCl solution, or PBS buffer.

Specific formulations such as liposomes, cationic lipids, may also be used for the manufacture of the vaccines.

EXAMPLE 30

Vaccination of chickens

The chickens are vaccinated with doses of 10, 50 or 100 μg per plasmid. The injections can be performed with a needle by the intramuscular route. The sites of injection are the carina (for chickens more than 2 weeks old) and the thigh (for 1-day-old or older chickens). In this case, the vaccinal doses are administered in the volume of 0.1 to 0.3 ml.

In adult chickens (more than 20 weeks old) the injections are also performed by the intramuscular route using a liquid jet injection apparatus (with no needle) which has been specially designed for the vaccination of chickens (for example AVIJET apparatus). In this case, the injected volume is 0.3 ml. The injection may be performed in the carina or at the level of the thigh. Likewise, in adult chickens, the injections may be performed with a needle by the intramuscular route, in the carina or in the thigh, in a volume of 0.3 ml. The injection of the plasmid vaccines can also be done in ovo. In this case, special formulations as mentioned in Example 29 may be used. The volume injected into the 18-day embryonated egg is between 50 μl and 200 μl.

44 1 37 DNA Marek′s disease gammaherpesvirus MKT-1 1aaaactgcag actatgcact attttaggcg gaattgc 37 2 35 DNA Marek′s disease gammaherpesvirus MKT-1 2ggaagatctt tacacagcat catcttctga gtctg 35 3 29 DNA Marek′s disease gammaherpesvirus MKT-1 3aaactgcaga tgaaagtatt tttttttag 29 4 32 DNA Marek′s disease gammaherpesvirus MKT-1 4ggaagatctt tataggcggg aatatgcccg tc 32 5 39 DNA Newcastle disease virus 5ataagaatgc ggccgccatg gaccgtgcag ttagcagag 39 6 34 DNA Newcastle disease virus 6cgcggatcct taaatcccat catccttgag aatc 34 7 1716 DNA Newcastle disease virus 7atggaccgtg cagttagcag agttgcgcta gagaatgaag aaagagaagc aaagaataca 60tggcgctttg tattccggat tgcaatctta cttttaatag taacaacctt agccatctct 120gcaaccgccc tggtatatag catggaggct agcacgcctg gcgaccttgt tggcataccg 180actatgatct ctaaggcaga agaaaagatt acatctgcac tcagttctaa tcaagatgta 240gtagatagga tatataagca ggtggccctt gagtctccat tggcgttgct aaacactgaa 300tctgtaatta tgaatgcaat aacgtctctc tcttatcaaa tcaatggagc tgcaaataat 360agcgggtgtg gggcacctgt tcatgaccca gattatatcg gggggatagg caaagaactt 420attgtggatg acgctagtga tgtcacatca ttctatccct ctgcgttcca agaacacctg 480aactttatcc cggcacctac tacaggatca ggttgcactc ggataccctc attcgacata 540agcgctaccc actactgtta cactcacaat gtgatattat ctggttgcag agatcactca 600cactcatatc agtacttagc acttggcgtg cttcggacat ctgcaacagg gagggtattc 660ttttctactc tgcgttccat caatttggat gacagccaaa atcggaagtc ttgcagtgtg 720agtgcaactc ccttaggttg tgatatgctg tgctctaaaa tcacagagac tgaggaagag 780gattatagtt caattacgcc tacatcgatg gtgcacggaa ggttagggtt tgacggtcaa 840taccatgaga aggacttaga cgtcataact ttatttaagg attgggtggc aaattaccca 900ggagtggggg gtgggtcttt tattaacaac cgcgtatggt tcccagtcta cggagggcta 960aaacccaatt cgcctagtga caccgcacaa gaagggagat atgtaatata caagcgctac 1020aatgacacat gcccagatga acaagattac cagattcgga tggctaagtc ttcatataag 1080cctgggcggt ttggtggaaa acgcgtacag caggccatct tatctatcaa ggtgtcaaca 1140tctttgggcg aggacccggt gctgactgta ccgcctaata caatcacact catgggggcc 1200gaacggagag ttctcacagt agggacatct catttcttgt accagcgagg gtcttcatac 1260ttctctcctg ctttattata ccctatgaca gtcaacaaca aaacggctac tcttcatagt 1320ccttacacat tcaatgcttt cactaggcca ggtagtgtcc cttgtcaggc atcagcaaga 1380tgccccaact catgtgtcac tggagtttat actgatccgt atcccttagt cttccatagg 1440aaccatacct tgcggggggt attcgggaca atgcttgatg atgaacaagc aagacttaac 1500cctgtatctg cagtatttga taacatatcc cgcagtcgca taacccgggt aagttcaagc 1560cgtactaagg cagcatacac gacatcgaca tgttttaaag ttgtcaagac caataaaaca 1620tattgcctca gcattgcaga aatatccaat accctcttcg gggaattcag gatcgttcct 1680ttactagttg agattctcaa ggatgatggg atttaa 1716 8 37 DNA Newcastle disease virus 8agaatgcggc cgcgatgggc tccagatctt ctaccag 37 9 34 DNA Newcastle disease virus 9tgctctagat catatttttg tagtggctct catc 34 10 1662 DNA Newcastle disease virus 10atgggctcca gatcttctac caggatcccg gtacctctaa tgctgatcat ccgaaccgcg 60ctgacactga gctgtatccg tctgacaagc tctcttgatg gcaggcctct tgcggctgca 120gggatcgtgg taacaggaga taaagcagtc aacatataca cctcatccca gacagggtca 180atcatagtta agttactccc gaatatgccc aaggacaaag aggtgtgtgc aaaagcccca 240ttggaggcat acaacaggac actgactact ttactcaccc cccttggtga ttctatccgc 300aggatacaag agtctgtgac tacttccgga ggaaggagac agagacgctt tataggtgcc 360attatcggca gtgtagctct tggggttgcg acagctgcac agataacagc agcttcggcc 420ctgatacaag ccaaccagaa tgctgccaac atcctccggc ttaaagagag cattgctgca 480accaatgaag ctgtgcacga ggtcactgac ggattatcac aactagcagt ggcagtaggg 540aagatgcaac agtttgtcaa tgaccagttc aataatacag cgcaagaatt ggactgtata 600aaaattgcac agcaggtcgg tgtagaactc aacttgtacc taactgaatt gactacagta 660tttgggccac aaatcacttc ccctgcctta actcagctga ctatccaagc gctttacaat 720ctagctggtg gtaatatgga ttacttgctg actaagttag gtgtagggaa caaccaactc 780agctcattaa ttggtagcgg cttgatcacc ggcaacccta ttctgtacga ctcacagact 840cagatcttgg gtatacaggt aactttgcct tcagttggga acctgaataa tatgcgtgcc 900acctacctgg agaccttatc tgtaagcaca accaagggat ttgcctcagc acttgtccca 960aaagtggtga cacaggtcgg ttccgtgata gaagaacttg acacctcata ctgtataggg 1020accgacttgg atttatactg tacaagaata gtgacattcc ctatgtctcc tggtatttat 1080tcttgtctga gcggtaatac atcggcttgc atgtattcaa agactgaagg cgcacttact 1140acgccatata tggctctcaa aggctcagtt attgccaatt gcaagctgac aacatgtaga 1200tgtgcagatc ccccaggtat catatcgcaa aattatggag aagctgtgtc cttaatagat 1260aggcactcat gcaacgtctt atccttagac gggataactc tgaggctcag tggggaattt 1320gatgcaacct atcaaaagaa tatctctata ctagattctc aagttatagt gacaggcaat 1380cttgatatat caactgagct tgggaatgtc aacaactcaa taagtaatgc cctgaataag 1440ttagaggaaa gcaacagcaa actagacaaa gtcaatgtca aactgaccag cacatctgct 1500ctcattacct acatcgtttt aactgtcata tctcttgttt ttggtgtact tagcctggtt 1560ctagcatgct acctgatgta caagcaaaag gcacaacaaa agaccttgtt atggcttggg 1620aataataccc ttgatcagat gagagccact acaaaaatat ga 1662 11 33 DNA Infectious bursal disease virus 11tcagatatcg atgacaaacc tgcaagatca aac 33 12 38 DNA Infectious bursal disease virus 12agaatgcggc cgcttacctc cttatagccc ggattatg 38 13 1362 DNA Infectious bursal disease virus 13atgacaaacc tgcaagatca aacccaacag attgttccgt tcatacggag ccttctgatg 60ccaacaaccg gaccggcgtc cattccggac gacaccctgg agaagcacac tctcaggtca 120gagacctcga cctacaattt gactgtgggg gacacagggt cagggctaat tgtctttttc 180cctggattcc ctggctcaat tgtgggtgct cactacacac tgcagagcaa tgggaactac 240aagttcgatc agatgctcct gactgcccag aacctaccgg ccagctacaa ctactgcaga 300ctagtgagtc ggagtctcac agtgaggtca agcacactcc ctggtggcgt ttatgcacta 360aacggcacca taaacgccgt gaccttccaa ggaagcctga gtgaactgac agatgttagc 420tacaatgggt tgatgtctgc aacagccaac atcaacgaca aaattgggaa tgtcctggta 480ggggaagggg tcactgtcct cagcctaccc acatcatatg atcttgggta tgtgaggctt 540ggtgacccca ttcccgctat agggcttgac ccaaaaatgg tagctacatg cgacagcagt 600gacaggccca gagtctacac cataactgca gccgatgatt accaattctc atcacagtac 660caaccaggtg gggtaacaat cacactgttc tcagccaaca ttgatgctat cacaagcctc 720agcattgggg gagagctcgt gtttcaaaca agcgtccaag gccttgtact gggcgccacc 780atctacctta taggctttga tgggactgcg gtaatcacca gagctgtagc cgcagataat 840gggctgacgg ccggcaccga caatcttatg ccattcaatc ttgtcattcc aaccaatgag 900ataacccagc caatcacatc catcaaactg gagatagtga cctccaaaag tggtggtcag 960gcaggggatc agatgtcatg gtcggcaagt gggagcctag cagtgacgat ccatggtggc 1020aactatccag gggccctccg tcccgtcaca ctagtagcct acgaaagagt ggcaacagga 1080tccgtcgtta cggtcgctgg ggtgagtaac ttcgagctga ttccaaatcc tgaactagca 1140aagaacctgg ttacagaata cggccgattt gacccaggag ccatgaacta cacaaaattg 1200atactgagtg agagggaccg tcttggcatc aagaccgtct ggccaacaag ggagtacact 1260gattttcgtg agtacttcat ggaggtggcc gacctcaact ctcccctgaa gattgcagga 1320gcatttggct tcaaagacat aatccgggct ataaggaggt aa 1362 14 32 DNA chicken infectious bronchitis virus 14acgcgtcgac atgttggtaa cacctctttt ac 32 15 35 DNA chicken infectious bronchitis virus 15ggaagatctt cattaacgtc taaaacgacg tgttc 35 16 1614 DNA chicken infectious bronchitis virus 16atgttggtaa cacctctttt actagtgact cttttgtgtg tactatgtag tgctgctttg 60tatgacagta gttcttacgt ttactactac caaagtgcct ttagaccacc taatggttgg 120catttacacg ggggtgctta tgcggtagtt aatatttcta gcgaatctaa taatgcaggc 180tcttcacctg ggtgtattgt tggtactatt catggtggtc gtgttgttaa tgcttcttct 240atagctatga cggcaccgtc atcaggtatg gcttggtcta gcagtcagtt ttgtactgca 300cactgtaact tttcagatac tacagtgttt gttacacatt gttataaata tgatgggtgt 360cctataactg gcatgcttca aaagaatttt ttacgtgttt ctgctatgaa aaatggccag 420cttttctata atttaacagt tagtgtagct aagtacccta cttttaaatc atttcagtgt 480gttaataatt taacatccgt atatttaaat ggtgatcttg tttacacctc taatgagacc 540acagatgtta catctgcagg tgtttatttt aaagctggtg gacctataac ttataaagtt 600atgagagaag ttaaagccct ggcttatttt gttaatggta ctgcacaaga tgttattttg 660tgtgatggat cacctagagg cttgttagca tgccagtata atactggcaa tttttcagat 720ggcttttatc cttttattaa tagtagttta gttaagcaga agtttattgt ctatcgtgaa 780aatagtgtta atactacttt tacgttacac aatttcactt ttcataatga gactggcgcc 840aaccctaatc ctagtggtgt tcagaatatt ctaacttacc aaacacaaac agctcagagt 900ggttattata attttaattt ttcctttctg agtagttttg tttataagga gtctaatttt 960atgtatggat cttatcaccc aagttgtaat tttagactag aaactattaa taatggcttg 1020tggtttaatt cactttcagt ttcaattgct tacggtcctc ttcaaggtgg ttgcaagcaa 1080tctgtcttta gtggtagagc aacttgttgt tatgcttatt catatggagg tccttcgctg 1140tgtaaaggtg tttattcagg tgagttagct cttaattttg aatgtggact gttagtttat 1200gttactaaga gcggtggctc tcgtatacaa acagccactg aaccgccagt tataactcga 1260cacaattata ataatattac tttaaatact tgtgttgatt ataatatata tggcagaact 1320ggccaaggtt ttattactaa tgtaaccgac tcagctgtta gttataatta tctagcagac 1380gcaggtttgg ctattttaga tacatctggt tccatagaca tctttgttgt acaaggtgaa 1440tatggtctta cttattataa ggttaaccct tgcgaagatg tcaaccagca gtttgtagtt 1500tctggtggta aattagtagg tattcttact tcacgtaatg agactggttc tcagcttctt 1560gagaaccagt tttacattaa aatcactaat ggaacacgtc gttttagacg ttaa 1614 17 39 DNA chicken infectious bronchitis virus 17ataagaatgc ggccgcatgt ccaacgagac aaattgtac 39 18 38 DNA chicken infectious bronchitis virus 18ataagaatgc ggccgcttta ggtgtaaaga ctactccc 38 19 678 DNA chicken infectious bronchitis virus 19atgtccaacg agacaaattg tactcttgac tttgaacagt cagttgagct ttttaaagag 60tataatttat ttataactgc attcttgttg ttcttaacca taatacttca gtatggctat 120gcaacaagaa gtaagtttat ttatatactg aaaatgatag tgttatggtg cttttggccc 180cttaacattg cagtaggtgt aatttcatgt atatacccac caaacacagg aggtcttgtc 240gcagcgataa tacttacagt gtttgcgtgt ctgtcttttg taggttattg gatccagagt 300attagactct ttaagcggtg taggtcatgg tggtcattta acccagaatc taatgccgta 360ggttcaatac tcctaactaa tggtcaacaa tgtaattttg ctatagagag tgtgccaatg 420gtgctttctc caattataaa gaatggtgtt ctttattgtg agggtcagtg gcttgctaag 480tgtgaaccag accacttgcc taaagatata tttgtttgta caccggatag acgtaatatc 540taccgtatgg tgcagaaata tactggtgac caaagcggaa ataagaaacg gtttgctacg 600tttgtctatg caaagcagtc agtagatact ggcgagctag aaagtgtagc aacaggaggg 660agtagtcttt acacctaa 678 20 34 DNA chicken infectious bronchitis virus 20aaaactgcag tcatggcaag cggtaaggca actg 34 21 33 DNA chicken infectious bronchitis virus 21cgcggatcct caaagttcat tctctcctag ggc 33 22 1230 DNA chicken infectious bronchitis virus 22atggcaagcg gtaaggcaac tggaaagaca gacgccccag ctccagtcat caaactagga 60ggaccaaagc cacctaaagt tggttcttct ggaaatgtat cttggtttca agcaataaaa 120gccaagaagt taaattcacc tccgcctaag tttgaaggta gcggtgttcc tgataatgaa 180aatctaaaac caagtcagca gcatggatat tggagacgcc aagctaggtt taagccaggt 240aaaggtggaa gaaaaccagt cccagatgct tggtattttt actatactgg aacaggacca 300gccgctaacc tgaattgggg tgatagccaa gatggtatag tgtgggttgc tggtaagggt 360gctgatacta aatttagatc taatcagggt actcgtgact ctgacaagtt tgaccaatat 420ccgctacggt tttcagacgg aggacctgat ggtaatttcc gttgggattt cattcctctg 480aatcgtggca ggagtgggag atcaacagca gcttcatcag cggcatctag tagagcacca 540tcacgtgaag tttcgcgtgg tcgcaggagt ggttctgaag atgatcttat tgctcgtgca 600gcaaggataa ttcaggatca gcagaagaag ggttctcgca ttacaaaggc taaggctgat 660gaaatggctc accgccggta ttgcaagcgc actattccac ctaattataa ggttgatcaa 720gtgtttggtc cccgtactaa aggtaaggag ggaaattttg gtgatgacaa gatgaatgag 780gaaggtatta aggatgggcg cgttacagca atgctcaacc tagttcctag cagccatgct 840tgtcttttcg gaagtagagt gacgcccaga cttcaaccag atgggctgca cttgaaattt 900gaatttacta ctgtggtccc acgtgatgat ccgcagtttg ataattatgt aaaaatttgt 960gatcagtgtg ttgatggtgt aggaacacgt ccaacagatg atgaaccaag accaaagtca 1020cgctcaagtt caaaacctgc aacaagagga aattctccag cgccaagaca gcagcgccct 1080aagaaggaga aaaagccaaa gaagcaggat gatgaagtgg ataaagcatt gacctcagat 1140gaggagagga acaatgcaca gctggaattt gatgatgaac ccaaggtaat taactggggg 1200gattcagccc taggagagaa tgaactttga 1230 23 39 DNA Chicken anemia virus 23ttcttgcggc cgccatggca agacgagctc gcagaccga 39 24 38 DNA Chicken anemia virus 24ttcttgcggc cgctcagggc tgcgtccccc agtacatg 38 25 39 DNA Chicken anemia virus 25ttcttgcggc cgccatgcac gggaacggcg gacaaccgg 39 26 32 DNA Chicken anemia virus 26cgcggatcct cacactatac gtaccggggc gg 32 27 38 DNA chicken infectious laryngotracheitis virus 27ttcttgcggc cgccatggct agcttgaaaa tgctgatc 38 28 36 DNA chicken infectious laryngotracheitis virus 28ttcttgcggc cgcttattcg tcttcgcttt cttctg 36 29 33 DNA chicken infectious laryngotracheitis virus 29ccggtcgaca tggaccgcca tttatttttg agg 33 30 33 DNA chicken infectious laryngotracheitis virus 30ggaagatctt tacgatgctc caaaccagta gcc 33 31 54 DNA avian encephalomyelitis virus 31tttgatatca tggaagccgt cattaaggca tttctgactg gataccctgg gaag 54 32 31 DNA avian encephalomyelitis virus 32tttggatcct tatactattc tgctttcagg c 31 33 31 DNA avian encephalomyelitis virus 33acgcgtcgac atggaagccg tcattaaggt g 31 34 32 DNA avian encephalomyelitis virus 34tgctctagac tataaatttg tcaagcggag cc 32 35 32 DNA Turkey rhinotracheitis virus 35aaactgcaga gatggggtca gagctctaca tc 32 36 31 DNA Turkey rhinotracheitis virus 36cgaagatctt tattgactag tacagcacca c 31 37 33 DNA avian plague virus 37aaactgcagc aatggccatc atttatctaa ttc 33 38 31 DNA avian plague virus 38cgaagatctt catatgcaga ttctgcattg c 31 39 31 DNA avian plague virus 39aaactgcaga tgaacactca aatcctgata c 31 40 31 DNA avian plague virus 40tttggatcct tatatacaaa tagtgcaccg c 31 41 32 DNA Avian influenza virus 41ccggtcgaca tggcgtctca aggcaccaaa cg 32 42 30 DNA Avian influenza virus 42cgcggatcct taattgtcat actcctctgc 30 43 35 DNA avian plague virus 43cgcgtcgaca tgaatccaaa tcagaaaata ataac 35 44 31 DNA avian plague virus 44ggaagatctc tacttgtcaa tggtgaatgg c 31

Claims

1. An immunogenic composition for inducing in an avian host an immunological response against Newcastle disease comprising a plasmid that contains and expresses in vivo in an avian host cell a nucleic acid molecule having the sequence encoding Newcastle disease virus HN protein and a pharmaceutically acceptable carrier.

2. The composition according to claim 1, wherein the plasmid further contains and expresses in vivo in the host cell a nucleic acid molecule having the sequence encoding Newcastle disease virus F protein.

3. The composition according to claim 1, wherein the composition further comprises a second plasmid that contains and expresses in vivo in the host cell a nucleic acid molecule having the sequence encoding the Newcastle virus F protein.

4. The composition according to any one of claims 1 to 3, wherein expression of the sequence is under control of a promoter selected from the group consisting of CMV-IE promoter, SV40 early promoter, SV40 late promoter, Rous sarcoma virus LTR promoter, promoter of a cytoskeleton gene.

5. The composition according to any one of claims 1 to 3, wherein expression of the sequence is under the control of CMV-IE promoter.

6. An immunogenic composition for inducing in an avian host an immunological response against infectious bursal disease comprising a plasmid that contains and expresses in vivo in an avian host cell a nucleic acid molecule having the sequence VP2 protein.

7. The composition according to claim 6, wherein expression of the sequence is under the control of a CMV-IE promoter.

8. An immunogenic composition for inducing in an avian host an immunological response against infectious anaemia virus comprising at least one plasmid that contains and expresses in vivo in an avian host cell a nucleic acid molecule having the sequence encoding infectious anaemia virus C protein and a nucleic acid molecule having the sequence encoding infectious anaemia virus NS I protein.

9. The composition according to claim 8, wherein expression of the sequences is under the control of the CMV-IE promoter.

10. A method for inducing an immunological response in an avian comprising: administering to said avian a vaccine selected from the group consisting of a live whole vaccine, an inactivated whole vaccine, a subunit vaccine, and a recombinant vaccine; and thereafter, administering to said avian an immunogenic composition as claimed in any one of claims 1, 5, 6, 7, and 8-9.

11. A method for inducing an immunological response in an avian comprising administering to said avian an immunogenic composition as claimed in any one of claims 1, 5, 6, 7, and 8-9.

12. A kit comprising (i) an immunogenic composition according to any one of claims 1, 5, 6, 7, and 8-9, and (ii) an avian vaccine selected from the group consisting of a live whole vaccine, an inactivated whole vaccine, a subunit vaccine, and recombinant vaccine.