CA2432738A1 - New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications - Google Patents

New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications Download PDF

Info

Publication number
CA2432738A1
CA2432738A1 CA002432738A CA2432738A CA2432738A1 CA 2432738 A1 CA2432738 A1 CA 2432738A1 CA 002432738 A CA002432738 A CA 002432738A CA 2432738 A CA2432738 A CA 2432738A CA 2432738 A1 CA2432738 A1 CA 2432738A1
Authority
CA
Canada
Prior art keywords
virus
recombinant
west
polypeptide according
nile
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Abandoned
Application number
CA002432738A
Other languages
French (fr)
Inventor
Philippe Despres
Marie Pascale Frenkiel
Chantal Combredet
Frederic Tangy
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Individual
Original Assignee
Centre National de la Recherche Scientifique CNRS
Institut Pasteur de Lille
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from CA002420092A external-priority patent/CA2420092A1/en
Application filed by Centre National de la Recherche Scientifique CNRS, Institut Pasteur de Lille filed Critical Centre National de la Recherche Scientifique CNRS
Priority to CA002432738A priority Critical patent/CA2432738A1/en
Priority to BRPI0407840A priority patent/BRPI0407840B8/en
Priority to ES04714865T priority patent/ES2394307T3/en
Priority to PCT/IB2004/001027 priority patent/WO2004076619A2/en
Priority to DK04714865.5T priority patent/DK1599495T3/en
Priority to CA2517258A priority patent/CA2517258C/en
Priority to CA002456873A priority patent/CA2456873A1/en
Priority to EP04714865.5A priority patent/EP1599495B9/en
Publication of CA2432738A1 publication Critical patent/CA2432738A1/en
Priority to IL170418A priority patent/IL170418A/en
Priority to US11/210,960 priority patent/US7556812B2/en
Priority to HK06105979.8A priority patent/HK1086278A1/en
Priority to US12/476,304 priority patent/US8859240B2/en
Abandoned legal-status Critical Current

Links

Classifications

    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K39/00Medicinal preparations containing antigens or antibodies
    • A61K39/12Viral antigens
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61PSPECIFIC THERAPEUTIC ACTIVITY OF CHEMICAL COMPOUNDS OR MEDICINAL PREPARATIONS
    • A61P31/00Antiinfectives, i.e. antibiotics, antiseptics, chemotherapeutics
    • A61P31/12Antivirals
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61PSPECIFIC THERAPEUTIC ACTIVITY OF CHEMICAL COMPOUNDS OR MEDICINAL PREPARATIONS
    • A61P31/00Antiinfectives, i.e. antibiotics, antiseptics, chemotherapeutics
    • A61P31/12Antivirals
    • A61P31/14Antivirals for RNA viruses
    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07KPEPTIDES
    • C07K14/00Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof
    • C07K14/005Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof from viruses
    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07KPEPTIDES
    • C07K14/00Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof
    • C07K14/005Peptides having more than 20 amino acids; Gastrins; Somatostatins; Melanotropins; Derivatives thereof from viruses
    • C07K14/08RNA viruses
    • C07K14/18Togaviridae; Flaviviridae
    • C07K14/1816Flaviviridae, e.g. pestivirus, mucosal disease virus, bovine viral diarrhoea virus, classical swine fever virus (hog cholera virus), border disease virus
    • C07K14/1825Flaviviruses or Group B arboviruses, e.g. yellow fever virus, japanese encephalitis, tick-borne encephalitis, dengue
    • CCHEMISTRY; METALLURGY
    • C12BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
    • C12NMICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
    • C12N15/00Mutation or genetic engineering; DNA or RNA concerning genetic engineering, vectors, e.g. plasmids, or their isolation, preparation or purification; Use of hosts therefor
    • C12N15/09Recombinant DNA-technology
    • C12N15/63Introduction of foreign genetic material using vectors; Vectors; Use of hosts therefor; Regulation of expression
    • C12N15/79Vectors or expression systems specially adapted for eukaryotic hosts
    • C12N15/85Vectors or expression systems specially adapted for eukaryotic hosts for animal cells
    • C12N15/86Viral vectors
    • CCHEMISTRY; METALLURGY
    • C12BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
    • C12QMEASURING OR TESTING PROCESSES INVOLVING ENZYMES, NUCLEIC ACIDS OR MICROORGANISMS; COMPOSITIONS OR TEST PAPERS THEREFOR; PROCESSES OF PREPARING SUCH COMPOSITIONS; CONDITION-RESPONSIVE CONTROL IN MICROBIOLOGICAL OR ENZYMOLOGICAL PROCESSES
    • C12Q1/00Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions
    • C12Q1/70Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions involving virus or bacteriophage
    • C12Q1/701Specific hybridization probes
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K39/00Medicinal preparations containing antigens or antibodies
    • A61K2039/51Medicinal preparations containing antigens or antibodies comprising whole cells, viruses or DNA/RNA
    • A61K2039/525Virus
    • A61K2039/5256Virus expressing foreign proteins
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K39/00Medicinal preparations containing antigens or antibodies
    • A61K2039/51Medicinal preparations containing antigens or antibodies comprising whole cells, viruses or DNA/RNA
    • A61K2039/53DNA (RNA) vaccination
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K38/00Medicinal preparations containing peptides
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61KPREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
    • A61K39/00Medicinal preparations containing antigens or antibodies
    • CCHEMISTRY; METALLURGY
    • C12BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
    • C12NMICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
    • C12N2760/00MICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA ssRNA viruses negative-sense
    • C12N2760/00011Details
    • C12N2760/18011Paramyxoviridae
    • C12N2760/18411Morbillivirus, e.g. Measles virus, canine distemper
    • C12N2760/18441Use of virus, viral particle or viral elements as a vector
    • C12N2760/18443Use of virus, viral particle or viral elements as a vector viral genome or elements thereof as genetic vector
    • CCHEMISTRY; METALLURGY
    • C12BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
    • C12NMICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA
    • C12N2770/00MICROORGANISMS OR ENZYMES; COMPOSITIONS THEREOF; PROPAGATING, PRESERVING, OR MAINTAINING MICROORGANISMS; MUTATION OR GENETIC ENGINEERING; CULTURE MEDIA ssRNA viruses positive-sense
    • C12N2770/00011Details
    • C12N2770/24011Flaviviridae
    • C12N2770/24111Flavivirus, e.g. yellow fever virus, dengue, JEV
    • C12N2770/24122New viral proteins or individual genes, new structural or functional aspects of known viral proteins or genes
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02ATECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
    • Y02A50/00TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE in human health protection, e.g. against extreme weather
    • Y02A50/30Against vector-borne diseases, e.g. mosquito-borne, fly-borne, tick-borne or waterborne diseases whose impact is exacerbated by climate change

Landscapes

  • Life Sciences & Earth Sciences (AREA)
  • Health & Medical Sciences (AREA)
  • Chemical & Material Sciences (AREA)
  • Organic Chemistry (AREA)
  • Virology (AREA)
  • Genetics & Genomics (AREA)
  • General Health & Medical Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Zoology (AREA)
  • Molecular Biology (AREA)
  • Wood Science & Technology (AREA)
  • Biochemistry (AREA)
  • Biophysics (AREA)
  • Proteomics, Peptides & Aminoacids (AREA)
  • Medicinal Chemistry (AREA)
  • Biotechnology (AREA)
  • General Engineering & Computer Science (AREA)
  • Bioinformatics & Cheminformatics (AREA)
  • Microbiology (AREA)
  • Immunology (AREA)
  • Physics & Mathematics (AREA)
  • Biomedical Technology (AREA)
  • Gastroenterology & Hepatology (AREA)
  • Pharmacology & Pharmacy (AREA)
  • Animal Behavior & Ethology (AREA)
  • Public Health (AREA)
  • Veterinary Medicine (AREA)
  • Communicable Diseases (AREA)
  • Analytical Chemistry (AREA)
  • Plant Pathology (AREA)
  • Nuclear Medicine, Radiotherapy & Molecular Imaging (AREA)
  • General Chemical & Material Sciences (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Oncology (AREA)
  • Mycology (AREA)
  • Tropical Medicine & Parasitology (AREA)
  • Epidemiology (AREA)
  • Micro-Organisms Or Cultivation Processes Thereof (AREA)
  • Peptides Or Proteins (AREA)
  • Medicines Containing Antibodies Or Antigens For Use As Internal Diagnostic Agents (AREA)

Description

htEW DENGUE AND WEST NILE ~IIRUSES PROTEINS AND GENES CODING
THE FOREtat711~1G, AND THEIR USE It~i VA~C1NAL, THERAPEUTIC
AND DIAGNOSTIC APPLICATIONS
i~nb°~aduction The aim of this ws~rh is to develop viral vectors expressing different immunogens from the West Nile Encephalitis Virus (Wf~J) or the Dengue virus able to induce protective humoral and cetiular immune responses against ~11NV
or Dengue virus infections, lP~e describe 3 antigens from VIINV (the secreted 9 D envelope glycopmtein (E), the heterodimer ~lycoproteins (~re~M~EI and the protein) and from i~engue virus (the secreted envelope glycoprotein (E), the heterodimer gtyaoprateins (pre-~M-E) and the NS1 protein). These antigens have been deriv8d from lNest Nile Virus 15-38-ST"I strain and from G~engue virus.
Any fr~ment of a nucleotitii~c or aminoacid sequence ~of the present Invention comprising at least 30 nucleotide:~-fl;--'.c~-~.,mse:~sids--are--pard-o~~t,";e ~iar°W°.i i -invention.
Any nucleotidic car aminoacid sequee~ce having at least 80°/0 of identity of the sequences of the present invention are part of said invention provided that the seqttertres have the capacity to hydridize under stringent conditions with the nucleotidic sequence as disclosed or the poly~nucieotidic sequences capable~to be rann~r~i~~sn1 G.a. nr,l:6....1C'.e- w.....~.J ........~.,.w,~i .....v.
..w.m...~...y.:d.. .e...d..wr....-.n r... ~I:.~~.s~.~-..~
in the present invention.
Various viral ve~:tors are ktyovvn at~d well documented. As examples, we refer to the use of Hepatitis B virus (French Patent N° 2~3a53~), or Human Papitloma 2~ Virus, or Polio virus (tnterrtational patent ~tppiiCation n°~/IfCJ
89 0151fi), or Mengo virus (International patent application n°WC7 94 29#72), or ~Ileasles virus (European Patent Application N° 02291551.6 files cn June 20, 21702) ft~r the expression of foreign nucleotidic sequences as useful immunogens in therapeutical, vaccines, or diagnostic fields.
Introduction WNV

Flaviviridae are arbcwiruses (arthr~dpod-bcarne virus mainly transported by mosquitoes and blood-sucking ticks. They are small encapsidated viruses and their genomes consist of lnfectlous single-stranded and linear RNA of positive polarity. in Man, flaviviruses cause deadly hemorrhagic fever or meningo-encephalitis. Yellow fever, dengue fever anti Japanese encephalitis are the main tropical flavivlrases. ether important human flaviviroses are Saint Louis encephalitis, tick-bom European encephalitis and West I~Ite fever.
West Nile fever is a zaonosis associated with a flavivirus which was first isolated in Uganda in 193'. Its transmission cyde calls for birds ass the maim resevoir and for blood sucking mosquitoes of the ~ulex genus as vectors.
M~rdtory viremic birds transport the virus to fag aw2Ey regions where they transmit it anew to amithophile mosquitoes of the ~ulex genus. Many species of mammals are permissive far the West Nile virus. Horses are particularly sensitive to the disease taut do not participate in the cycle of transmission. West Nile fever is endemic in Africa, Asia, Europe and Australia. Phylagenic studies have revealed the existence of two strains of viruses : viral line 1 has a worldwide distribution, and viral line 2 is essentially African. Viral line 1 was responsible for enzooties in Romania (1996), Russia (1999J, Israel (19g~-2800) and more recently in hlorth America where the virus had never been detected befnre 1999. The viral strains isolated during the recent epidemics in Israel and the United-States are more than 99,7'°6 identicaf_ In the Middle-Fit and North America, where the virus has taken root, an important #~ird mortality rate has been observed among infected birds, notably in Corvidae. In North America, over 4000 subjects were infected with the West Nile virus, 250 of whleh diett taetween the months of August and December 2002. At the present time, zoonosis is observed in a!I regions of the United States, At the moment, there exists no hur'rtan vaccine or specific therapy against West Nile fever.
In temperate and sub-tropical regit~ns, human infections rnay occur during the faH season. When a subject is bitten by an infected mosquitos, the inGUbation period lasts approximately one week but fesa than 2~ % of people infected with the West Mile virus ever gr~ on to clinica3 manifestations. in its benignant form, the viral infection manifests itself by an undifferentiated febrile state associated with muscular weakness, headaches and abdominal pain. In less than 9alo of infected subjects, encephalitis or acute aseptic meningitis may occur. Splenon~egaly, hepatitis> pancreatitis and myocarditis are also observed. Flask paralyses similar to a poliomyelitis syndrome have recently been reported, but fatal cases cal viral encephalitis (5'~6 of patients having severe neurological disorders) mainly concern fragile subjects and tire aged. Inter-hurnari transmission of the virus has also recently been observed in the United-States in sub~er~ having undergone organ transplants or having been perfused vrith oontaminat~l blond produets..lntra-uterine transmission of the virus has been reported in the Linited-States. The development of a human vaccine against the Vlfest Nlle fever is a priority in view of the feat that the zoonosis has taken root in North America and is expected to propagate in the coming months to Central America, South America and the Caribbean where dengue fetter and yellow fever are atready rampant The present invention wilt be more readily understood by referring to the following examples. These examples are 7tustrative at then vuide range of applicability of the present invention and are not intended to limit its scope.
Modifications and variations can be made therein wifhout departing from the spirit and scope of the invention. Although any methods and materials similar or equivalent to those described herein can be used in the practice fear testing of the 2~ present invention, the preferred methods and materials are described.
Exarnple~ 1 : ~onstrucfion ~f measles viruses (M1J~. expr~assing WNV and De~n~i antigens In order to test their capacity as vaccine candidates agair~:tt WN1!_ intertinn;
we constructed recombinant Sshwar~ ameastes viruses (Ni~d) expressing these WNV anct I~EN-1 antigens. Tl~e different genes were introdaoed in art additional I
transcription unit in the achvvarz M1/ c~lNr~ that we previously cloned (pTM-i M'VSchw) (European Patent Appli~tion N° 0229'1559.6 filed on June 2iJ, 2UD2).
After rescue of the different recombinant Sahwarz measles viruses expcessinv the 3D UVNV and DEN-9 gene, their capacity to protect mice from a lethal WNV
intraperitoneal challenge, and monkeys from Dengue virus infection will tae tested.

MY vector Mass vaccination with live attenuated vaccines has reduced the incidence of measles and its complications drarrtatically since i't was introduced In the 50's. By now, the vaccine has been ~'sven to billions of people and is safe and efficacious. It induces a very efficient, life-long DD4, C1~8 and humorai immunity after a single injection of ~!~4 TCID50. Moreover, it is easy to produce, cheap, and the means to deliver it worldwide already exist. The safety of this vaccine is due to several factors: i) The stability of the MV genome which explains that reversion to 1o pathogerticity has never beer; observed. ii)The impossbility for the MV
gename to integrate in host chromosomes since viral replication is exclusively cytoplasmic. iii) The productie~n of the vaccine ~on safe primary chick embryo fibrobfastic cells.
Thus, live attenuated MV could provide a safe and efficient pediatric vaccination vector.
MV belongs to the genus Morbillivirus in the family i'aramyxoviridae. The Edmonston MV was isolated in 1954 ('!), serially passaged an primary human kidney and amnion cells, then adapted to chick embryo fibroblasts (CEi=) to produce ~dmonston A and B seeds (see (~, ~) for t'eview). Edmonston B was licensed irw 1953 as the first MV vaccine. Further passages of Edmonston A and B
2tl on CIEF produced the more attenuated Schwarz and A~loraten viruses (4) whose sequences have fecently been shown to be identical (5, 6). Being "reactogenic,"
Edmonston 8 vaccine was a3~andoned in 1975 and replaced by the Sc~warzfMaraten vaccine. This is now the most ct~mmoraly used measles vaccine (2, 6)_ In a previous work, wee constructed an infectious cDNA from a batch of commercial Schwarz vaccine, a widely used MV vaccine (European Fatent Application N° 42291551.6 filed on June 20, 2002). The extremities of the cDNA
were engineered in order to maximize virus yield during rescue. A previously described helper cell-based rescue system was adapted by co-cu~ivating 84 transfected celEs ors primary chick embryo 5broblasts, the Its used to produce the Schwarx vaccine. After two passages the sequence of the rescued virus was identical to that of the cDNA and of the published ~chwar~ sectuence. Two ,T7 additional transcription units (ATtJ) were 9r~trcsduced in the c~NA for cloning fpreign genetic material. The immun~ageneclty of rescued virus was studied in ~ mioe transgenic for the CD46 MV receptor and in macaques. Antibody titers in animals inoculated with tow doses of the rescued virus were identical to those obtained with commercial 8chwarz ~IIV vaccine. In contrast, the imenunogenicity of a previously described ~dmonston strain-derived Ml~l clone was much lower. This new molecu~r cione allows producing MV vaccine without having to rely on seed stocks. The ATIJs, allow producing recombinant vaccines based on an approved, efficient and worldwide used vaccine strain.
Example ~: Construction of ~Schwarz AAiI V~INiI recombinant pl2~smids.
"l) Secreted glycoprotein E from NV
The WNV env gene encoding the secreted form of the protein was generated by I~T-PCR amplificatir~n of viral RNA purred from viral particles (9JVNV IS-9~-ST't strain). The specific s~uence was amplified using Pft,~Turbo DNA palymerase (Stratagene) and speciflo primers that contain unique sites for subsequent cloning in pTM-MVSchw vector , HIV-VSdNEnvS 5' TATCGTACt;r~T~AGAGTTC~~'GTl'I"GTCGTGCTA-3' (BsilN1 site underlined) and MV-INNEnv3 5'-A'fAGCGCGGTT~AGACJ~GCCTTGCCAACTGA-3' (BssHll site underlined). A start and a stop vadon were added at both ends of the gene. The whole sequence generated is 1380 nucleotides long, including the start and the stop colons and respects the rule of sixn, stipulating that the nucleotides number of MV genome must be divisible by B {7, ~)_ The Env protein thus generated contains its Signal peptide in hi-term ('! g aa) and no transrr~embr'arre region. Thus, It represents amine acids 275-732 in WNV potyprotein and has the following sequence:
S~Q IG N~ 1 i atgagagttgtgtttgtcgtgc~tattgcftttggtggccccagcttacagcttcaactgccttggaatgagc~aarag agacitcttggaaggagtgt~9agcaacatg99t99a'~99ttctcgaaggcgacagctgcgtgacitatc atgtctaaggacaagcctaccatcgatgtgaagatgatg aatatgga9gGggtcaacct~gcaga9Stccg C~gttatk9~tr'~ttt9~Ct~ccgtcagcgBtCtC't~C~GC2cl~gCtgogtg~c~cg~CC~'P~~~~ga3gctc aazgacaaacgTgc~gacccagcrcc9rgtgca9acaaggagt99t99a~9999~9998~a~9~9 c9gaftatftggcaaaggaagcattc~aCacatgcgccaaattfgcctgctctaccaaggcaataggaagaac catcttgaaagac~aatatcaagtacgaagtgggccatftttgtccatggaccaactactgtggagtcgcar,~9a aactaetccacacaggttggagccactcaggcagggagattcagcatcactrctgcggcgccttcatacaca ctaaagctt9ga9aatatggagag.9t9a9t9gact9t9aat~acggtcagg9attgacaa:aatgcata ctacgtgatgactgttggaacaaagacgttcttggtccatc~gtgagtggttcatqgacctcaacctccc~t~ggag cagt9ctqgaagtactgtg'tgga9gaacagagagacgttaatggagtttgag9aarCaca~gcgaag cagtctgtgatattr"attg99ctcaaaagagggagctctg~tcaagcttk99ga9ccattcctg#g9aattt t~~~s~.,~..r,~c~t~tc~~r,t'~~e~~~t~t~a~~.~.~~c~~d~,~~~c 9t9'~99aattgcagtacactggcacggatggaccffgcaaagtttafc~cgtcagtggcktcattgaacgac ctaacgccagt9g9~9att99tt9tcaacccttttgtttcagt9gccacggccaaogctaaggtcctgatt gaat~gaaccaccctttggagactcatacatagtggtgggcagaggagaacaacagatcaatca~attg gc~acaagtctggaagcagcattggcaaagcctttacaaccaccctcaaaggagcgcagagactagccgct 95 ctaggagacacagcttgg9acttiggatcagttgga9g99t9ttcacctcagttgggaaggctc~tctaa sli=d ~t~ I~° s I~IRVVFVVLI.L.LVAPAYSFNGL(31VISNRDF~LEL;VSGA'I'~IVVDLVLEGC)SDV~IMS
K»KF'TIDVKMMNMF~VNLAEVRSYCYLATVSDLSTKAACPTtVIGEAHNDKRA
20 DPAFVCRQGVVDRG~tf3NGCGLFGKGSIDTGAKFAGSTKAtGRTtLKENIKYE
VAIFVHGPTTVESH~NYS'fQVGATQAGRFSt'TPAAPSYTLKLGEYGEVTifDCE
PRSGIDTNAYYVMTV~TK'TFLVHRt=WFN1DLNLPWSSA~S'1~MIRNF~ETLIUIEF
EEPHATKC~SVIALGSQEGALHt~ALAGAIPVEFSSNTVKLTSGt-fLKCRVKIVtEKL
Gtl_KGTTYGVGSKAFKFLGTPADTGt~GTVIILEE'QYT~TDCPGKVPISSVASLN
,~5 Dt_TPV~'aI~LVNNPFVSVATANAKVLtELEPPFCDSYtIIV~F'~'GEQQINHhiWHKS
GSStGKAFTfTLKGAQRLAALGDTA1NDFGSVGGVF'r'SVGKAV*
~) preM plus E giyccrproteins from WNV
The iNNV gene encoding tha preM plus E gtycoprdteins was generated by 3D PCR amplification of plasmi~l pVL prM-E.55.1 (clone CNGN! I-~~~32 dip~s~ la 1~
actobre 2081, Philippe Desprtas). This expression plasmid encodes the pre~~l and E proteins of WNV (IS-98-ST1 strain). The sequence was amplified using F'fuTurbo I~NA pclymerase 4~tratagene) anti specific primers that contain unique sites for subs~uent cloning in pTM-MVSchw vector : MV VtINpreME~ 5'-TATCGTACGATGCAAAAGAAAAGAGGAGGAAACa-3' (gsiWl site underlined) and MV-WNpreME3 5'-ATAGCG~G~TTAAGCGTC~GAGGTTCA~faG AG-3' (l3ssW11 site underlined). A start and a stag cadan were added at both ends of the gene.
The whole sequence generated is 20'78 nucleotides long, including the start and the stag cadons and re$pecfs the MV "rule of six". In the construct, the G-terminus pact of the C protein serves as a prM transhacatic~n signal. Both preM and ~
viral glycaprateins are transmembrane glycaproteins type I. It is presumed that WNV
env preME expressing IIAV v~ill praduce and release multimeric farms of pceM-t=
heterodimers exhibiting high immunagenic potential. TI~ construct represents amino acids 302-789 in WNV palypratein and has the following sequence SEAII~N°2 9 5 t atgcaaaagaaaagaggaggaaagaccggaattgcagtcatgatt~ggcctgatcagccJtaggagca gttaccctctctaacttccaagggaaggtgatgatgacggtaaatgctactgacgtcacagatgtcatcacgat tccaacagckgctggaaagaacctatgcattgtcagagcaatggatgtgggatacatgtgcgatgatactatc acttatgastgcccagtgctgtcggctggtaatgatccagaagacatcgactgttggtgcaoaaagtCagcag tatacgtoaggtat9gaagatgcacc~agacacgccactcaagaogcagtcggag9tcact9acagt9ca gacacacggagaaagcactctagcgaacaagaagggggcttggatggacagcaccaaggccacaagg tatttggtaaaaaoagaatce~tggatcttgaggaaccctggat2~tgccctggtggcagcx~tcattggit~gat gdtgggagcaacaccatgcagagagttgtgtttgtcgtgctattgcttttggtggccccagcttacagcttcaac tgccttggaatgagcaacagagacttcttggaaggagtgtctggagcaacatg9gkg9a~99tt~c9aa9 gcgacagctgcgtgactatcatgtct~raggacaagcctaccatcgatgtgaagatgatgaata~tggaggcx~g 2~ tcaacctggcagaggtccgcagttattgctatttggctaccgtcagcgatctctccaccaaagctgcgtgcccg accatgggagaagctcacaatgaraaacgtgatgaeccagcttttgtgtgcagacaaggagtggtg9acag 999~9gg9~ac99ct9c9$atta'~9~aa99aagcattgacacatgcgccaaatttgcc~bgctctac caaggcaataggaagaaccatcttgaaagagaatatcaagtacgaagtggccatttttgtccatggacccaac tactgtgga9tcgcac99aaactactccacacaggtt,9ga9ccactcaggcagg9a9attcagcatcactc 3U ctgcggcgccttcataeacactaaagcttggagaatatggagaggtgacagtggactgtgaaccacggtca gggattgacaccaatgcatactacgtgatgactgttggaacaaagacgttcttggtccatcgtgagtggttcatg gacctcaacctccr..t~gagcag~ctggaa9tac'tcJtgtgga99aacagagagacgttaatggagtttgag gaaccacacgccacgaagcagtcfgtg atagcatfg99ctcacaagag98a9ctct9catcaagctttggrt g9agcca'LtcGtgtggaattttcaagcaaccactgtcaagtkgacgtcgggtcatttgaagtgtagagtgaagat ggaaaaattgcagttgaag9gaacaacctatggcgtct~gttcaaagg ctttcaagtttcttg99actcccgcag acacaggtcacg9cact9t99t9'~99aattgCag~cactggcacggatggaccttgcaaagttc~tatotc gtcagtg9cttcattgaacgar,~taacgoca~gtgggcagattggtcaatgtcaacccttttgtttcagtggccac 99ccaacgcfiaaggtcctgattgaat#ggaa~ccaccctttgg~gactcatacatagtggtg99~9aggaga acaacagatcaatcaccattggcacaagtctggaagcagcattggcaaagcctttacaa~ccetcaaau ga$cgoagag2~ctagccgotctaggagac~cagcttgggactitggatca~gttggaggggt9itcacctcag ttJggaa99~9tccatcaagtgttcgga99a9~ttctcactgttcgga9gcat9tcct99ataacgca 'I D
aggaitqctgggggctc~#cctgttgtggatgggcatcaatgctcgtgat2~ggtCCatagCtctcacgtttctcgca gttggaggag'ttctgctcttcctctccgtgaacgtgcacgcttaa SEt~ 1~ N° 6 ~ Mf~KKRGGKTG~4VMIG1"IASVGAVTLSNFQGKVMI~TVNATDVTDViTIPTAA~
15 KNLCiVRAruIDVGYtVICt~~TIT'YE~PVLSA~~IDI~ED:i~~,~.~TIr~A~~Y:~!~Y~!?C';" _ KTRHSRRSRRSLTV~tTHGESTLANKKGAWMDSTKA'TRYI_~IKTESWtLRNPG
YALVAAVtGWMLGSNTMQRVVF~ILLLLVAPAYSFN~LGMSNRDFLi~GVSGA
Twlillllill Gr~BIG.J'~~~W nernvrcr~ns~srfiasmarrwanW nrlrrsntrndri w~rire~t~ti nT
__. _ _ _ . . ...Cl~p~~~~~~~~NG~~FGKGSIDl~C:AfCFA
20 ~STKAIGP~TILKENIKYEVAIFVHGPTTVESH~NYSTc~VGAT~AGF~FSITPAAP
SYTLKLGEYGEVTVDCEPRSGIDTNAYYVMTVGTKTFLVHREWFMDLNLPW
SSAGSTV'VVRNRETLiUIEFEEPHATKQ~VIALGS~EGALHC~ALAGAIf~VEF.SSN
TVKLTSGHLKCRVK11AEKLQLKGTTY'GVDSKAFKFLCTPA~TGH(aTVIILEL(~Y
TGTDGPCKVPIS5V~4SLNDLTPVGRLVTVNPFVSVAI"ANAKVLIELEPPFGDS
25 YIVVGRGEQC.~IhIHHWHKS~Cx~'SIe~KA~TTTLKGAQRLAALGDTAV1PDFGSVG~
VFTSVaGKAVHQVFGGAFRSLFC~GMSWITQGI~I~GALLIrt,ltlMGINAI~DRSIALTF
LAVG~VLLFLSVNVHA*
3) NS1 protein from WNV
3a Ttze WNV NS1 gene was generated by RT-i'CR aarEplificatiQn of ~riral RNA
purified from viral particle$ (OfVNV iS-g8-ST'1 strain). The specific sequant~
was amplified using PfuTurbo DNA polymerase (Stratagene) and specific primers : MV-WhIN515 5'- TATCGTACC~ATGACGTCCATAGCTCTCACG-3' ~Bs'W9 site underlined) arid MV-WNNS13 5'_ ATAGCGCGCTCATTAGGTCTTTTCATCATt;TCTC-3' (BssHll site underlined)- A
start codon was added at the ~° end and fi~r~ stop codons at the 3' end pf the sequence. The whole sequence is 1110 nucleotides long, it~cl~ding the start and the two step cndorws, thus respecting the "rule of six°. The NS~1 protein generated contains its signet peptide sequence in N-tens (23 aa). 9t represents amino acids 7fi9-113 in WhE1! polyprotein and has the fatlowit~g sequence SEQ Itf N° 3 i atgaggtccatagctctcacgtttctcgcagt~ggaggagEtctgctcttcctctcxgtgaacgtgcacgctgaca ctgggtgtgccatagacatcagccggcaagagctgagatgtggaagkggagtgttcatacarraatgatgtgg aggcttggatggaccggtacaagtattaccotgaaacgccacaaggcctagccaagatcattcagaaagct cataaggaaggagtgtgcggtctacgatcagtttccagackggagcatcaaatgtgggaagcagtgaagga cgagctgaacactattttgaaggagaatggtgtggaccttagtgtcgtggttgagaaacaggagggaatgtac aagtcagcacetaaacgcctcaccgccaccacggaaaaattggaaattggctggaaggcctggggaaag agtattttatttgcaccagaactcgccaacaacacctttgtggttgatggtccggagaccaaggaatgtccgac tcagaatcgcgcttggaatagcttagaagtggaggattttggatttggtctcaccagcactcggatgttcctgaa 99t~9a9agag~acacaactgaatgtgactcgaagatcattgg aacggatgtcaagaacaacttggcg ~0 atccacac~tgacctgtcctattggattgaaagcaggctcaat'gatacgiggaagcttgaaag99oagtt~g9 gtgaagtcaaatcatgtacgtggcctgagacgcataccttg'tg9ggc9a'!~ggaatccttgagagtgacttgat aataccagtCacactggcgggaccacgaagcaatcacaatcggagacctgggtacaagacacaaaacc ag99cccatgg9acgaa99g9~Ja9a'g9acttc~attactgcccaggaactar,~ggtcaccctgagt gagagatgoggacaccgtggacctgccactcgcaccaccacagagagcggaaagttgataacagattggt 9~9~9ga9ct9~ccaccactgcgctaaccaaactgacago9gct9tt9gtatggtat9gagatca gaccacagagacatgatgaaaagacctaatga SEQ iD N° 7 s MRBIAI_TFL.AVGGVLLFL~VhIVHApTGCAipISRQELRCtaSGVFIHNI~VVEAUVM
3U C'yRYKYYPE-C'PQGLAK)IC~ISAHKEG1PCGLRSVSFLEHCN1WEAVKDEL1'JTLLI~E
NGVI7LSVWEKQEGIWW'~'KSAP4iRLTATTEKI.EIG1NKAWGKSItFAPELANNTF
VVDGPETKECPTQNRAUIINSt,EVEDFGFGLTSTRMFLifVVI~ESNT1'ECaSICIIG

1a TAVKNNLAIWSDLEYWtESRLNI~TVIIKI-ERAVL~EVI°C~GTWt~ETI°iTLWC~UGIL
E~D~IiPVTI_A~PRSNHNRRPGYKTC~NC~GPW~EGRVEIDFDYGPGTT'V'TLSE
SGtaHRCPATRTTTESGI~LITDWCGI~SCTLPPLRYQTDSGGWYUtuILIRPGRH
DEKT**
~6) preM-E protein from Dengue type 1 virus The Dengue ~rirus gene encoding the prelUl plus E glycdproteins ~nras generated by PCR amplification of piasmid pVL pINDI[prN1+E] (alone 2) ~COUI~AGEC7Ta IVL-P., FRENKIEb, nA.-P., lOllARTE DC~SAIVTC~~, G.N., I
DEIJREL, V. & DESPRES P. 2000, A-glucosidase inhibitors reduce dengue virus production by affecting the initial steps of virian rr~arphag~enesis in the endolasmic reticulurr9- ,laurnal of Virology 74: 4-~7~). This plasmid encodes the pre-A~
and E
i glycoproteins of DEN-1 virus strain FGAl139). The sequence was amplified using PfuTurbc~ GhIA polymerase ~Stratagene) and specific primers that contain unique sites for subsequent cloning in pTlkA-II~VSehw vector : AAV-DE~11 prel~E~r ~' TATCGTr4CGATGAACAGGAt~t; C~ATCG~TG-3' (BsiWl site underlined) and !4!V-.DENlprelblE3 5'-ATA~CC'aGGGTTAAACCAT .~.~AC:T~C~T~CaCaT ACA~'a-3' j (BssHll site underlined). A start and a stop colon were added at both ends a$ the gene. The whole secfuenr..e generated is 2C~4t3 nucleotides long, including the start 2t~ and the stop colons and respects the It~V "n,iie of six'aa In this construct, the G-terminus part of the G protein serues as a preiul translacatian signai. ~3otH
pre~l and E viral glycoprcxkoinE arc °b'aracrnet~r~rar.~-~.9y,:..,:::~°sr.~e-'!'$'e-a- :--;t er prr..w :~.~-J .
that DEN-'I env expressing tU9td will pfoduce and realease multimeric forms of preAJl-E heterodimers exhibiting high immunogenic pmtential. The construct represents amino acids 95-773 in DEN-'I polyprotein and has the fc~ltowing sequence:
SEC! If7 i11° 4 ~ atgaacaggaggaaaagatccgtgaccatgctcctcatgctgctgcccacagtcctgg~tttc~catttgacca cacgatJggg9aAa9Cr-ai:acatgatagttagtaagcaggaaagagg~aagtcactctkgttcaagac~ct gaag9tgtcaatatgtgcactctcattgcgatggatttgg9ac~agtta~gtga989actt~c~aaig cccccggatcactgag9cg9aaccagatgacgttgac#gctggtgcaatgceacagacacatgggtgacct atgggacgtgttctGaaaccg9t9aacaccgacgagacaaacgttccgtggcactg9ccccacacg~gg acttggtctagaaacaagaaccgaaacatggatgtcctctgaaggcgcctggaaacaaatacaaaaagtg 9a9a~99gga9a~cc~ggattcacggtgatagctcittttttagc:acatgccataggaacatccatc actcagaaagggatcattttcattctgctgatgctggtaacaccatcaatggccatgcgatgcgtgggaatagg caacagagacttcgttgaaggactgtcaggagcaacgtgg9t9gac9tg9tattggagcatggaagc.~tgcg tcaccaccatggcaaaaaataaaccaacattggacattgaactcttgaagacggaggtcacgaac~ctgcc gtcttgcgcaaattgtgcattgaagctaaaatatcaaacaccaccaccgattcaagatgtccaacaeaagga 9a99~acactggtggaagaacaagacgcgaactttgtgtgtcgacgaacggttgtggagaggctgg9 gcaatggctgcggactatttggaaaaggaagcctactgacgtgtgctaagttcaagigt9t9acaaaactgg aaggaaagatagtkt;aatatgaaaacttaaaatattcagtgatagtcactgtccacacaggggaccagGacc aggtgggaaacgagactacagaaca~qgaacaattgcaaccataacacctcaagctcctacgtcggaaat acagttgacagactacggaacttacactggactgcte;acccagaacagggctggactttaatgaggt9gt gctattqacaatgaaagaaaaatcatggcttgtccacaaacaatggtttctagacttaccactgccttggacttc gg999~caacatcccaagagacttggaacagacaagatttgctggtcacattcaagacagctcatgcaa 1 ~ agaagcaggaagtagtcgtactgggatcacaggaaggagcaatgcacactgcgttgaccggggcgacag aaatccagacgtcaggaacgaca~acaatcttfigcaggacacctgaaatgcagattaaaaatggata~ta~tg actttaaaagggatgtaatatgtga:g#gcacaggac.;,.;:;cwgs wgcgaaggucg:ggctgcgac~m.~.ag catggaactgtcctagtgc,~gttaaatargaaggaacagatgcgccatgcaagatccccttttogacccaa gatgagaaaggagtgacccagaatgggagattgata~a~g a.~-aatcccatagttactgacaaagaaaaa ccaatcaacattgagacagaaccaccttttggtgagagctacatcatagtaggggcaggtgaaaaagctttg aaactaag~tggtt~aagaaaggaagcagcatagg9aaaatgttcgaagcaat~gr"~gagga~g~acg aaggatggctatcctgggagacaccgcatgggacttcggctctataggaggagtgttkacgtctgtgggaaa attggtacaccaggtttttgg2~accgcatacggggtcctgttcagcg9cgtttctt9gaccatgaaa2taggaat agggatcttgctgacatggttgg9attaaattcaaggagcgc9tc9ctttcgatgacgt~cattgcagttggcat ggttacactgtacctaggagtcatggt#taa ~~GZ I~ N° $
Gi~nrae-lesl~t(1v !T~.1i Y s ~1 s P'eT6 !1 rr~ !e TTr.e-"trryy jq~pi~[~j/,irl~,"yyt~,p,y n re~~rly~,,~y ga.l_.. . _.. ___. .
MCTLIAMDLGELCEDTMTYKCPRtTEAEPaC>IIDCWGNATDTiN~TYGTDSGiT
~EHRI~I~KRSVALAPHVCaLGLETRTETWMSBEGAWKGIIQtCdIETWALRHPfiF
TVIALF~AFiAIGTSITQK~IIFILLMLVTP~MAMR~VGi4aNRDFIIEGi_SC~ATiI~~D
WLEHGS~V't'TMAKNKPTLDIELLKTEVT~,IPAiILRKL~GIEe4K6SttITTTDBRDF~T

QGEATt.VEEC~DANF\ICRRTVIdDRGWGNGCGI_FGKG~LLTCAKFKCVTKLEG
KIVC~YENLKYSVIVTVHTGI~(~HC~VGNETTEH ,t".~TIATITP'QAPTSEIQLTI~YGTL
TLOCSPRTGt_DFNEVVLLTMKEKSWLVI~KQWFLDLPLPWTSGASTSQI=TWN
RC~DL1.VTFKTAHAKKQEVWLGSG~EGAMHTALTGATEIQTSGTTTIFAGfILKC
RLKMDKLTLKGMSYVMCTGSFKLI=KEVAETC,~HGTV!-VQVKYEGTDAPCKII'F
STQDEKGV'I"QNGt~LITANPIVTDKEKPINIETEI~PFGESYIIVGAGEKALKLSWF
KKGSSIGKMFEAIARGARRMAILGDTAWDFGSIGGVI=TSVGKLVHG1VFGTAY
GVLFSGV'SWTMKIGIGII.I.T~IVIrG~.NSRSASLSMTCIA'~it;MVTLYLGVMV*
1~ The same irnmunogens can be prepared by the same way from DEN-2, DEId-~ and D~N~4 seratypes.
~~ Insertian into lulV Schwarz vector The different WNV and DEN-1 nucleotidlc sequences were cloned in pCR2.1 TaPD plasmid (Invitrogen) and sequenced to check that no n"iutations were introduced. After Bs~IVUBssHll digestion of the pGR~.1-TUPO plasmids, the DNA fragrnertts were stoned in the pTM-MVSchw vector in ATl? position 2 giving plasmids : pTM-MVSchw-EnvtJVNV, pTM-MVSchw-preMEwnv, pTM-MVSchw NS1 WNV and pTM~MVSohwypreMEDEN-1 according to lFigt~re 1.
i ~"~ 1819 dp I
i t~°~~ a:u aw CRi.t p~d~EE
r~w~~°-~~~.~: ...Y._....._.~~~-~-- xor9 s>a sews G
G F'P Yi L
~~'1~~~'!~C
T7 ~
(p.'~t1 ~s 2y ~'fM~ Ml/~,ychW-VNriIV
Figure '!
Schematic map of the pTM-MVSchw recombinant plasmids descrit ed Example 3 : Recovery of recorntxinant IInV~chw-EnvIH~~IV, NI~fSchw-pre141tEWNV and MVSchw-n1~1 NV diruses.
To recover recombinant Schwarc viruses from the plasmids, we used the helper-cell-based rescue system described by Radecke et al. (9l and moc3ed by Parks et al. (~0)_ Human helper cells stably expressing T'~ F~NA pc~lymerase and measles N and P proteins (283-3-,4B cells, a kind gift fre~m MA Billeter) were transfected using the calcium phosphate procedure with pTM-MVSchw-EnuVll~lV, pTM-MVSchw preMEwnv or pTM-MVSchw-NS'f WNV plasmids (~ Ng) and a plasmid expressing the MV polymerase L gene (pEMC-La, ~0 ng, a kind gift from MA ~illeter). After overnight incubation at 37° C, the trar~sfection mediurr~ was replaced by fresh medium and a heat shock was applied (43~ C for two hours) (~i Cl). After two days of incubation at 37° C, transfected cells were transferred an a CEF cells layer and incubated at 32° C in mrder to avoid any adaptafiQn of the i Schwarz vaccine that was t~riginally selected on CEF cells and is currently grown 'f5 on these cells for safety considerations. Infectious virus was easily recovered between 3 and 7 days following cocultivation. Syncykia appeared occasir~nally in CEF, but net systematically- The recombinant viruse$ were also rescued by the same technique after cocultivation of transfected 293-3-~~ f~elper cells at 37° ~
with primate Vero cells (african green r'nonkey kidney. In this case, syncytia ~t~ appeared systematically in all transfections after 2 days c~f coculture.
In order to increase the yield of rescue and because these recombinant viruses will be used in mice experiments, we used Veto cells a5 target cells in place of the ~rsuai crick embryo fibroblasts (CEF) (European Patent .Application N° I~22915~'1_6 files on June ~1~, 2g42), l~ecambinant viruses were passaged two times on Vero cells.
We 26 have previously shown that tvvo passages c~f the Schuvarz virtas on Vero cells did not change its immunogenic capacities in macaques (Eur~spean Patent Application IV° 0229'1551.6 files on Jane 20, 2802)_ The reGOmbinant viruses were prepared as described above and the expression of the transger~e in infected cells was checked by 30 immunofluorescence. To detect WNV Envelope glycoproteins expression, vne csed immune sera from mice resistant to WNV ir~fectic~n (International Patent AppIiGation WO 021081741}.To detect NSI protein expression, we used anti-NS1 Monoclonal antiobodies (International Patent Application N° Wp UC7rT6665).
Example 4.: Vaccination against West-Mile virus We constructed a recombinant ~chwar-.r measles attenuated virus expressing the WNV E salable farm and tested its capacity as vaccine candidate against WN
encephalitis. The LAIN cDNA corresponding to the sE protein of IS-9~-~T9 strain of WNV was introduced in an additional transcription unit in the Schwarz MV cC~NA
that we previously cloned (pTM-MVSchw) (Et~rapean ~'atent Application hJ°
~~~g~~~~a~~,I~Y~ w~nl 6v.~r~a~~~lr~~dc~rt$~~InIP~fY~~tVY~G%'B~ ~Bltl ll~lii IW
141~V1I iIC~
intraperitoneal challenge was tested.
A. MA~'ERtALS AND METHt~I~S
A1. ~efls and WN virus.
WN virus strain IS-98-ST1 was produced on masquitc Aedes AF'~'I cells as described in i~espres et at. (1993), Mashirno et al. (2002), and Lucas et af.
(2003), and DI2QO~t-~f7.
The clone Qf Veto-NK cetts used in this study was selec~ked for its capacity to fuse following infection with the Measles' virus and to then amplify the WN virus.
A2. Titration of the WN virus on AP69 mosquito cells by immonudetectian of viral replication foci (Focus Immuno Assay, J=IA) was parfarmed as described in Despres et at. (1993), Mashimo et al. (2000, and Lucas et al. (2~D03), and 131 200'1-17.
The WN vinrs infectious titer ors AP61 cells was determined in units forming foci an AI"'81 cells (Ap6~ UFFIm).
A3. PurifcatiQn of the V1IN virus pracfuced on AP61 ells was pertormed as descritxed in Despr~s et at. (1993}, Mashimo et al. (2002), and Lucas et al.
(2003), arid pl 2001-1~.

Briefly, the viral particles present in the supernatants of AP61 cells at 3-days post infection with the WN virus strain IS-98-ST1 (M~) t7,4) were concentrated with 7°!a PEG fit700 and then purified an a discontinuous (30-60°r6) sa~ccharrase gradient and 5 orf a Linear (10-50°!0) sa~charose gradient. WN virions at ~t~°!o saccharose were stored at - 84°C. The infectious titers obtained were appraxim~tely AP61 FF Ulml.
A4. petectian of anti-WN antibodies by ELtSA
10 Anti-WN antibody titers of diluted sera ('1:160) were determined by ELISA
with 106 AP81FFU WN IS-88-STi virions purified on a saocharase gradient as described in Despr~s ef a1_ (1993} and Mashirna et al_ (2002}.
A5. Anti-WN imrrrune Sera 15 Anti-WN immune sera were cC~itected in adult mice genetic~fly resistant to viral Errcephatitis (Mashimo et al., 2002) wf7ioh were challenged for at least One month with 9 03 AP61 FFU of the 1NN virus strain lSy9$-ST1 in~eoted intraperitaneally.
ELtSA anti-WtV titers of immune sera diluted 1:1C?C? ~nrer~ approximately 1,4 per DD
unit. Neutralizing TNRFgO titers of anti-WN sera were approximately 1600.
Anti-WN strain lS-98-ST1 mouse ascites (HMAF) ware collected from animals hyperirnmunized with crushec# brain of baby mice inoculated with V11N virus.
FLISA
titers of ante-WN HMAF diluted 1:1660 were apporximately 1 per DD unit.
Anti-WN immune sera roars used for indirect immunof8uoresoence and fc~r passive seraprotect~n tests. The anti-WN HNiAF were used for membrane ~a immun4detectinn of viral proteins.
Ai6. Construct~n of rrecombinant Schr~rz measles virus expressing WN sE
The WNV env gene encoding the secreted form of the protein eras generated by RT PCR amplification flf viral RNA pt~rifled from viral particles (WNV 1S-98-MTh ~0 straitz). fife speck seqr~ence was amplified using PfuTurbr~ DNA poiymerase (Stratagene) and specific primers that contain unique sites fvr subsequent cloning in pTM-MVSchw vector : MV-WNErivS 5'_ h.
TATCGTACG;ATGAGA(a~'TGTGT'1~TGTGGTGCTA-3' (~silN1 site underained) and MV INNEnv3 5'-ATAGCG~G~TTAGAtaAC~CTTCCCAACTGA-~' ~BssHll site underlined}. A start and a step codon were added at both ends of the gene. The whole sequence generated is 138Ct nucleotides long, including the start and the stop codon$ and respects the "rule t~f six", stipulating that tt~e nucteotides number of MV genome must be divisible by 6 [Calain, '1993 #19011; Schrteider, 1997 #'t9~7]. The Env pmtein thus generated contains its signal peptide in N-term ~1$
aa~ and no transmembrane region, Thus, it represents amino acids ~7~-?32 in WNV polyprotein and has the following sequence sEQ ID N° 1 ~
atgagagttgtgtttgtcgtgctattgcttt~qgtggccccagcttacagcttcaactgccttggaatgagcaacag agacttcttggaa9ga9t9tct9ga9caacat~ggt9999tt~c9aag9~Ja~~g~tg2~tatc atgtctaa~ggacaagcCtaccatcgatgtgaagatgatgaatatgga9gc9gtcaaCgcaga9gtccg cagttattgctatttggctaccgtcagcgatctCtccaccaaagGtgcgtgcccgaccatgggagaagctcac aatgacaaacgtgctgacccagGttttgtgtgcagacaaggagtggtggacag999~9J99~acg9~9 rggattatttgg~caaaggaagcattgac..atgcgccaaatttgcctgctctar"caaggcaataggaagaac catcttgaaagaga2ttatcaa~gtacgaagt9gccattttt9tccatggaccaactactgtggagtcgcacgga aartactccacacaggttgga9ccacggcaggga9attcagcatcactrctgccJgagcottcatacaca ctaaagcttggagaatatg9aga99tgacagt9gact9tAaacca~gtcagggattgacaccaatgcata °t4o9t~o'tgdc~~'~,~. aa~.acra~dL~iisai~~litx.-~eie,-~tgdc.~Iggncs~ZggaCCtcaa~CCiccc~Ittggag cagtgctggaagtactgtgtgga9gaaCagagagacgttaatggagtttga99aaccacaogccracgaag cagtctgtgatagcattgg9ctcacaagagggagctctgcatca2~gotttggctgga9ccatEcc~gtggaattt tcaagcaaca#gtcaagttgacgtcg9gtcatttgaagtc~t~anana~r~~tr,~~.ttgca~agg ~5 gaacaacctatggcgtctgttcaaaggc#itcaagtttcttgctgactcccgcagacacaggtcacggcactgtg gi9tt9gaatt9ca9tacactggcacgg~x'tgga~ttgcaaagttcctatctcgtcagtggcttcattgaargac ctaacgccagtc~ggcagattggtcactgtcaacccttftgtttcagtggccarx,~gccaacgctaaggtcctgatt gaa~gaacca~ttttggagactcatacatag'tggtgggca9a99agaacaacagatcaatcaccattg gcacaagtct~gaa~r c~a~c~tt~~~aaa,.,~, cc~tt~ta~y~~c~ac,s~,r,~~~~~~'~',~~~.~.c~a.__________.

~E~ fD N~
MRWFWLLLLVAPAYSFNC1~GMSNRI~FLEGVSGA~'W1ID~.VLEGDSC1N1MS
KDKPTIDVKMMNMEAVNLAEVRSYCYLi4TVSDLSTKAACPTMGF~HNDKI~A
DPAFVCRQGVVDRGWGNGCGLFGKGSIDTCAKFACSTKAIGRTILKENIKYE
VAIFVHGPTTVESHGNYSTQVGATCiAGRFSITPAAPSYT~.Kt.C3EYGEVTVDCE
PRSGIDTNAYYVMTVGTKTFLVHREWFMDLNLPWSSAGSTVWRNRETLMEF
EEPHATKQSVIALGSQE~aALHQALAGAIPVEFSSNTViCLTSC3HLK~RVKN1EK~.
Qi..KGTTYGVCSKAFKFLGTPADTGHGTVVLELQYTGTDGPCKVPISSVASLN
D~.TPVGRLVTVNPFVSVATANAKVLIELEPPFc~I~SYIhAIIGRt~EQGtINHHVVHKS
90 GSSIGtfAFfTTLKGAQRLAALGDTAWDFGSVGGVFTSVGKAV"
After agarase gel purification, the PCR fragment was cloned in pCR2.'1-TGPI~
plasmid (Invitrogen) and sequenced to check that rra rrrut~tions wePe introduced.
Affrler BsiW1lBssHli digestic~ry of the pCR2.'i-Tf~PC~ plasmid, the DNA
fragrner<t was 1~ clotted in the pTM-MVSchw vector itr ATII position 2 giving plasmid : pTM-MVSchw-sEINNV according to Figure 2.
A7. Production of recombinant measles virus expressing SdilN sE
To recover recombinant MV from plasmid, we used the helper cell-based rescue 2D system described by Radecke et ai. (Rar~ecke~ ~9g5 #2D~~] and modified by Parks et al. [Parks, 1999 #1900]. Human helper cells stably expressing T7 RNA
polymerise and Etreasles N and P proteins X293-3-48 cells, a kind gift from ~rlA
Billeter, University of Zurich) were transfi~cted using the calcium phosphate procedure with pTM-MVSohw-sEWNV plasmid (~ ~g~ acrd a plasmid expressing 25 the MV polymerise L gene (pEMC-La, 2U ng, a kind gift from MA Bilfeter).
After overnight irycubation at 37°C, the transfectian medium was replaced by fresh medium and a heat shack was applied (43° C for two hours) (Parks, '1999 #'19U0J.
After two days of incubation at 3?°C, transfected cells were transferred on a~ CEF
cells layer and incubated at 3~°C in order to avoid adaptation of the Schwarz 30 vaccine that was originally selected on CEF cells and is curre~rtfy grown on these cells. Infectious Virus was recovered befinreen ~ and ~ days following CocuItiVatiOn.
The recombinant virus was also rescued by the same technique after cocultivation of transfected 293--3-,4B helper cells at 37° C with Vero cells (africart green rt~onkey kidney, cone hero-NK). In order to increase the yie#d of rescue and because;these recombinant viruses were prepared to be used be used in mice experiments, we used Vero ~##s as producir;g cells in place of the usual chink embryo fibrs~blasts.
(GEF) (European Patent Appfi~ation N° ~I2291551.8 fi#es on June 20, 2002).
Single syncytia were harvested and transferred to Vero cells grown in ~amm wells in Dulbebecco's modified Eagle's medium (DMEM) supplemented with 5°/a fetal calf serum (FG5). The infected cells ware expanded in 7~ and 150 cm~ flasks.
alllhen syncytia reached 8t7-90°/a confluence (usually 36-~4~ hours prast infedtion), 1~ the cells were scraped in a small volume of DptiMEM (Gibco BRL) and frazeaa and thawed once. After !ow-speed centrifugation to pellet cellular debris, the supernatant, which c4ntained virus, was shred at -8iD°G. 1Ne have pt~evi~ausly shown that two passages of the Schwarz virus on Vero cells did not change its imrnunogenic capacities in macaques (European !'atent Application N°
02291 r1.6 files on June ~D, 2042) (Gombredet, 2003 #2~D~.
AS. Titration ref recombinant MV-'WN virus The titers of recombinant MV were determined by an endpoint limit dilution assay on Vero cells. b0°/a tissue culture infectious dose (TGiD50) were calculated using 2~ the K~rber method (Karber, 193'l #1989.
A9. lmmunofluorescence detection of UyNV sE expressed in Vero cells infected by MV WN sE recombinant virus.
The expression of the WN sE protein in cells infected by recombinant MV-V9iN
sE
was detected by immunofluorescence. Vero ~Ils were grown ~n potyornithine-coated coverslips and infected by MV V1IN sE at an Ar101 of CJ.~S. After two days of infection, coverslips were washed twice in PB5 and faxed for 15 minutes in paraformaldehyde (4°~ in P8S)_ #n same cases, ce#Is were perrne~abilized by Triton X1 ~0 (0.1 %, 5 min)_ After iwo PBS washes, coverslips were incubated for 1 b 3~ minutes at room temperaiure in PBS with 2°!o goat serum, then incubated for 1 hour at room temperature with mouse anti-WNV immune sera or mouse ant!-WNV
HMAF (see R5) diluted in P8S with ~nlo goat serum. After ~ruashing in PBS, cells were incubated for 45 minutes at room temperature with R~phycoerykhrin-cortjugated goat anti-mouse IgC~ (SBA, Birmingham). Following washing in PBS, caverslips were mounted on slides with fluoramount (Southern BiotecE~
Assaciates inc., Birmingham, Alabarna~.
__~ ______._._. .. . . .
AntE-MV antibodies were detected using a standard ELISA kit (Trinity Biotech, USA). An anti-mouse antibtydy-HRP conjugate (l~mersha~n) was used as the secondary antibody. Titers were determined by limiting dilutions and calculated as 1g the highest dilution of serum giving twice the absorbence of a 1I10~
dilution of a i mixture of control sera.
A11. Neutrallsatir~n assay by reduction of ~ThlRF9~) viral replication foci on VERO
cells 15 Sera to be tested was serially dilated in DMEM Glutarnaxf2°Io dec~mplen'tented FBS in 0,5 m! tuE~s.
For 0,1 ml diluted serum in DMEM ~lutamaxl2°/~ FBS, add 0,1 rr~i of DMEM
Gl~tama~cl2°!o FBS crantaining 100 APfi'3UF'F of W~tV strain E x-9~-T1.
Control cell. G,2 ml of DMEM D,2°!° FBS.
2t) Control virus: C~,2 rnl of C~MEM ~lutamaxl26/o FBS containing 'i 00 AP~1 UFF of WNV strain 1S-98-ST1.
IVlild rotation for 2 hours et 37°~ ;
12-well plates with ~ 150 SOD VBR~ HK cells per well were grawrl in monolayers for ~4 hours in dMEM Glutar'naxla% FMS ;
25 eeils are rinced once in DMEM 9 Add 0,~ ml DMiwM ~Eutarna~ t2°l° FBS ;
Add 0,2 m! serumIWEVI! mix on cells ;
Encubate far 2 horars at 37°C under CC~.
Remove ser~nv'WNV mix ;
30 Rirtce infected cells once with DM~IIA;
Add 'f ml DMEM 2%FBS per well ;
Add 1 ml CMC 1,fi% ditute~i in DMEM Glutamaxl2% FBS

~Q
Incubate for 2 days at 37'C ~~2.
Reveal plaques by FBA. ~etr~rmine the end point dilution irr~mune sera which neutralize at least 9D°la WN1I foci fcmm~sing units tested ors VERC~
cells (Ti~I~FgS).
The neutralizing anitbody titer of sera i~ determined in ThlRF9t~.
A12. Production of pseuda-particles of WhJlf by IUIEFt3T3.Tet~C~ffIprE.WAI #
h2 cell line.
Pseudo-particles of WNV strain IS-98-ST1 composed of prl~lE complexed glycoproteins vWere secreted by the MEFl3T3.Tet-OfflprNlE.YIIN # h2 cell line induced far expression of viva! proteins (CNCNI I-301$). Particles were purified from supernatants of 3 day cultures as in the protncole used for the p~trifcation of f WNV.
Passive serc~protection test against the VIIhJV in adult BALBdc rreice.
Six-meek-old E~ALBIc mice were provided by centre d'~levage ,#artvier. The viral challenge dose is 100 AP~IIIFF e_g. 10 ~f-6t3 ( Tomoshi et al., 2~0~) diluted in t 1~ ul CIf~BS supplemented with 0,~% BS,~ (bovirse serum albumine} at pH ~,5 (Sigma) inarulated intraperator~e~lly. fUlean mortality time was 10 days.
r4,r~imals were observed for two to three weeks.
Sera to be tested for p2~ssive seroprr~tection in mice were diluted in 0,1 ml 2~ t7f'BS10,2°Jo BSA and inacufated 24 hours before the viral challenge.

~. ~~~mTS ~ coi~c~usl~Ns B1. Fraduction of recombinant measles virus expressing ~'Vhi sly rthe cDNA coding for provtein E possessing a deleted transmembrane domain region of WNV strain IS-98-~T1 was introduced into the Measles' virus genome ( ~chwarz strait' as shown in Figure 2.
8siwt BssHl ~"~,vv~v ~~'' z T7~ n , sso ~
(ATEJ Los 2) ~igura 2 pTM-MV~ehw-sEWNV
Figure 2: Schematic representation of recombinant pTM-MVSchw $EWNV. The 'P f7 MV genes are indicated: N (nucleoprotein), F'VG (phosphoprotein and V, G
proteins), M (matrix), F (fusion), H (hemrnaglutinin), L (poiymerese). TT : T7 RNA
pcrlymerase promoter; T7t : T7 RNA polymerise tem~inatar; r3 : hepatitis delta virus (HDV) ribozyme; A"f"u : additional transcription unit.
After rescue, the recombinant virus was grown on Venn cell rr~onoiayers. The procedure used tra prepare the recombinant virus was similar to the standard procedures used to prepare #1e live attenuated measles ~rit~nes, exc~;pt for the Iyophilization that was not used.
~0 The WNV sE ~cpressir~n in Vero cells infected by the MV,llYihi sE ~rirus was verified by using indirect immunofluoreseence assay as shown ire Figure 3.

~19u~"e ~ : Expression of sE protein from WNV in lIIIV induced synaytia Figure 3 : Immunofluor~e,~.-ae-d2te~i~n-~--setei-'J~.IV-Env-~s~j pro~iE~ i~r -syrtcytia induced by recombinant MV-WN sE in Vero Delis. (A, B) sE prot~eir~
det8cted at the external since all around recembinant hull induced syncytia-(G, D) lntr~aceUula~r sE pratein in recombinant MV-induced syncyki~_ Q ~ ~r..~;.a,:...,.,. ,..,.....o..... w..._ ,.__..t._ _u__ _ __. ... . . _ _ .
,...., . ,~
Anti-WN immune sera to be tasted were obieined from rr~ice ger~tically resisEant to the disease (Allashimo et al., 2~0~). These anti-IfVN sera, tardily callected, are injected intraperitaneally in genetically sensitive adult BA Bfc mice at dilutions 1:~Q
('16 ThIRF90~ er~d 1:4Q (4 TPIf~Fga), in a final ~r~lume of 0, 1 ml DPBSICI,,~°/~ ~~A.
Antit~odies were administered anly 24 hours before the viral challenge ar 24 hours k~efore and 2~ following the test challenge with aL5t1 frarn ~IVtNV strain I~--~t'~-ST.
The negative contfol i the injectit~n of normal sera (mouse) diluted ~d:~90.
WNV
~ 5 neurovirulenae is evacuated in mice tested uvith C~I~8~d0,~Qlo SSA.
Results c~f passive proteatio~t obtained iwo weeks (allowing the viral challenge are Passive transfer Mortality M~7i~rD"~
P~SIBSA (0.~%) 615 10.5 (t1.5) raorrnal serum (1:10) 616 12.5 (t1.5) anti-WNV serum (1:'i0), 016 NA
2 doses'' anti-WNV serum {1:40), fl16 NA
2 doses 1 Base*"' 116 12 anti 1NNV serum (1:10) , Otra -NA
anti-WNV sen~m (1:44), 1 dose (*~Jlean ~ay O$ Death ~Si7) (**aay-1 and Qay+1 of virus challenge}
(**" Day--1 of virus challenge) .
Table 1 : Passive seraprotection against WNV encephalitis in adult 8AL131c mice.
Therefore a single intraprsritoneal injection of anti-WN ant~c~dies (2,5 fio 14 fsl of serum) obtained from mice genetically resistant to WNt! iota adult mice sensitive to viral encephalitis confers pasive protection against a challenge dQSe. : .
Sera of BAt-Slc mice having received anti-WN protective antibodies and having resisted to viral infection have El.ISA anti-WN antibody titers of approximately 1 per G1D unit (for a serum dilution of 1: 100) one month following the challenge. This 1D indicates. that V'JNV inoGUlated far the test has replicated in the protected mice and int~uced a humoral response. It' pas$ive serapratection protects against fatal WN
viral encephalitis, it dues not seem to block viral propagatie~n within alt infected individual.
8.~. Vaccination a~f irD4fi~!° iFN-«!pR-~- mice uvith MVIWN si= virus Mice susceptible for MV infection were obtained as described previously [Nirkic, 1998 #1918]. FVB mice he#erozyg~ous far the CD~l6 l~V receptor transgene [Yannoutsos, 1998 #9$02] ~a kind gift Pram F. Grosveld, Erasmus Unlv~rsity.
i=totterdam) were crossed with l~9Sv 1FN--a~jiR-~ mice ~Mullers 1994 #2011) (a ~Q kind gift from IW. Aguet, Swiss Institute far Experimental Cancer Research, Switzerland). The F1 progeny was screened by PCR and the GD4B ~'~- animals were crossed again with 129Sv iFN-ccl~iR-J mice. lFN-al~3RV~ GD~46 '"~ animals were se~cted and used for immunization experiments. Six-week,old Dl~4B+f- lF'N-al~R"~- mice were inoculated intraperitonealty with a singt~ close cf stan~3ard MV

s~
vaccine (906 TCID50, 3 mice) or V-Wfll s~ racc~m5inant virus ('ICI. or 106 T~CID50, 6 mice per dose) in 300 ~I phs~sphate buffer saline (PBS).
Serum u~ras collected from the eye one month follcawing vaccination with a single dr~~e in order to determine anti-MV, anft-VIIN E and neutralizing antibody production of the c3~atlenge rrirus.
6) Sera diluted 1:1000 and tested fir anti-MV antibodies by LISA
~~ti-11~~J s~ro~oy a~~t~. a~t~ tl~~ f~r~t ~~ e~tion 15 ~v io~
~tvwytv~~: eo~
MV-VV~1T-a~ IOa(females) MV-WN-sE 10'~
11~V.WlV,sk. I(1° (femalos) °~~ f7.0 4r5 d,0 i.5 2,0 2,5 O~
b) Sera diluted x:'!00 and tested for antiE'odies, by ELISA pur~~tecl'WNV
virion:
E~~ Unit 30 A~tti-WN rtlc3use Ascite : 1 (control +) Anti-WN mouse serum: 0,6 (cr~ntrol ~-~
MV vaccinated mouse serum: 0,110 ~ 0,005 MVIWN $~, 'IC~4 DCIPSt~ vaccinated mouse serum: 0,635 ~ 0,040 (mates) MV-WN s~, '104 ~)CIPSt~ vaccinated mouse serum: 0,8'15 t 0,005 (females) IE~.ISA M'lr Trinity Biotech t hit~rs I'mrnunseruan diitatiora : llID00 {timiti:n Secondary antihod~r : anti4tra(~ase I<G

MV V1TN sE, 106 DCIP50 vaocinated mouse serum. O,SOCJ t 0,200 (males) MV-WN sE, 10t517C1P5D vaccinated mouse serum: D,9~(I ~ 0.196 (females) c) In vitro Seraneutralization assay of WNV tn VERC~ cells TNRF90's crf pooled sera on 1 t7i~ AP61 UFF of WNV strain 1~-98-ST1 o~n VEI~O
i cells:

MV vaccinated mouse sera: ~ 1 ~
MV WN aE, 'f04. tlClP60 vaccinated mouse sera: ' 400 1 D Mil-1NN sE. 106 UCIPS~ va~oinated_mot~se ~pra: s~nn Therefore, antibodies directed against soluble glyooprotein E of WNV have the cap2~crty to neutralize in vitro the lS-98-~T1 strain used for the WNV
challenge in mice.
p y~ri,~~". ~.1..,,.a ,.." ,~,n ~.~.s./ ...... .., _ r . . ".. _. , r...-...........
following the initial vaccination, witty a sir~ie dose identical to that of the first injection.
Two weeks following the taaost, sera were tested by Ei_ISA and TNRF99 as previaus8y:
a) aera diluted 1:100 and tested for antibodies by ELtSA an purled WNV
viriors:
' OD unit 26 l~nti-WN mouse ascite: 1,~. {control +) Anti-.VtIN mouse serum: 7 {contrfile +~

MV vaccinated mouse serum_ ~, t 1 ~ ~ 0,005 ~ .

M~ ~M sE, 'IO~E DCIPS~J vaccinated mouse serum:0,8113 ~ 0.'i00 (males) M1r WN sE, 10$ aCIPSfJ vaccinated mouse serum-'1,151 ~ U,Q75 {females) MV WN sE, 1Q6 IaCIP50 vaccinated mouse serurrt:0.$65 ~ 0,230 (males) IVIV WN sE, 10B pC1P50 vaccinated mouse serum:'i,0e~5 ~ a,2d~ (females) b) In vitro seroneutralixation assay tin VERC3 cells TNRF90's of pooled sera on 10~ AP61UFF WNV 4~-98-ST'i strain on VERO cells:
~6 TNRF~O
MV boosted mouse serum : ~ 10 MV WN sE, 104 DCIP50 boosted mouse serum: > 18t?0 MV WN sE, 108 f3CIP50 boosted mouse serum: ~ 16001 Four weeks following the boost, sera were tested by ELlSA and TNRF80 as previously:
a) Sera diluted 1:'!00 and tested far anitbc~dies by ELiSA on purified VIIN
virion:
8 OD unit Anti-WN mouse ascite: 1,7 (controls +) Anti WN mouse serum. 1,2 (controls +) MV vaccinated mouse serum: 0,2 ihAAV WN sE, 104 DCIP50 vaccinated mouse serum: 1,5? (f 0,15) 1~ MV WN sE, 108 DCIPSC~ vaccinated mouse serum: 1,?6 (t 0,'10) b) Its vitro seroneuttalization assay on VI~RD ~:eils TNRi=90's of pooled sera on 10D AP01tJFF vVNV strain 1S-98-ST1 on VERI~ cells:
TNf;F90 1~ MV-WN sE, 904 DCIP50 vaccinated mouse serum: 4000 (ma3es) MV IrVN sP, 904 DClP50 vaccinated mouse serum: 800t7(femates) MV WN sE, 906 DCIP50 vaccinated mouse serum: 14 Q~00 - 12 000 Therefore, following a b~aaster of an identical close, anti-WNV antibody titers. and 2tl neutralizing anti WNV titers are significantly increase~t by a facto of 10 or more.
SpIenoGytes of CD46+!- iFN-aJ~iR-I mice immuni~d by two injections, four weeks apart, with MV WN sE virus at 1D4 or 106 I~~IP5f3 doses are tested by EL6' spot flow cytornetry for T CC34 et CCDB response following in vitro stimulation by:
viral 25 ~rseuda-particles virales purifed an saccharase gradients from irt~fuced MEFI3T3.'Tet ClfifIprME.WlV #it-2 cell supernatants {CNCM I-3D18).
8.4. Anti-!Nn passive steroprote~otian test in BALBlo mice for anti-E
antibodies Immunesera of CD4fi'*f- IF~1-a!(iR°d mice vaccinated wifh a single dose of 34 recombinant MV were coilecte~l after one month. Sera were injected at different ._..
dilutiorts in a final volume of 0,1 ml in six week old BALBIc mice and only ~4 Furs before intraperitoneal inoculation of 100 AP61UFF of WiVV strain IS-98-Sri.
{10 I~1,.60) see section B~_ Results for passive protection t~nro weeks following viral challenge are the following Passive transfer Mortality day Pf3SlC3SA (D.2°Jo) 818 1 t9 t0 11 anti WNV serum (1:1 D), D~6 I~A
1 hose' anti-WNV serum ('f:40)> 116 2p 1 Base anti-MV (1:1D), 1 dose 416 10 to anti-MV WN sE 9 De~4 316 8 to 10 (1:1 D), 1 dose anti-MV-WN sE 1 De6 (1:1f3t8 f~lA
D), 1 close anti-M1l-WN sE 1 De6 018 i~tA
(1:~.D), i dose anti-MV-WN sE 1 De6 (1:13~ 1 D td DD), 1 19 dose (*i3ay-1 of virus chafienge) Table 2 : Recombinant MV WN sE induce antibodies that provide full protection against WNV encephalitis in BALBIc mice Therefore, the antibodies directed against the WNV soluble glycoprotein E have the capacity to protect in vivo from WNV encephalitis. Single fn~ection vaccination "10 of ~D46~'!- IFN-a!(3R-!- mice at a dose of iars D~CIP50 of MV-WN sE virus was necessary in order to induce, over a four ~nreek period~ an anti N E humoral response capable of protecting against the disuse though passive seraprotectlan. A rrrinimal volume of 2,~ fcl immune sera from mice vaccinated with the MV WN sE virus is se~ffisant to confer complete protection adult BAi-Blc.
mice 15 challenged with a lethal dose of WNV ~e.g. a ratio of approximately ~,9nnl of immune serum ! kg). However immune sera diluted l:iD induced only partial protection (~ 3D°Jo) against Whit/ encephalitis.
Sera obtained from CD~46+'- !FN-ocl~R f- mice vaccinated and boosted at a knru 2(~ dose {10,4 TCIiD5D) are tested for their K;apacity to confer passive protection in BAi_Blc mice.

B.b. Vra1 challenge Qf Ca4F~'t IFN-ocl)3R--~- mice vaccinated with MV-WN sE
virus ~D46~'~ IFN-aJ~iR-l- mice waccir~ated two months following t~~c__irt~tifnnr _ weeks apart of 10S DCIP'5Q of Mli-WN sE virus ~nrere challenged with 100 AP6ItJFF of WN9 strain iS-:Iti-~ I 1.
The two mice vaccinated v~th the n-seasles standard died tt~e third day of the cl~aAenge. No morbidity or mortality was observed for the mice vaccinated with MV-WN sE by the seventlZ day of the challenge . Therefore, CD46+~- IFN-cxl~RW
mice immunized against WNV solulale gpl~ are protected against a lethal close of 1 fl lNNll irr the absence of interferon-alpha anti-viral aativ'ity.
E36. New anti-WN vaccination test with antigenic boost Adult GD~46+l- IFN-crJ~3R-l mice were vaccinated over a four week period with the ..._.~..,..~....,~ .~.__ ...~ _ ____ _. ._. _ _.. _.. ;_....... .. . .. , ~..
15 humans) and an antigenic boast was provided by purified WNV pseudo-particles j that were secreted by MEFl3T3.Tet-c?ffIWN prME # h2 cells.
References:
Despres et al. (1993). Virology 196: 209-2"19 20 Mashimo et al. (20x2)_ Proc.NatLAcad.Sci. USA 99: 11311-1131 Lucas et al. {2pp3). Imrnunoi. bell Biol.
Bibliography WNV
25 Anderson, d.i=., and Rahal, J.,1. (2002). Efficacy of interferon alpha-2b ar?d ribavirin against West Nile virus infection.
Anonymous (2Da2). Intrauterine West Nile virus infection-New York, 2002. MMWR
Morb Mortal Wkly Rep. 51 :1135-1'133f.
Br~inton, M.A. (2602). The molecular bioiogy of West IViie rrirus: a new invader of 30 the Western Hemisphere. Anna. Rev. Microbiol. 5fa: 371-402 Campk~ell, ta., Marfin, A.A_, l.anctotti, R.R., Gubler, D.J. (~~02}. West Nile virus_ The Lancet 2: 519-529 Crupi RS, Asnis GS, Lee CC, Santucci T, Marino MJ, Flanz ~J. X2403}. Meeting the challenge of bioterrorism: Lessons teamed from West 9Vile virus and anthrax, Am J Emerg Med_ 21:77-9.
Glass, J.D., Samuels, ~7., RiGh, iill.M. (2002). Poliomyelitis due to llVest Nile virus.
N. Engl. J. Med. Sep. 23 Lanciotti, R.S., I=bet., G.D., ~eubel, wl., and al. (2~OZ). complete gendme sequence analysis of West Nile virus strains isolated fnorn the United States, Europe, and the Middle East. Virology 298 : 96-1~5 Petersen, !_.F~., Roehrig, J.T., Hughes, J.M. (2002). West Nile virus encephalitis.
N. Engl. J. Med. 347: 1225-1228 (~~irk, M. (2D42}. First treatment trial for West Nile infection begins. The Lancet 2 Tesh RB, Arroyo J, Travassos Da Rosa A~', Guzman ti, ~iiao SY, Mor~th TP.
(20Q2). Ir~ca~cy of killed virus vaccine, live attenuated ci~nrneric virus vaccine, and passive immunization far prevention of Vilest Nile virus encephalitis in hamster model. Emerg Infect his. 8:1392-1391.
Monath TP, Arroyo J, Miller C, Guirakhoo F. (2fl01). West Nile virus vaccine_ Curr 2~ drug Targets Infect ~isord. 1 :3~-50.
$ibtiography MV
1. Enders, J. ~'. & Peebles, T. C. (19,~.~4) PraG_ Soc. Exp. viol. Med. 86, 2i~'-285.
2. ~ri~n; a. (20p1} in Field°s Virology, 4th Edition, eds. Knipe, t~. &
Howley, P.
(Lippincott - Raven Publishers, Phitadetphia}, Val_ 2, pp. 1 di3't-'1441.
3, Hilleman, M. ~~aoz) Vaccine 20, 651-fi&5.
Sch~nrarz, A. (19G2y Am. J. Dis. Child. 103, x!15-219.

5. Parks, C_ L., Lerch, F~. A., Waipita, P., Wang, H. 1~., Sidhu, Ni_ S. &
U~dem>
S. A. (2Q01 ) J Viro175, J10-2~.
Parks, G. L., Lerch, l~. A., Watpita, P., Wang, H. P., Si~lilu, NI. S. &
Uc9em, S. A. (~Od1) J Viral 75, 921-33.
7. Calais, P. 8~ Roux, L. X1993} J Viroi 57, X822-30.
8. Sahrieider, H., Kaetirn, !C. & Biileter, M. A. (1~~7} lfirQlo~gy 227, 3'!~-22. . .
9. Radecke, F., Spielhofer, P., S~hneider, H., Kaelire, iC., Hut'rer, M., lDotsch, ~., ~hristiansen, G. & Billeter, M. A. (1990 Embo J 1~, 57~3~.84.
90. ParKs, C. L., Lerch, R. i0.., Walpita, P., Sidhu, M. S. $~ Udem, S. A.
{'l999} J
Virol 73, 3560-6.

Claims (29)

1. A purified polypeptide wherein it derives from a West-Mile virus antigen or a Dengue virus antigen.
2. The polypeptide according to claim 1, wherein it is capable of inducing a protective immune response against a West-Nile virus or a Dengue virus in a mammal.
3. The polypeptide according to claim 1 or 2, wherein the West-Nile virus antigen is selected from the group consisting of secreted envelope glycoprotein (E), heterodimer glycoproteins (PreM-F) and NS1 protein.
4. The polypeptide according to claim 3, wherein the secreted envelope glycoprotein (E) comprises the sequence of SEQ ID NO: 5 or a fragment thereof.
5. The polypeptide according to claim 3, wherein the heterodimer glycoproteins (PreM-E) comprises the sequence of SEQ ID NO: 6 or a fragment thereof.
6. The polypeptide according to claim 3, wherein the NS1 protein comprises the sequence of SEQ ID NO: 7 or a fragment thereof.
7. The polypeptide according to claim 1 or 2, wherein the Dengue virus antigen is selected from the group consisting of secreted envelope glycoprotein (E), heterodimer glycoproteins (PreM-E) and NS1 protein.
8. The glycoproteins (PREM-E) comprises the sequence of SEQ ID NO: 8 or functional derivatives thereof.
9. The polypeptide according to any one of claims 1 to 8, which is an immunogenic peptide.
10. A purified polyclonal or monoclonal antibody capable of specifically binding to a polypeptide according to any one of claims 1 to 9, or to a fragment thereof.
11. An expression vector comprising a polynucleotide sequence coding.for a polypeptide according to any one of claims 3 to 9.
12. A purified polynucleotide sequence coding for a polypeptide according to any one of claims 1 to 9.
13. The purred polynucleotide sequence of claim 12 comprising a sequence selected from the group consisting of SEQ ID Nos: 1 to 4.
14. Use of a polynucleotide sequence as defined in claims 12 or 13 for detecting the presence or absence of a West-Nile virus antigen or a Dengue virus antigen in a biological sample.
15. A recombinant viral vector which is a recombinant virus comprising a polynucleotide sequence as defined in claim 12 or 13.
16. The recombinant viral vector of claim 15, wherein the recombinant virus is a live attenuated virus or a defective virus.
17. The recombinant viral vector of claim 15 or 16, wherein the recombinant virus is selected from the group consisting of measles virus, hepatitis B
virus, human papillomavirus, picornaviridae and lentivirus.
18. A recombinant measles virus capable of expressing a polypeptide according to any one of claim 1 to 9.
19. A recombinant measles virus comprising, in its genome, a polynucleotide according to claim 12 or 13.
20. The recombinant measles virus of claim 18 or 19, which is a live attenuated virus or a defective virus.
21. The recombinant measles virus according to any one of claims 18 to 20, which is derived from the Schwarz measles virus strain.
22. A pharmaceutical composition comprising:

a) at least one component selected from the group consisting of:

- a polypeptide according to any one of claims 1 to 9 or a fragment thereof;

- an antibody according to claim 10;

- an expression vector according to claim 11;
- a polynucleotide according to claim 12 or 13, - a recombinant viral vector according to any one of claims 15 to 17;
and - a recombinant measles virus according to any one of claims 18 to 21;
and b) a pharmaceutically acceptable vehicle or carrier.
23. The pharmaceutical composition of claim 22, capable of inducing a protective immunity against a West-Nile virus or a Dengue virus in a mammal or in a bird.
24. Use of a pharmaceutical composition according to claim 22, as an anti-West Nile virus agent, or for the preparation of an anti-West-Nile virus vaccine.
25. Use of a pharmaceutical composition according to claim 22, as an anti-Dengue virus agent, or for the preparation of an anti-Dengue virus vaccine.
26. A host cell incorporating an expression vector as defined in claim 11 or a recombinant viral vector as defined in any one of claims 15 to 17.
27. Method of producing a recombinant virus for the preparation of an anti-West-Nile virus vaccine of an anti-Dengue virus vaccine, the method comprising the steps of:

a) providing a host cell as defined in claim 26;
b) placing the host cell from step a) in conditions permitting the replication of a recombinant virus capable of expressing a polypeptide according to any one of claims 1 to 9; and c) isolating the recombinant virus produced in step b).
28. The cell line deposited at the C.N.C.M. under accession number I-3018.
29. A West-Nile virus neutralization assay, comprising the steps of:

a) contacting VERO cells with West-Nile virus and an antibody;

b) culturing said VERO cells under conditions which allow for West-Nile virus replication; and c) measuring reduction of West-Nile virus replication foci on said VERO
cells.
CA002432738A 2003-02-26 2003-06-20 New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications Abandoned CA2432738A1 (en)

Priority Applications (12)

Application Number Priority Date Filing Date Title
CA002432738A CA2432738A1 (en) 2003-02-26 2003-06-20 New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications
EP04714865.5A EP1599495B9 (en) 2003-02-26 2004-02-26 Dengue and west nile virus proteins and genes and their therapeutic application
CA002456873A CA2456873A1 (en) 2003-02-26 2004-02-26 West nile virus proteins and genes coding the foregoing and their use in vaccinal, therapeutic and diagnostic applications
ES04714865T ES2394307T3 (en) 2003-02-26 2004-02-26 Proteins and genes of the West Nile virus and dengue and its therapeutic application
PCT/IB2004/001027 WO2004076619A2 (en) 2003-02-26 2004-02-26 New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications
DK04714865.5T DK1599495T3 (en) 2003-02-26 2004-02-26 PROTEINS AND GENES OF DENGUE AND WEST NILE VIRUS AND THERAPEUTIC APPLICATION THEREOF
CA2517258A CA2517258C (en) 2003-02-26 2004-02-26 Recombinant measles virus comprising dengue or west nile virus polynucleotides, and their use in vaccinal and therapeutic applications
BRPI0407840A BRPI0407840B8 (en) 2003-02-26 2004-02-26 recombinant measles virus, pharmaceutical composition, use of a pharmaceutical composition, bacterial cell, method for producing a recombinant virus and use
IL170418A IL170418A (en) 2003-02-26 2005-08-22 Recombinant virus which is a live attenuated or a defective measles virus, pharmaceutical composition comprising same, its use and method of preparation
US11/210,960 US7556812B2 (en) 2003-02-26 2005-08-25 Dengue and West Nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications
HK06105979.8A HK1086278A1 (en) 2003-02-26 2006-05-24 Dengue and west nile virus proteins and genes and their therapeutic application
US12/476,304 US8859240B2 (en) 2003-02-26 2009-06-02 Dengue and West Nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
CA2,420,092 2003-02-26
CA002420092A CA2420092A1 (en) 2003-02-26 2003-02-26 New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications
CA002432738A CA2432738A1 (en) 2003-02-26 2003-06-20 New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications

Publications (1)

Publication Number Publication Date
CA2432738A1 true CA2432738A1 (en) 2004-08-26

Family

ID=32909240

Family Applications (1)

Application Number Title Priority Date Filing Date
CA002432738A Abandoned CA2432738A1 (en) 2003-02-26 2003-06-20 New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications

Country Status (9)

Country Link
US (2) US7556812B2 (en)
EP (1) EP1599495B9 (en)
BR (1) BRPI0407840B8 (en)
CA (1) CA2432738A1 (en)
DK (1) DK1599495T3 (en)
ES (1) ES2394307T3 (en)
HK (1) HK1086278A1 (en)
IL (1) IL170418A (en)
WO (1) WO2004076619A2 (en)

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US8475808B2 (en) 2003-05-23 2013-07-02 Novartis Vaccines And Diagnostics, Inc. Immunogenic reagents from west nile virus

Families Citing this family (20)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE60233038D1 (en) 2002-06-20 2009-09-03 Pasteur Institut Infectious cDNA of an approved measles virus vaccine strain. Use in immunogenic compositions
EP1375670B1 (en) 2002-06-20 2013-06-12 Institut Pasteur Recombinant measles viruses expressing epitopes of antigens of RNA viruses and use of the recombinant viruses for the preparation of vaccine compositions
US20050287170A1 (en) * 2002-12-11 2005-12-29 Hawaii Biotech, Inc. Subunit vaccine against West Nile viral infection
CA2432738A1 (en) * 2003-02-26 2004-08-26 Philippe Despres New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications
EP1740727A1 (en) 2004-04-30 2007-01-10 Baxter International Inc. System and method for detecting west nile virus
FR2870126B1 (en) * 2004-05-17 2009-07-17 Pasteur Institut RECOMBINANT LENTIVIRAL VECTOR FOR EXPRESSION OF FLAVIVIRIDAE PROTEIN AND ITS APPLICATIONS AS VACCINE
FR2871888A1 (en) * 2004-06-22 2005-12-23 Pasteur Institut Method for diagnosis and detection of flavivirus, especially West Nile virus, infection, by immunoassay using new antibodies specific for the secreted form of non-structural protein 1
US8158413B2 (en) * 2005-10-17 2012-04-17 Institut Pasteur Lentiviral vector-based vaccine
US8222029B2 (en) 2005-05-16 2012-07-17 Institut Pasteur Lentiviral vector-based vaccine
CA2508266A1 (en) * 2005-06-20 2006-12-20 Institut Pasteur Chimeric polypeptides and their therapeutic application against a flaviviridae infection
CN106377767A (en) * 2008-05-26 2017-02-08 卡迪拉保健有限公司 Combined measles-human papilloma vaccines
CA2735164C (en) * 2008-08-29 2021-08-31 Boehringer Ingelheim Vetmedica, Inc. West nile virus vaccine
US20120141520A1 (en) * 2009-05-31 2012-06-07 Beth-Ann Coller Recombinant subunit west nile virus vaccine for protection of human subjects
EP2571990A4 (en) 2010-05-21 2013-11-20 Univ Pittsburgh Universal dengue virus sequences and methods of use
ES2842595T3 (en) 2011-03-14 2021-07-14 Boehringer Ingelheim Animal Health Usa Inc Equine rhinitis vaccine
EP2759301A1 (en) 2013-01-24 2014-07-30 Institut Pasteur Use of a genetically modified infectious measles virus with enhanced pro-apoptotic properties (MV-DeltaC virus)
WO2016110869A2 (en) * 2015-01-05 2016-07-14 Joshi Vishwas Dattatraya Dna molecules producing custom designed replicating and non-replicating negative stranded rna viruses and uses there of
EP3184119A1 (en) * 2015-12-23 2017-06-28 Themis Bioscience GmbH Chromatography based purification strategies for measles scaffold based viruses
US11459619B2 (en) 2016-02-08 2022-10-04 The Johns Hopkins University Handheld nucleic acid-based assay for rapid identification
EP3474892A1 (en) 2016-06-24 2019-05-01 Institut Pasteur Compositions and methods comprising measles virus defective interfering particles for the prevention of infectious diseases

Family Cites Families (25)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
IL91304A0 (en) 1988-08-20 1990-03-19 Us Health Recombinant vaccinia virus for prevention of disease caused by flavivirus
AU7007491A (en) * 1990-02-02 1991-08-08 Schweiz. Serum- & Impfinstitut Bern Cdna corresponding to the genome of negative-strand rna viruses, and process for the production of infectious negative-strand rna viruses
JP3045581B2 (en) 1991-10-14 2000-05-29 社団法人北里研究所 Measles vaccine virus strain identification method
ATE181112T1 (en) 1995-08-09 1999-06-15 Schweiz Serum & Impfinst CDNA CORRESPONDING TO THE GENOME OF MINUTE-STANDED RNA VIRUSES AND METHOD FOR PRODUCING INFECTIOUS MINUTE-STANDED RNA VIRUSES
MY150893A (en) * 1996-09-24 2014-03-14 Bavarian Nordic As Recombinant mva virus expressing dengue virus antigens, and the use thereof in vaccines
AU4427897A (en) * 1996-09-27 1998-04-17 American Cyanamid Company 3' genomic promoter region and polymerase gene mutations responsible for att enuation in viruses of the order designated mononegavirales
HU228705B1 (en) 1997-02-28 2013-05-28 Univ St Louis Chimeric flavivirus vaccines
US7192593B2 (en) * 1997-05-23 2007-03-20 The United States Of America, Represented By The Secretary, Department Of Health And Human Services Use of recombinant parainfluenza viruses (PIVs) as vectors to protect against infection and disease caused by PIV and other human pathogens
US7227011B2 (en) * 1998-06-04 2007-06-05 United States Of America As Represented By The Secretary Of The Department Of Health And Human Services, Centers For Disease Control And Prevention Nucleic acid vaccines for prevention of flavivirus infection
US6146642A (en) 1998-09-14 2000-11-14 Mount Sinai School Of Medicine, Of The City University Of New York Recombinant new castle disease virus RNA expression systems and vaccines
JP2003506039A (en) 1999-08-02 2003-02-18 ワイス Rescue of epidemic parotitis virus from cDNA
SI1317559T1 (en) 2000-04-28 2009-04-30 St Jude Childrens Res Hospital Dna transfection system for the generation of infectious negative strand rna virus
CA2440593A1 (en) * 2001-03-12 2002-09-19 Yale University Compositions and methods comprising west nile virus polypeptides
DE60233038D1 (en) 2002-06-20 2009-09-03 Pasteur Institut Infectious cDNA of an approved measles virus vaccine strain. Use in immunogenic compositions
EP1375670B1 (en) 2002-06-20 2013-06-12 Institut Pasteur Recombinant measles viruses expressing epitopes of antigens of RNA viruses and use of the recombinant viruses for the preparation of vaccine compositions
CA2432738A1 (en) * 2003-02-26 2004-08-26 Philippe Despres New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications
EP1454988A1 (en) * 2003-03-03 2004-09-08 Institut National De La Sante Et De La Recherche Medicale (Inserm) Infectious flavivirus pseudo-particles containing functional prM-E envelope proteins
EP1694829B1 (en) * 2003-12-02 2010-08-04 Institut Pasteur Novel strain of sars-associated coronavirus and applications thereof
CA2508266A1 (en) * 2005-06-20 2006-12-20 Institut Pasteur Chimeric polypeptides and their therapeutic application against a flaviviridae infection
ES2423518T3 (en) 2006-12-22 2013-09-20 Institut Pasteur Cells and methodology to generate unsegmented negative sense chain RNA viruses
EP2058003A1 (en) * 2007-10-10 2009-05-13 Institut National De La Sante Et De La Recherche Medicale (Inserm) Medicaments and methods for treating mesothelioma
EP2085479A1 (en) * 2008-01-31 2009-08-05 Institut Pasteur Reverse genetics of negative-strand rna viruses in yeast
CN106377767A (en) 2008-05-26 2017-02-08 卡迪拉保健有限公司 Combined measles-human papilloma vaccines
GB0815872D0 (en) * 2008-09-01 2008-10-08 Pasteur Institut Novel method and compositions
EP2427201B1 (en) 2009-05-05 2015-01-28 Cadila Healthcare Limited Combined measles-malaria vaccine

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US8475808B2 (en) 2003-05-23 2013-07-02 Novartis Vaccines And Diagnostics, Inc. Immunogenic reagents from west nile virus

Also Published As

Publication number Publication date
US20130089558A1 (en) 2013-04-11
BRPI0407840B8 (en) 2021-05-25
HK1086278A1 (en) 2006-09-15
EP1599495B9 (en) 2013-11-13
BRPI0407840B1 (en) 2020-05-26
WO2004076619A2 (en) 2004-09-10
ES2394307T3 (en) 2013-01-30
BRPI0407840A (en) 2006-02-14
US8859240B2 (en) 2014-10-14
EP1599495B1 (en) 2012-08-29
EP1599495A2 (en) 2005-11-30
US20060073164A1 (en) 2006-04-06
US7556812B2 (en) 2009-07-07
DK1599495T3 (en) 2012-12-03
IL170418A (en) 2014-11-30
WO2004076619A3 (en) 2005-03-17

Similar Documents

Publication Publication Date Title
CA2432738A1 (en) New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications
US10793877B2 (en) Recombinant measles viruses expressing epitopes of antigens of RNA viruses—use for the preparation of vaccine compositions
US20230310581A1 (en) A live attenuated measles virus vectored vaccine for sars-cov-2
Tangy et al. Live attenuated measles vaccine as a potential multivalent pediatric vaccination vector
CA2755257A1 (en) Replication-defective flavivirus vaccine vectors against respiratory syncytial virus
EP3846848A1 (en) Dna plasmid-launched live-attenuated vaccines for plus-sense single stranded rna viruses
EP3823654B1 (en) Methods for treatment of cancer using chikungunya-vsv chimeric virus
US20120263751A1 (en) Recombinant Measles Virus Useful as a Bivalent Vaccine Against Measles and Nipah Infections
CA2517258C (en) Recombinant measles virus comprising dengue or west nile virus polynucleotides, and their use in vaccinal and therapeutic applications
CA2420092A1 (en) New dengue and west nile viruses proteins and genes coding the foregoing, and their use in vaccinal, therapeutic and diagnostic applications
Lorin et al. A paediatric vaccination vector based on live attenuated measles vaccine
CA2456873A1 (en) West nile virus proteins and genes coding the foregoing and their use in vaccinal, therapeutic and diagnostic applications
TANGY et al. Sommaire du brevet 2517258
TANGY et al. Patent 2517258 Summary

Legal Events

Date Code Title Description
FZDE Discontinued