VACCINE COMPRISING AN ATTENUATED PESTIVIRUS
Attenuated pestiviruses, in particular attenuated BVDV, wherein at least one mutation is in the coding sequence for glycoprotein Ems and at least another mutation in the coding sequence for Npro which preferably leads to combined inactivation of the RNase activity residing in glycoprotein Ems in addition to the inactivation of the (hypothesized) immunomodulating activity residing in Npro. Methods for attenuating pestiviruses such as BVDV, nucleic acids encoding the pestiviruses, in particular BVDV, compositions and vaccines comprising the attenuated pestiviruses, in particular BVDV, of the invention.
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This application claims benefit of U.S. Ser. No. 60/589,361, filed Jul. 20, 2004, and claims priority to German Application No. 10 2004 025 452.4, filed May 19, 2004, each of which is hereby incorporated by reference in its entirety.
FIELD OF THE INVENTIONThe present invention relates to the field of animal health and in particular to attenuated pestiviruses such as bovine viral diarrhea virus (BVDV).
BACKGROUND OF THE INVENTIONPestiviruses are causative agents of economically important diseases of animals in many countries worldwide. Presently known virus isolates have been grouped into four different species which together form one genus within the family Flaviviridae.
- I/II. Bovine viral diarrhea virus (BVDV) type 1 (BVDV-1) and type 2 (BVDV-2) cause bovine viral diarrhea (BVD) and mucosal disease (MD) in cattle (Baker, 1987; Moennig and Plagemann, 1992; Thiel et al., 1996). The division of BVDV into 2 species is based on significant differences at the level of genomic sequences (summarized in Heinz et al., 2000) which are also obvious from limited cross neutralizing antibody reactions (Ridpath et al. 1994).
- III. Classical swine fever virus (CSFV), formerly named hog cholera virus, is responsible for classical swine fever (CSF) or hog cholera (HC) (Moennig and Plagemann, 1992; Thiel et al., 1996).
- IV. Border disease virus (BDV) is typically found in sheep and causes border disease (BD). After intrauterine infection of lambs with BDV persistently infected lambs can be born that are weak and show different abnormalities among which the “hairy shaker” syndrome is best known (Moennig and Plagemann, 1992; Thiel et al., 1996).
Pestiviruses are small enveloped viruses with a single stranded RNA genome of positive polarity lacking both 5′ cap and 3′ poly(A) sequences. The viral genome codes for a polyprotein of about 4000 amino acids giving rise to final cleavage products by co- and post-translational processing involving cellular and viral proteases. The viral proteins are arranged in the polyprotein in the order NH2—Npro—C-Ems-E1-E2-p7-NS2-NS3-NS4A-NS4B—NS5A-NS5B—COOH (Lindenbach and Rice, 2001). Protein C (=core- or capsidprotein) and the glycoproteins Ems, E1, and E2 represent structural components of the pestivirus virion as demonstrated for CSFV (Thiel et al., 1991). This also holds true for BVDV. E2 and, to a lesser extent, Ems were found to be targets for antibody neutralization (Donis et al., 1988; Paton et al., 1992; van Rijn et al., 1993; Weiland et al., 1990, 1992). Ems lacks a typical membrane anchor and is secreted in considerable amounts from the infected cells; this protein has been reported to exhibit RNase activity (Hulst et al., 1994; Schneider et al., 1993; Windisch et al., 1996). The function of this enzymatic activity for the viral life cycle is presently unknown. The enzymatic activity depends on the presence of two stretches of amino acids conserved between the pestivirus Ems and different known RNases of plant and fungal origin. Both of these conserved sequences contain a histidine residue (Schneider et al., 1993). Exchange of each of these residues against lysine in the Ems protein of a CSFV vaccine strain resulted in the destruction of RNase activity (Hulst et al., 1998). Introduction of these mutations into the genome of the CSFV vaccine strain did not influence viral viability or growth properties but led to a virus exhibiting a cytopathogenic phenotype (Hulst et al., 1998). Similarly, Meyers et al. showed that an RNase negative variant of the virulent CSFV strain Alfort/Tübingen was fully viable. However, the respective virus mutant showed no cytopathogenic phenotype (Meyers et al., 1999).
Npro represents the first protein encoded by the long open reading frame in the pestivirus RNA. Npro represents a nonstructural protein that has protease activity and cleaves itself of the nascent polyprotein (Stark et al., 1993; Wiskerchen et al., 1991) presumably already during translation. Npro is a cysteine protease (Rümenapf et al., 1998) that is not essential for virus replication (Tratschin et al., 1998). Recently, it was shown that Npro somehow interferes with the cellular antiviral defense so that it can be hypothesized to modulate the immune system within an infected host (Rüggli et al., 2003). Mayer and coworkers presented indications for an attenuation of CSFV in consequence of a deletion of the Npro gene (Mayer et al., 2004).
Present BVDV vaccines for the prevention and treatment of BVDV infections still have drawbacks (Oirschot et al., 1999). Vaccines against the classical BVDV-1 provide only partial protection from BVDV-2 infection, and vaccinated dams may produce calves that are persistently infected with virulent BVDV-2 (Bolin et al., 1991; Ridpath et al., 1994). This problem is probably due to the great antigenic diversity between type 1 and type 2 strains which is most pronounced in the glycoprotein E2, the major antigen for virus neutralization (Tijssen et al., 1996). Most monoclonal antibodies against type 1 strains fail to bind to type 2 viruses (Ridpath et al., 1994).
Vaccines comprising attenuated or killed viruses or viral proteins expressed in heterologous expression systems have been generated for CSFV and BVDV and are presently used. Killed vaccines (inactivated whole virus) or subunit vaccines (conventionally purified or heterologously expressed viral proteins) are most often inferior to live vaccines in their efficacy to produce a full protective immune response even in the presence of adjuvants.
The structural basis of the attenuation of BVDV used as live vaccines is not known. These vaccines, although attenuated, are most often associated with safety problems. The vaccine viruses may cross the placenta of pregnant animals, e.g., cows, and lead to clinical manifestations in the fetus and/or the induction of persistently infected calves. Therefore, they cannot be applied to breeding herds that contain pregnant cows. Pregnant cows have to be kept separate from vaccinated cattle to protect fetuses and must not be vaccinated themselves. Furthermore, revertants of attenuated live BVDV pose a serious threat to animals. For conventionally derived attenuated viruses wherein the attenuation is achieved by conventional multiple passaging, the molecular origin as well as the genetic stability of the attenuation remains unknown and reversion to the virulent wild-type is unpredictable.
Because of the importance of an effective and safe as well as detectable prophylaxis and treatment of pestiviral infections, there is a strong need for improved attenuated pestiviruses, such as BVDV, with a high potential for induction of immunity as well as a defined basis of attenuation which can also be distinguished from pathogenic pestiviruses, such as BVDV, as well as compositions and vaccines comprising the attenuated pestiviruses, such as BVDV.
Therefore, the technical problem underlying the present invention is to provide improved attenuated pestivirus, preferably an attenuated BVDV for use as live attenuated vaccines. Such improved attenuated pestivirus, preferably BVDV, should especially (i) not cross the placenta themselves, and (ii) induce an immunity that prevents viral transmission across the placenta and thereby prevents pregnancy problems like abortion of the fetus or birth of persistently infected host such calves in the case of BVDV infection.
All subsequent sequences show the deleted regions indicated with dashes (−), which are also numbered, whereas the sequences in the sequence listing attached hereto are continuously numbered without the deleted regions or amino acid codons.
SEQ ID NO:1 XIKE-A-cDNA sequence
SEQ ID NO:2 XIKE-A-NdN-cDNA sequence
SEQ ID NO:3 XIKE-B-cDNA sequence
SEQ ID NO:4 XIKE-B-NdN-cDNA
SEQ ID NO:5 XIKE-A amino acid sequence
SEQ ID NO:6 XIKE-A-NdN amino acid sequence
SEQ ID NO:7 XIKE-B amino acid sequence
SEQ ID NO:8 XIKE-B-NdN amino acid sequence
SEQ. ID NO:9 XIKE-C-NdN amino acid sequence
SEQ ID NO:10 XIKE-C-NdN-cDNA sequence
SEQ ID NO:11 XIKE-C-cDNA sequence
SEQ ID NO:12 XIKE-C amino acid sequence
SUMMARY OF THE INVENTIONThe present invention relates to attenuated pestivirus, preferably to attenuated BVDV, wherein at least one mutation is in the coding sequence for glycoprotein Ems and at least another mutation in the coding sequence for Npro which preferably leads to combined inactivation of the RNase activity residing in glycoprotein Ems in addition to the inactivation of the (hypothesized) immunomodulating activity residing in Npro. The invention also relates to methods for attenuating pestivirus in such that the attenuation results in an attenuated pestivirus, preferably in an attenuated BVDV, as described above. The present invention furthermore relates to nucleic acid molecules encoding the attenuated pestiviruses, preferably encoding attenuated BVDV, compositions and vaccines comprising the attenuated pestivirus, preferably BVDV as disclosed herein.
DETAILED DESCRIPTION OF THE INVENTION Definitions of Terms Used in the DescriptionBefore the embodiments of the present invention it must be noted that as used herein and in the appended claims, the singular forms “a”, “an”, and “the” include plural reference unless the context clearly dictates otherwise. Thus, for example, reference to “a BVDV” includes a plurality of such BVDV, reference to the “cell” is a reference to one or more cells and equivalents thereof known to those skilled in the art, and so forth. Unless defined otherwise, all technical and scientific terms used herein have the same meanings as commonly understood by one of ordinary skill in the art to which this invention belongs. Although any methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, the preferred methods, devices, and materials are now described. All publications mentioned herein are incorporated herein by reference for the purpose of describing and disclosing the cell lines, vectors, and methodologies as reported in the publications which might be used in connection with the invention. Nothing herein is to be construed as an admission that the invention is not entitled to antedate such disclosure by virtue of prior invention.
The term “pestivirus” as used herein refers to all members of the genus Pestivirus, including BVDV, CSFV, and BDV, within the family Flaviviridae.
The term “CSFV” as used herein refers to all viruses belonging to species of classical swine fever virus (CSFV) in the genus Pestivirus within the family Flaviviridae.
The term “BVDV” as used herein refers to all viruses belonging to species bovine viral diarrhea virus (BVDV) type 1 (BVDV-1) and BVDV type 2 (BVDV-2) in the genus Pestivirus within the family Flaviviridae (Heinz et al., 2000). The more classical BVDV type 1 strains and the more recently recognized BVDV type 2 strains display some limited but distinctive differences in nucleotide and amino acid sequences.
The term “NP'” as understood herein relates to the first protein encoded by the viral open reading frame and cleaves itself from the rest of the synthesized polyprotein (Stark et al., J. Virol. 67:7088-7093 (1993); Wiskerchen et al., Virol. 65:4508-4514 (1991)). The term, depending on the context, may also relate to the remaining “Npro” amino acids after mutation of the encoding nucleotide sequence or to the coding nucleotide sequence for the protein itself. “Protease activity residing in Npro” relates to the polypeptide cleavage activity of the “Npro”.
“Ems” as used herein relates to the glycoprotein Ems which represents a structural component of the pestivirus virion (Thiel et al., 1991). Ems lacks a typical membrane anchor and is secreted in considerable amounts from the infected cells; this protein has been reported to exhibit RNase activity (Hulst et al., 1994; Schneider et al., 1993; Windisch et al., 1996). It should be noted that the term glycoprotein E0 is often used synonymously to glycoprotein Ems in publications. The term, depending on the context, may also relate to the mutated “Ems” protein after mutation of the encoding nucleotide sequence or to the coding nucleotide sequence for the protein itself. “RNase activity residing in glycoprotein Ems” relates to the RNA cleavage activity of the glycoprotein, i.e., the ability of the glycoprotein Ems to hydrolyze RNA. The term “inactivation of the RNase activity residing in the glycoprotein” refers to the inability or reduced capability of a modified glycoprotein Ems to hydrolyze RNA as compared to the unmodified wild-type of the glycoprotein Ems.
“An attenuated pestivirus or BVDV particle” as used herein means that there is a statistically significant difference between the virulence of attenuated pestivirus or BVDV particles of the present invention, wherein the attenuated viral particles being attenuated by a method described herein, and wild-type pestivirus or BVDV isolates from which the attenuated pestivirus or BVDV particles have been derived, for the predominant clinical parameters, in case of BVDV for diarrhea, pyrexia, and lethality in animals infected with the same dose, preferably 6×106 TCID50. Thus, the attenuated BVDV particles do not cause diarrhea, pyrexia, and lethality and thus may be used in a vaccine.
“Inactivation of Ems” as used herein means RNase activity not significantly above the level measured for noninfected control cells in an RNase assay as described in Meyers et al., 1999. “Not significantly above the level measured for noninfected control cells in an RNase assay as described in Meyers et al., 1999,” means for example, that the RNase activity is less than 150% compared to the noninfected control cells.
“Inactivation of Npro” as used herein means the prevention or considerable reduction of the probable immunomodulating activity of Npro by mutation. In a preferred embodiment, this mutation prevents or considerably reduces the interference of Npro with the induction of an interferon response by the infected cells as described by Rüggli et al., 2003. In this case, the inactivation of Npro would allow the cell to mount a normal interferon response.
“Processing signal” as used herein relates to a substance that ensures the generation of a functional N-terminal of the C protein of the pestivirus, preferably of BVDV, in particular a substance selected from the group of ubiquitin, LC3, SUMO-1, NEDD8, GATE-16, and GABA(A)RAP. Also proteases selected from the group of intein, picornavirus 3C, caridovirus 2A, and p15 of rabbit hemorrhagic disease virus are understood as “processing signals” as used herein. Any other similar processing signal known to the skilled person that ensures the generation of a functional N-terminal of the C protein shall also be comprised in the term “processing signal”.
“Protein C” or “C protein” or “C-protein” as used herein relates to a structural component of the pestivirus virion (Thiel et al., 1991). “Protein C” is the capsid or core protein of pestiviruses. The term, depending on the context, may also relate to the “Protein C” with one or several amino acids exchanges resulting from mutation of the encoding nucleotide sequence.
A “fragment” according to the invention is any subunit of a polynucleotide molecule according to the invention, i.e., any subset. For DNA, the fragment is characterized in that it is shorter than the DNA covering the full length viral genome.
A “functional variant” of the nucleotide molecule according to the invention is a nucleotide molecule which possesses a biological activity (either functional or structural) that is substantially similar to the nucleotide molecule according to the invention. The term “functional variant” also includes “a fragment”, “a functional variant”, “variant based on the degenerative nucleic acid code”, or “chemical derivative”. Such a “functional variant”, e.g., may carry one or several nucleotide exchanges, deletions, or insertions. The functional variant at least partially retains its biological activity, e.g., function as an infectious clone or a vaccine strain, or even exhibits improved biological activity. “Possess a biological activity that is substantially similar” means with respect to the pestiviruses provided herewith, for example, that the pestivirus is attenuated in a manner described herein and result in an non-pathogenic virus suitable for the production of live attenuated virus, which loss ability to pass the placenta but mediates an immune response after vaccination.
A “variant based on the degenerative nature of the genetic code” is a variant resulting from the fact that a certain amino acid may be encoded by several different nucleotide triplets. The variant at least partially retains its biological activity, or even exhibits improved biological activity.
A molecule is “substantially similar” to another molecule if both molecules have substantially similar nucleotide sequences or biological activity. Thus, provided that two molecules possess a similar activity, they are considered variants as that term is used herein if the nucleotide sequence is not identical, and two molecules which have a similar nucleotide sequence are considered variants as that term is used herein even if their biological activity is not identical.
A mutation as used herein relates to modifications in the nucleic acid molecules encoding the proteins/amino acids according to the invention. The mutations relate to, but are not limited to, substitutions (replacement of one or several nucleotides/base pairs), deletions (removal of one or several nucleotides/base pairs), and/or insertions (addition of one or several nucleotides/base pairs). As used herein, mutation may be a single mutation or several mutations, therefore, often the term “mutation(s)” is used and relates to both a single mutation and several mutations. The mutations include, but are not limited to point mutations (single nucleotide mutations) or larger mutations wherein, e.g., parts of the encoding nucleic acid molecules are deleted, substituted, and/or additional coding nucleic acid is inserted. The mutations may result in a modified expressed polypeptide due to the change in the coding sequence. Such modified polypeptides are desired, as set out in the disclosure of the invention as set out below.
The term “vaccine” as used herein refers to a pharmaceutical composition comprising at least one immunologically active component that induces an immunological response in an animal and possibly but not necessarily one or more additional components that enhance the immunological activity of the active component. A vaccine may additionally comprise further components typical to pharmaceutical compositions. The immunologically active component of a vaccine may comprise complete virus particles in either their original form or as attenuated particles in a so called modified live vaccine (MLV) or particles inactivated by appropriate methods in a so called killed vaccine (KV). In another form the immunologically active component of a vaccine may comprise appropriate elements of the organisms (subunit vaccines) whereby these elements are generated either by destroying the whole particle or the growth cultures containing such particles and optionally subsequent purification steps yielding the desired structure(s), or by synthetic processes including an appropriate manipulation by use of a suitable system based on, for example, bacteria, insects, mammalian, or other species plus optionally subsequent isolation and purification procedures, or by induction of the synthetic processes in the animal needing a vaccine by direct incorporation of genetic material using suitable pharmaceutical compositions (polynucleotide vaccination). A vaccine may comprise one or simultaneously more than one of the elements described above. The term “vaccine” as understood herein is a vaccine for veterinary use comprising antigenic substances and is administered for the purpose of inducing a specific and active immunity against a disease provoked by a pestivirus infection, preferably by a BVDV infection. The attenuated pestivirus, in particular the attenuated BVDV as described herein, confer active immunity that may be transferred passively via maternal antibodies against the immunogens it contains and sometimes also against antigenically related organisms. A vaccine of the invention refers to a vaccine as defined above, wherein one immunologically active component is a BVDV or of pestiviral origin or derived from a nucleotide sequence that is more than 70% homologous to any known pestivirus sequence (sense or antisense).
The term “live vaccine” refers to a vaccine comprising a living, in particular, a living viral active component.
Additional components to enhance the immune response are constituents commonly referred to as “adjuvants”, e.g., aluminum hydroxide, mineral or other oils, or ancillary molecules added to the vaccine or generated by the body after the respective induction by such additional components, like but not restricted to interferons, interleukins, or growth factors.
A “pharmaceutical composition” essentially consists of one or more ingredients capable of modifying physiological, e.g., immunological functions, of the organism it is administered to, or of organisms living in or on the organism. The term includes, but is not restricted to, antibiotics or antiparasitics, as well as other constituents commonly used to achieve certain other objectives such as, but not limited to, processing traits, sterility, stability, feasibility to administer the composition via enteral or parenteral routes such as oral, intranasal, intravenous, intramuscular, subcutaneous, intradermal, or other suitable route, tolerance after administration, or controlled release properties. One non-limiting example of such a pharmaceutical composition, solely given for demonstration purposes, could be prepared as follows: cell culture supernatant of an infected cell culture is mixed with a stabilizer (e.g., spermidine and/or bovine serum albumin (BSA)) and the mixture is subsequently lyophilized or dehydrated by other methods. Prior to vaccination, the mixture is then rehydrated in aqueous (e.g., saline, phosphate buffered saline (PBS)) or non-aqueous solutions (e.g., oil emulsion, aluminum-based adjuvant).
The solution to the above technical problem is achieved by the description and the embodiments characterized in the claims.
It has surprisingly been found that pestiviruses, in particular BVDV, can be more effectively attenuated by introducing at least one mutation in the coding sequence for glycoprotein Ems and at least another mutation in the coding sequence for Npro which preferably leads to combined inactivation of the RNase activity residing in glycoprotein Ems in addition to the inactivation of the immunomodulating activity residing in Npro. An immunomodulating effect in one aspect is indicated but not limited to the indicated function for one pestivirus in an exemplary manner by Rüggli et al., 2003.
A pestivirus, in particular BVDV, attenuated in accordance with the present invention may be advantageously used in vaccines. The attenuated pestivirus, in particular the attenuated BVDV, now provide live vaccines of high immunogenicity. Surprisingly, the pestivirus, in particular the BVDV, according to the invention furthermore are safe for use in pregnant animals as they do not cross the placenta. This is exemplified in a non-limiting manner for BVDV in Example 3.
Furthermore, live vaccines with defined mutations as a basis for attenuation will allow to avoid the disadvantages of the present generation of vaccines, e.g., the risk of reversion to an more pathogenic strain. A further advantage of the attenuating mutations lies in their molecular uniqueness which allows to use them as distinctive labels for an attenuated pestivirus, in particular BVDV, and to distinguish them from pestivirus, in particular BVDV, from the field. Therefore, in one aspect the present invention provides an attenuated pestivirus, in particular an attenuated BVDV, having at least one mutation in the coding sequence for glycoprotein Ems and at least another mutation in the coding sequence for Npro. Preferably, in such attenuated pestivirus, preferably in such attenuated BVDV, the mutation in the coding sequence for glycoprotein Ems leads to inactivation of the RNase activity residing in Ems and/or the mutation in the coding sequence for Npro leads to inactivation of the Npro. The inactivation may take place by any mutation known to the person skilled in the art of the Ems- and the Npro-coding sequence, wherein the mutations are any mutation as defined in the Definitions of Terms Used in the Description section above, such as deletions, insertion mutations, and/or substitution mutations. Most preferably, the mutation(s) are deletions, as the likelihood for revertation to the wild-type is the lowest for deletions.
It has been shown that the glycoprotein Ems forms a disulfide-bonded homodimer of about 97 kD, wherein each monomer consists of 227 amino acids corresponding to the amino acids 268 to 494 of the CSFV polyprotein as described by Rümenapf et al., 1993. The genome sequence of the Alfort/Tübingen strain of CSFV is available in the GenBank/EMBL data library under accession number J04358; alternatively, the amino acid sequence for the BVDV strain CP7 can be accessed in the GenBank/EMBL data library (accession number U63479); in the BVDV CP7 polyprotein, the Ems protein corresponds to residues 271 to 497. Two regions of amino acids are highly conserved in glycoprotein Ems as well as in some plant and fungal RNase-active proteins (Schneider et al., 1993). These two regions are of particular importance to the RNase enzymatic activity. The first region consists of the region at the amino acids at position 295 to 307 (298 to 310 for BVDV strain CP7) and the second region consists of the amino acids at position 338 to 357 (341 to 360 for BVDV strain CP7) of the viral polyprotein as exemplified for the Alfort strain of CSFV in Meyers et al., 1999 (numbering according to the published deduced amino acid sequence of CSFV strain Alfort/Tübingen (Meyers et al., 1989). The amino acids of particular importance to the RNase activity as mentioned above are by no means limited to the exact position as defined for the Alfort/Tübingen strain of CSFV but are simply used in an exemplary manner to point out the preferred amino acids being at that position or corresponding to that position in other strains such as found in BVDV, BDV, and pestiviruses in general since they are highly conserved. For pestiviruses other than the CSFV Alfort/Tübingen strain, the numbering of the positions of the preferred amino acids can be different but an expert in the field of the molecular biology of pestiviruses will easily identify these preferred amino acids by the high degree of conservation of this amino acid sequence and the position of these motifs in the sequence context. In one particular non-limiting example, the position of CSFV Alfort/Tübingen 346 is identical to position 349 of BVDV strain CP7.
As a consequence, the present invention preferably relates to a BVDV according to the invention, wherein the mutation(s) in the coding sequence for glycoprotein Ems are located in the encoding nucleotide sequence corresponding to amino acids at position 298 to 310 and/or position 341 to 360. Preferably, such mutations are (where amino acids are given in the one letter symbols; the amino acid before the position number indicates the amino acid to be substituted, the amino acid after the position number the substituting amino acid (del indicates deletion): for example, H300L means histidine 300 was substituted by leucine):
Suitable modification of the glycoprotein Ems are for example, the single substitutions/deletions: S298G, H300K, H300L, H300R, H300del, W303G, P304de1, E305A, C308G, R343G, E345del, W346G, K348A, H349K, H349L, H349de1, H349Q, H349SV (mutation H349S and insertion of V), K348R, W351P, W351G, W351L, W351K, W351H; the double substitutions/deletions: H300L/H349L, K348del/H349del, H349del/G350de1, E345del/H349de1, W303G/E305A, H300K/H349K, H300K/H349L and the triple deletions: L299de1/H300del/G300del, K348del/H349del/G350de1. Numbering is according to the published amino acid sequence of BVDV CP7 for all the mutants listed above (the given numbers minus 3 would correspond to the equivalent residues of the CSFV Alfort/Tübingen amino acid sequence). All the above-listed mutants were at least tested as respective CSFV or BVDV mutants without mutations in the Npro region. Suitable mutants of the pestiviral glycoprotein Ems are provided, for example, by WO 99/64604, which is incorporated herein in its entirety. It should be noted, however, that according to the present invention, at least one additional mutation in the Npro region, as disclosed in further detail below, must be present.
It was particularly found that deletion or substitution of the histidine residue at position 346 (CSFV) or 349 (BVDV) leads to effective inactivation of Ems and therefore leads to particularly useful pestiviral live vaccines. The present invention demonstrates that pestiviruses are viable and code for an Ems protein without RNase activity when the histidine residue at position 346 of the viral polyprotein (numbering according to the published sequence of CSFV Alfort/Tübingen (Meyers et al., 1989)), or at position 349 (numbering according to the published sequence of BVDV CP7 (Meyers et al., 1996b)) if the pestivirus is BVDV, which represents one of the conserved putative active site residues of the Ems RNase, is deleted. Thus, preferably, the invention also relates to a BVDV according to the invention, wherein the mutation in the coding sequence for glycoprotein Ems is a deletion or substitution of the histidine residue at position 349. Even more specifically, the putative active site of the RNase is represented by the conserved Ems sequences SLHGIWPEKICTG and/or LQRHEWNKHGWCNWFHIEPW (sequence of the BVDV-2 NewYork93 protein given here in an exemplary manner; minor changes can possibly be found in other pestivirus sequences but the identity of the motif will always be obvious for an expert in the field. As an example, the corresponding amino acid sequences of BVDV-1 CP7 would be SLHGIWPEKICTG and/or LQRHEWNKHGWCNWYNIEPW and that of CSFV Alfort/Tübingen SLHGIWPEKICKG and/or LQRHEWNKHGWCNWYNIDPW). Thus, preferably, the invention further relates to a BVDV according to the invention, wherein the mutation(s) in the coding sequence for glycoprotein Ems are located in the nucleotide sequence coding for the conserved Ems sequence SLHGIWPEKICTG and/or LQRHEWNKHGWCNWFHIEPW. These sequences are representing the putative active site of the RNase. The sequences SLHGIWPEKIC and RHEWNKHGWCNW of the putative Ems active site are even more conserved across pestiviruses. Thus, preferably, the invention also relates to a pestivirus, in particular to BVDV, having at least one mutation in the coding sequence of the Npro protein and the glycoprotein Ems, wherein the mutation(s) in the coding sequence for glycoprotein Ems are located in the nucleotide sequence coding for the conserved Ems sequence SLHGIWPEKIC and/or RHEWNKHGWCNR. Preferably, the mutation is located in only one of the sequences. Thus the invention also relates to a pestivirus, in particular to BVDV, having at least one mutation in the coding sequence of the Npro protein and the glycoprotein Ems, wherein the mutation(s) in the coding sequence for glycoprotein Ems are located in the nucleotide sequence coding for the conserved Ems sequence SLHGIWPEKIC or RHEWNKHGWCNR. Preferably, such mutations concern two different amino acids, i.e., are double mutations. Thus, the mutations may be 1 to 3 nucleotide mutations in two different triplets encoding two amino acids. Thus, the invention also relates to a pestivirus, in particular to BVDV having at least one mutation in the coding sequence of the Npro protein and the glycoprotein Ems, wherein the mutation(s) in the coding sequence for glycoprotein Ems are two mutations located in the nucleotide sequence coding for the conserved Ems sequence SLHGIWPEKIC and/or RHEWNKHGWCNR. Preferably, such mutations concern a single amino acid. Thus, the mutation may be 1 to 3 nucleotide mutations in one triplet encoding one amino acid. Thus, the invention also relates to a pestivirus, in particular to BVDV, having at least one mutation in the coding sequence of the Npro protein and the glycoprotein Ems, wherein a single mutation is located in the conserved Ems sequence SLHGIWPEKIC or RHEWNKHGWCNR.
As mentioned above, the attenuated pestiviruses provided by the present invention, having at least on mutation in the coding sequence of the glycoprotein Ems and in the coding sequence of the Npro protein, wherein the mutation preferably result in inactivation of the RNase activity residing in the glycoprotein Ems and of the immunomodulating activity residing in Npro. Inactivation of the Npro is achieved in pestiviruses, in particular BVDV, of the specified formula described more in detail below, wherein between 0 and all amino acids of Npro are present; ubiquitin or LC3 or another sequence serving as processing signal (e.g., SUMO-1, NEDD8, GATE-16, GABA(A)RAP, or proteases, e.g., intein, picornavirus 3C, caridovirus 2A, or p15 of rabbit hemorrhagic disease virus) is present or absent. In case a processing signal is present, the coding sequence of the processing signal is inserted at or close to the C-terminal end of the (remaining part of the) Npro-protein. Only in the case that a processing signal is present, any number of amino acids coding for Npro (═Npro amino acids) may be present. In case no processing signal sequence is inserted, a maximum of 12 amino acids, preferably aminoterminal amino acids, of Npro may be present, the remaining amino acids have to be deleted. Furthermore, other than the Ems mutations as disclosed above (at least one of which has to be present in the pestivirus, in particular in BVDV according to the invention), the remaining sequences of the pestivirus, in particular BVDV may remain unchanged, i.e., are not mutated, or may also have mutations close to the N-terminal end of the C-protein. A number of more specific embodiments as disclosed below exemplify this.
Thus, the invention relates to a pestivirus, in particular to BVDV according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
[Npro]x−[PS]y−[C-term],
wherein:
- [Npro] relates to the Npro portion of the polyprotein, wherein x represents the number of amino acids of the Npro present in the polyprotein;
- [PS] relates to a processing signal selected from: ubiquitin, LC3, SUMO-1, NEDD8, GATE-16 or GABA(A)RAP) or proteases, e.g., intein, picornavirus 3C, caridovirus 2A, or p15 of rabbit hemorrhagic disease virus, or the like, or any processing signal known to the skilled person that ensures the generation of a functional N-terminal of the C-protein and y may be 0, which means that no processing signal is present (i.e., that PS is absent), or y may be 1, which means that a processing signal is present (i.e., that PS is present);
- [C-term] relates to the complete pestivirus, in particular the complete BVDV polyprotein except for Npro, but including the capsid (C)-protein and any other protein present in the pestivirus polyprotein, in particular in the BVDV polyprotein including the carboxyterminal NS5B. Preferably, the glycoprotein Ems in the [C-term] is mutated, in such that the RNase activity residing in the glycoprotein Ems is inactivated. The term “any other protein present in the pestivirus polyprotein/BVDV polyprotein” relates to Ems, E1, E2, p7, NS2, NS3, NS4A, NS4B, and NS5A, wherein glycoprotein Ems is mutated, preferably as disclosed herein (see above), in such that the RNase activity residing in the glycoprotein Ems is inactivated. Preferably, the pestivirus, in particular the BVDV, according to the invention has a C-protein which is not mutated except for the amino acid at position 2 which is changed from D to N. Therefore, [C-term*] is the same as [C-term] but with a mutation at position 2 of the C-protein (N instead of D);
- if y is 0 (which means that no [PS] is present) then x is 0 to 12, (which means no Npro specific amino acid or 1 to 12 amino acids of Npro, preferably of the N-terminus of Npro, are present); and
- if y is 1 (which means that [PS] is present) then x is 0 to 168; (which means no Npro specific amino acid or 1 to all 168 amino acids of Npro, preferably of the N-terminus of Npro, are present).
Also more preferably, the invention relates to a pestivirus, in particular to BVDV according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
[Npro]1−[PS]0−[C-term],
wherein the definitions are as defined above.
A specific example thereof is disclosed below, wherein the N-terminal methionine is followed by the C-protein and any other protein present in the polyprotein including the carboxyterminal NS5B. Hence, most preferably, the invention relates to a pestivirus, in particular BVDV, according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
M[C-term],
wherein the definitions are as defined above.
Also more preferably, the invention relates to a pestivirus, in particular to BVDV, according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
[Npro]3−[PS]0−[C-term],
wherein the definitions are as defined above.
A specific example of BVDV is disclosed below, wherein the N-terminal methionine is followed by the Npro sequence EL and the C-protein and any other protein present in the polyprotein including the carboxyterminal NS5B. Hence, most preferably, the invention relates to a BVDV according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
MEL−[C-term],
wherein the definitions are as defined above.
Also more preferably, the invention relates to a pestivirus, in particular to BVDV according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
[Npro]4−[PS]0−[C-term],
wherein the definitions are as defined above.
A specific example of BVDV is disclosed below, wherein the N-terminal methionine is followed by the Npro sequence ELF and the C-protein and any other protein present in the polyprotein including the carboxyterminal NS5B. Hence, most preferably, the invention relates to a BVDV according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
MELF−[C-term],
wherein the definitions are as defined above.
Also more preferably, the invention relates to a pestivirus, in particular to BVDV, according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
[Npro]6−[PS]0−[C-term],
wherein the definitions are as defined above.
A specific example of BVDV is disclosed below, wherein the N-terminal methionine is followed by the Npro sequence ELFSN and the C-protein and any other protein present in the polyprotein including the carboxyterminal NS5B. Hence, most preferably, the invention relates to a BVDV according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
MELFSN−[C-term],
wherein the definitions are as defined above.
Also more preferably, the invention relates to a pestivirus, in particular to BVDV, according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
[Npro]4−[PS]0−[C-term*],
wherein the definitions are as defined above except for the fact that the aminoterminal part of the C-protein is changed.
A specific example of BVDV is disclosed below, wherein the N-terminal methionine is followed by the Npro sequence ELF and in the C-protein sequence, the amino acid at position 2 is changed from D to N. Therefore, the aminoterminal C-protein sequence is SNEGSK . . . instead of SDEGSK. Hence, most preferably, the invention relates to a BVDV according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
MELF−[C-term*],
wherein in the C-protein the amino acid at position 2 is changed from D to N, and the definitions are as defined above.
Also more preferably, the invention relates to a pestivirus, in particular BVDV, according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
[Npro]x−[PS]1−[C-term],
wherein the definitions are as defined as above, and PS is any of the PS disclosed above, preferably selected from the group of ubiquitin or LC3.
A specific example of BVDV is disclosed below, wherein the N-terminal methionine is followed by any 21 or 28 Npro amino acids, ubiquitin, or LC3 and the C-protein. Hence most preferably, the invention relates to a BVDV according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
[Npro]22−[PS]1−[C-term], wherein preferably the PS is ubiquitin or LC3, or
[Npro]29−[PS]1−[C-term], wherein preferably the PS is ubiquitin or LC3.
Ubiquitin is a well known highly conserved cellular protein of 76 amino acids. Among other functions, ubiquitin is a key player in protein catabolism since conjugation with ubiquitin can mark a protein for degradation via the proteasome. Ubiquitin conjugated with or fused to other proteins via the carboxyterminal glycine can be cleaved off by cellular ubiquitin-specific proteases. Thus, fusion of a protein to the carboxyterminus of ubiquitin will usually result in defined proteolytic cleavage of the fusion protein into its components when expressed within a cell.
LC3 (light chain 3 of microtubule associated proteins) represents a cellular protein of 125 amino acids that serves a variety of functions (length given for bovine LC3). Recently, a fundamental role of the protein in autophagy has been defined. During this process, LC3 is activated by carboxyterminal cleavage. Thereby, a new carboxyterminus is generated that consists of glycine. LC3 is then conjugated via the carboxyterminal glycine to phosphatidylethanolamine present in the membranes of autophagic vesicles. Because of this process, a protein fused to the carboxyterminus of LC3 will be cleaved off by a cellular protease at a defined position.
Also more preferably, the invention relates to a pestivirus, preferably to BVDV according to the invention, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula selected from the group of:
[pro]2−[PS]y−[C-term] and preferably ME−[PS]y−[C-term];
[Npro]5−[PS]y−[C-term] and preferably MELFS−[PS]y−[C-term];
[Npro]7−[PS]y−[C-term] and preferably MELFSNE−[PS]y−[C-term];
[Npro]8−[PS]y[−C-term] and preferably MELFSNEL−[PS]r[C-term];
[Npro]9−[PS]y−[C-term] and preferably MELFSNELL−[PS]y−[C-term];
[Npro]10−[PS]y[C-term] and preferably MELFSNELLY−[PS]y−[C-term];
[Npro]11−[PS]y−[C-term] and preferably MELFSNELLYK−[PS]y−[C-term]; and
[Npro]12−[PS]y−[C-term] and preferably MELFSNELLYKT−[PS]y−[C-term],
wherein the definitions are as defined as above. The preferably disclosed embodiments refers to BVDV. Most preferably, y is 0 (i.e., no PS is present).
Also more preferably, the BVDV according to the invention as described supra is a BVDV type 1 BVDV. Most preferably, the BVDV according to the invention as described supra is a BVDV type 2 BVDV. BVDV-1 and BVDV-2 are differentiated according to features of their genomic sequences (Heinz et al., 2000 and references therein). BVDV-1 as disclosed herein may be used in the manufacture of a composition for use in the prevention and/or treatment of BVDV type 1 infections in breeding stocks of cattle, in pregnant cows and in the induction of fetal protection against BVDV type 1 infection is pregnant cows. Surprisingly, a BVDV-2 as disclosed herein may be used in the manufacture of a composition for use in the prevention and/or treatment of BVDV type 1 infections in breeding stocks of cattle. In particular, the invention relates to the use of a BVDV type 2 according to the invention in the manufacture of a composition for use in the prevention and/or treatment of BVDV type 1 infections in pregnant cows. Preferably, the BVDV type 2 according to the invention may be used in the manufacture of a composition for use in the induction of fetal protection against BVDV type 1 infections in pregnant cows. Surprisingly also, a BVDV-1 as disclosed herein may be used in the manufacture of a composition for use in the prevention and/or treatment of BVDV type 2 infections in breeding stocks of cattle. In particular, the invention relates to the use of a BVDV type 1 according to the invention in the manufacture of a composition for use in the prevention and/or treatment of BVDV type 2 infections in pregnant cows. Preferably, the BVDV type 1 according to the invention may be used in the manufacture of a composition for use in the induction of fetal protection against BVDV type 2 infections in pregnant cows. Most preferred is the use of BVDV type 1 and type 2 in combination for the manufacture of a composition for use in the prevention and/or treatment of BVDV type 1 and or type 2 infections in breeding stocks of cattle, in pregnant cows and in the induction of fetal protection against BVDV type 1 and/or type 2 infections is pregnant cows.
Most preferably, the wild-type BVDV according to the invention which is to be mutated as disclosed herein corresponds to amino acid sequence SEQ ID NO:5 (termed XIKE-A) or is a functional variant thereof. Most preferably also, the BVDV according to the invention has a Npro mutation according to the invention and corresponds to amino acid sequence SEQ ID NO:6 (termed XIKE-A-NdN) or is a functional variant thereof. Preferably, such a functional variant is at least 65% homologous to the amino acid sequence disclosed herein. On the amino acid level, homologies are very roughly: BVDV-1/-BVDV-1: 93%; BVDV-1/-BVDV-2: 84%; BVDV-2/-BVDV-2: 98%. Therefore, more preferable, such a functional variant is at least 70%, 71%, 72%, 73%, 74%, 75%, 76%, 77%, 78%, 79%, 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, or 90% homologous to the amino acid sequence disclosed herein. More preferably also, such functional variant is at least 91%, 92%, 93%, 94%, 95%, 96%, 97%, or 98% homologous to the amino acid sequence disclosed herein. Most preferably, such functional variant is at least 99% or 99.9% homologous to the amino acid sequence disclosed herein.
Most preferably also, the BVDV according to the invention has a Ems mutation according to the invention which has a deletion of the codon coding for histidine 349, and corresponds to amino acid sequence SEQ ID NO:7 (termed XIKE-B) or is a functional variant thereof. Most preferably also, the BVDV according to the invention has both a Ems mutation and a Npro mutation according to the invention, wherein the codon coding for histidine 349 of Ems is deleted and also the complete Npro coding region is deleted, except for codons 1 to 4, thus amino acids MELF of Npro remain. The mutant corresponds to amino acid sequence SEQ ID NO:8 (termed XIKE-B-NdN) or is a functional variant thereof. Preferably, such a functional variant is at least 65% homologous to the amino acid sequence disclosed herein. More preferable, such a functional variant is at least 70%, 71%, 72%, 73%, 74%, 75%, 76%, 77%, 78%, 79%, 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, or 90% homologous to the amino acid sequence disclosed herein. More preferably also, such functional variant is at least 91%, 92%, 93%, 94%, 95%, 96%, 97%, or 98% homologous to the amino acid sequence disclosed herein. Most preferably, such functional variant is at least 99% or 99.9% homologous to the amino acid sequence disclosed herein.
Most preferably also, the BVDV according to the invention has a Ems mutation according to the invention which has a substitution of the codon coding for histidine 300 by the codon coding for leucine and corresponds to amino acid sequence SEQ ID NO:9 (termed XIKE-C) or is a functional variant thereof. Most preferably also, the BVDV according to the invention has both a Ems mutation and a Npro mutation according to the invention, wherein the codon coding for histidine 300 is substituted by the codon coding for leucine and also the complete Npro coding region is deleted, except for codons 1 to 4, thus amino acids MELF of Npro remain. The mutant corresponds to amino acid sequence SEQ ID NO:10 (termed XIKE-C NdN) or is a functional variant thereof. Preferably, such a functional variant is at least 65% homologous to the amino acid sequence disclosed herein. More preferable, such a functional variant is at least 70%, 71%, 72%, 73%, 74%, 75%, 76%, 77%, 78%, 79%, 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, or 90% homologous to the amino acid sequence disclosed herein. More preferably also, such functional variant is at least 91%, 92%, 93%, 94%, 95%, 96%, 97%, or 98% homologous to the amino acid sequence disclosed herein. Most preferably, such functional variant is at least 99% or 99.9% homologous to the amino acid sequence disclosed herein.
Another important embodiment of the invention described herein is a composition comprising a pestivirus, in particular a BVDV according to the invention and a solution. The skilled person knows additional components which may be comprised in the composition (see also Remington's Pharmaceutical Sciences, 18th ed. Mack Publ., Easton (1990)). The expert may use known injectable, physiologically acceptable sterile solutions. For preparing a ready-to-use solution for parenteral injection or infusion, aqueous isotonic solutions, such as, e.g., saline or corresponding plasma protein solutions, are readily available. The pharmaceutical compositions may be present as lyophylisates or dry preparations, which can be reconstituted with a known injectable solution directly before use under sterile conditions, e.g., as a kit of parts.
The final preparation of the compositions of the present invention are prepared for, e.g., injection by mixing the pestivirus, preferably BVDV according to the invention with a sterile physiologically acceptable solution, that may be supplemented with known carrier substances or/and additives (e.g., serum albumin, dextrose, sodium bisulfite, EDTA). The solution may be based on a physiologically acceptable solvent, e.g., an aqueous solution between pH 7 and 8. The pH may be stabilized by a pharmaceutically acceptable buffer. The solution may also contain further stabilizing agents like a detergent like Tween 20, serum albumin such as bovine serum albumin (BSA), ascorbic acid, and/or spermidine. The composition may also comprise adjuvants, e.g., aluminum hydroxide, mineral or other oils or ancillary molecules added to the vaccine or generated by the body after the respective induction by such additional components, like but not restricted to interferons, interleukins, or growth factors.
For example, in a composition according to the invention, the pestivirus, in particular BVDV may be solved in:
If the composition is first lyophilized or dehydrated by other methods, then, prior to vaccination, the composition is rehydrated in aqueous (e.g., saline, phosphate buffered saline (PBS)) or non-aqueous solutions (e.g., oil emulsion (mineral oil, or vegetable/metabolizable oil based/single or double emulsion based), aluminum-based, carbomer based adjuvant).
Preferably, the composition according to the invention induces an immunological response in an animal. More preferred, the composition according to the invention is a vaccine. A vaccine as understood herein comprises a pestivirus, in particular BVDV according to the invention and is defined above in the Definitions of Terms Used in the Description section.
Most preferred, the composition according to the invention further comprises a pharmaceutically acceptable carrier or excipient. Several carriers or excipients are disclosed above. The composition may comprise, if aimed at injections or infusion, substances for preparing isotonic solutions, preservatives such as p-hydroxybenzoates, stabilizers such as alkali salts of ethylendiamintetracetic acid, possibly also containing emulsifying and/or dispersing agents.
The composition according to the invention may be applied intradermally, intratracheally, or intravaginally. The composition preferably may be applied intramuscularly or intranasally. In an animal body, it can prove advantageous to apply the pharmaceutical compositions as described above via an intravenous or by direct injection into target tissues. For systemic application, the intravenous, intravascular, intramuscular, intranasal, intraarterial, intraperitoneal, oral, or intrathecal routes are preferred. A more local application can be effected subcutaneously, intradermally, intracutaneously, intracardially, intralobally, intramedullarly, intrapulmonarily, or directly in or near the tissue to be treated (connective-, bone-, muscle-, nerve-, or epithelial tissue). Depending on the desired duration and effectiveness of the treatment, the compositions according to the invention may be administered once or several times, also intermittently, for instance on a daily basis for several days, weeks, or months and in different dosages.
The invention also relates to the use of a pestivirus, in particular BVDV, according to the invention in the manufacture of a vaccine for the prophylaxis and treatment of pestiviral infections, in particular of BVDV infections.
Another important part of the invention is a polynucleotide molecule comprising the nucleic acid coding for a pestivirus, in particular for a BVDV, according to the invention, or a fragment, functional variant, variant based on the degenerative nucleic acid code, fusion molecule, or a chemical derivative thereof. Preferably, the polynucleotide molecule is DNA. Also preferably, the polynucleotide molecule is RNA. In a more preferred embodiment, the polynucleotide molecule also comprises the nucleotide sequence of a functional 5′- and/or 3′-non-translated region of a pestivirus, in particular of BVDV.
There are several nucleotide sequences known in the art, which represents the basis for the production of a polynucleotide molecule coding for a pestivirus attenuated according to the present invention, having at least one mutation in the coding sequence of Npro and at least one in the coding sequence of glycoprotein Ems, wherein the mutations result in an combined inactivation of the RNase activity residing in glycoprotein Ems and in the inactivation of the immunomodulating activity residing in Npro. Examples of nucleic acid sequences of wild-type sequences of several members of pestiviruses are listed below:
Border Disease Virus
The mutations/modifications according to the invention relating to the coding sequence of Npro and Ems are described above more in detail. Having this information, a person skilled in the art is able to realize the manufacture of any polynucleotide/polynucleic acid coding for a pestivirus according to the present invention. Furthermore, this person is able to manufacture an attenuated pestivirus according to the invention. Molecular method for introducing a mutation into a polynucleotide sequence, cloning, and amplification of the mutated polynucleotide are for example provided by Sambrook et al., 1989 or Ausubel et al., 1994.
Most preferably, the wild-type BVDV according to the invention which is to be mutated as disclosed herein is encoded by the nucleic acid sequence SEQ ID NO: 1 (termed XIKE-A) or a functional variant thereof. Most preferably also, the BVDV according to the invention has a Npro mutation according to the invention and is encoded by nucleic acid sequence SEQ ID NO:2 (termed XIKE-A-NdN) or a functional variant thereof. Preferably, such a functional variant is at least 65% homologous to the nucleic acid sequence disclosed herein. On the nucleic acid level, homologies are very roughly: BVDV-1/-BVDV-1: 80%; BVDV-1/-BVDV-2: 70%; BVDV-2/-BVDV-2: 96%. Therefore, more preferable, such a functional variant is at least 70%, 71%, 72%, 73%, 74%, 75%, 76%, 77%, 78%, 79%, 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, or 90% homologous to the nucleic acid sequence disclosed herein. More preferably also, such functional variant is at least 91%, 92%, 93%, 94%, 95%, 96%, 97%, or 98% homologous to the nucleic acid sequence disclosed herein. Most preferably, such functional variant is at least 99% or 99.9% homologous to the nucleic acid sequence disclosed herein.
Most preferably also, the BVDV according to the invention has a Ems mutation according to the invention which has a deletion of codon H349 and is encoded by nucleic acid sequence SEQ ID NO:7 (termed XIKE-B) or by a functional variant thereof. Most preferably also, the BVDV according to the invention has both a Ems mutation and a Npro mutation according to the invention, wherein the codon coding for histidine 349 of Ems is deleted and also the complete Npro coding region is deleted, except for codons 1 to 4, thus amino acids MELF of Npro remain. The mutant is encoded by nucleic acid sequence SEQ ID NO:8 (termed XIKE-B-NdN) or by a functional variant thereof. Preferably, such a functional variant is at least 65% homologous to the nucleic acid sequence disclosed herein. More preferable, such a functional variant is at least 70%, 71%, 72%, 73%, 74%, 75%, 76%, 77%, 78%, 79%, 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, or 90% homologous to the nucleic acid sequence disclosed herein. More preferably also, such functional variant is at least 91%, 92%, 93%, 94%, 95%, 96%, 97%, or 98% homologous to the nucleic acid sequence disclosed herein. Most preferably, such functional variant is at least 99% or 99.9% homologous to the nucleic acid sequence disclosed herein.
Most preferably also, the BVDV according to the invention has a Ems mutation according to the invention which is a substitution of codon “H300” by a leucine codon, and is encoded by nucleic acid sequence SEQ ID NO:11 (termed XIKE-C) or a functional variant thereof. Most preferably also, the BVDV according to the invention has both a Ems mutation and a Npro mutation according to the invention, wherein the codon coding for histidine 300 is substituted by the codon coding for leucine and also the complete Npro coding region is deleted, except for codons 1 to 4, thus amino acids MELF of Npro remain. The mutant is encoded by nucleic acid sequence SEQ ID NO:12 (termed XIKE-C-NdN) or by a functional variant thereof. Preferably, such a functional variant is at least 65% homologous to the nucleic acid sequence disclosed herein. More preferable, such a functional variant is at least 70%, 71%, 72%, 73%, 74%, 75%, 76%, 77%, 78%, 79%, 80%, 81%, 82%, 83%, 84%, 85%, 86%, 87%, 88%, 89%, or 90% homologous to the nucleic acid sequence disclosed herein. More preferably also, such functional variant is at least 91%, 92%, 93%, 94%, 95%, 96%, 97%, or 98% homologous to the nucleic acid sequence disclosed herein. Most preferably, such functional variant is at least 99% or 99.9% homologous to the nucleic acid sequence disclosed herein.
Another important aspect of the invention is a method for attenuating a pestivirus, characterized in that at least one mutation in the coding sequence for glycoprotein Ems and at least another mutation in the coding sequence for Npro is generated in a pestivirus genome. According to a preferred embodiment, the pestivirus is BVDV.
According to a more preferred embodiment, the method comprises the steps:
- a) reverse transcription of a wild-type pestivirus nucleotide sequence into a cDNA;
- b) cloning the cDNA;
- c) introducing mutations selected from the group of deletions, insertion mutations, and/or substitution mutations into the cDNA, wherein the mutations are located in the coding sequence encoding glycoprotein Ems and the protease Npro; and
- d) incorporating the cDNA into a plasmid or into a DNA virus capable of directing the transcription of pestivirus cDNA into RNA in vitro or upon infection of suitable cells.
Regarding the method for attenuating a BVDV according to the invention, the preferred methods comprises the steps:
- a) reverse transcription of a wild-type BVDV nucleotide sequence into a cDNA;
- b) cloning the cDNA;
- c) introducing mutations selected from the group of deletions, insertion mutations, and/or substitution mutations into the cDNA, wherein the mutations are located in the coding sequence encoding glycoprotein Ems and the protease Npro ; and
- d) incorporating the cDNA into a plasmid or into a DNA virus capable of directing the transcription of pestivirus cDNA into RNA in vitro or upon infection of suitable cells.
Yet another important embodiment of the invention is a method of treatment of disease caused by a pestivirus, wherein a pestivirus according to the invention or a composition according to the invention, wherein the pestivirus or the composition is administered to an animal in need thereof at a suitable doses as known to the skilled person and the reduction of symptoms of the pestivirus infection.
Yet another important embodiment of the invention is a method of treatment of disease caused by BVDV, wherein a BVDV according to the invention or a composition according to the invention, wherein the BVDV or the composition is administered to an animal in need thereof at a suitable doses as known to the skilled person and the reduction of symptoms of BVDV infection such as viremia and leukopenia and/or pyrexia and/or diarrhea is monitored.
EXAMPLESThe following examples serve to further illustrate the present invention; but the same should not be construed as limiting the scope of the invention disclosed herein.
Example 1 BVDV XIKE-B Fetopathogenicity Assessment in Pregnant HeifersBVDV XIKE-B, an RNase negative mutant of the highly pathogenic BVDV type 2 isolate NewYork93/C was recovered from the infectious cDNA clone pKANE40B and showed wild-type-like (wt-like) growth characteristics in tissue culture. In animal experiments the mutant virus was found to be considerably attenuated so that it represented a promising candidate for development of a live attenuated vaccine virus (Meyer et al., 2002). To test whether this attenuated virus is still able to cross the placenta and infect the fetus, pregnant heifers were infected with XIKE-B. As a control, wild-type BVDV recovered from cDNA clone pKANE40A was used. The respective virus named XIKE-A expresses an active Emn RNase in the infected cell. The study aimed to assess the safety of XIKE-A and XIKE-B in pregnant animals.
Experimental DesignTen pregnant heifers were selected from a BVDV negative herd. The following groups of 5 heifers were included in the trial:
Heifers were moved to the experimental facilities 8 days before inoculations. Pregnancy status was confirmed after transport into the experimental facility. Heifers were between days 60 and 90 of gestation on the day of inoculation. Inoculation took place for all animals at one point of time.
Heifers were monitored for the presence of clinical signs of BVDV infection including abortions during the observation period. Blood samples were collected from the animals for serology, antigen detection, and white blood cells were counted. The experiment was terminated 9 weeks after infection. Non-aborted cows were slaughtered, the uterus examined, and collected. Fetal organ samples were collected during routine necropsy and examined for BVDV infection.
The presence of fetal infection was the main evaluation parameter, composed from the number of BVDV-related cow mortality, the number of BVDV-related abortions, and the number of BVDV positive fetuses at termination. In addition to the main parameter, clinical signs characteristic for BVDV infection, viremia, and white blood cell counts in cows and rectal temperature after challenge were evaluated.
AnimalsHeifers were purchased from a farm free of BVDV. Only animals which met the following inclusion criteria were used.
Inclusion Criteria
-
- Free of BVD antibodies; each individual was tested in the serum antibody test prior to transport and at the initiation of the study (at the animal test facility).
- Free of BVDV; plasma and/or buffy-coat preparation from each individual was tested by a suitable test.
- Clinically healthy at the initiation of the study judged upon physical examination. The health examination of the animals was accomplished in accordance with the current, generally accepted veterinary practice.
- Pregnancy confirmed by physical examination before inoculation. Pregnancy was between 60-90 days at the time of inoculation, proven by insemination records.
Pregnancy was confirmed immediately before inoculation.
Inoculation of HeifersThe inoculation is Day 0 of the experiment.
In each nostril, 3 mL of the test material was administered intranasally by syringe without needle. Each time a new sterile syringe was taken. Administration was performed during the aspiration phase in order to minimize loss of fluid via expiration of material.
Post-Inoculation Observations Collection and Examination of Blood SamplesBlood was collected following standard, aseptic procedures (disinfecting the bleeding site). A new sterile syringe and needle was used for each animal.
Blood Collection to Prepare SerumAt least 10 mL blood was collected from the heifers immediately before inoculation, then weekly after infection and at the termination of the study. Serum was stored at −20° C. until required.
Blood Collection for Leukocyte Counts and Buffy Coat PreparationsFor leukocyte counting, 3 mL blood was transferred immediately after collection to suitable sterile vessels (Venoject, Terumo Europe N.V., Leuven, Belgium), pre-filled with 0.06 mL EDTA (0.235 MOL/L).
For buffy coat preparations, at least 15 mL blood was transferred immediately after collection to suitable sterile vessels, pre-filled with 0.1 mL Heparin solution (Na-heparin for inj., 5000 IU/mL lot A7B163A, exp. date: 11/2000: Gedeon Richter R T, Budapest, Hungary) yielding at least 20 IU Heparin per mL blood in the blood sample. The content was carefully mixed thereafter.
For preparation of buffy coats and leukocyte counting, blood was collected from the heifers on every day, between Day 0 and Day 14 after infection; and on every second day, between Day 15 and Day 40, or until all animals were negative for virus isolation for three consecutive sampling time points.
Preparation of SerumBlood was allowed to clot at room temperature, and separated by centrifugation. Each serum sample was divided into two aliquots of at least 2 mL each. One set of aliquots was assayed for BVDV specific antibodies by ELISA. The rest of the sera was frozen and stored at −20° C. until required.
Leukocyte CountsLeukocyte counts was determined with a coulter-counter semi-automated electronic device (Diatron Minicell-16, Messtechnik GmbH, Wien, Austria) with a claimed accuracy of 0.1×109/1,100/μL. The instrument was used (calibration and leukocyte-counts) according to the manufacturer's recommendations.
Preparation of Buffy CoatsHeparin blood samples was transported to the laboratory as soon as possible. Buffy coat preparation procedure, following a standard laboratory procedure, was performed under aseptic conditions (sterile pipettes, handling, clean bench, etc.).
The obtained buffy coats were re-suspended in a small volume (2 mL) of RPMI 1640 and frozen at −70° C. in two aliquots of 0.5 mL. The residual 1 mL buffy coats was immediately used for determination of blood cell associated BVDV by co-cultivation in a permissive cell culture.
BVD Serum Antibody ELISA-TestEach serum sample was tested for the presence of BVDV-antibodies using a suitable and validated ELISA test (Svanovir™ BVDV antibody test Cat#10-2200-10). Test was validated and performed according to the manufacturer's recommendations. Positive samples were diluted according to the log2 scale to determine BVDV antibody titers.
BVD Antigen Assay(s)Each buffy coat sample was assayed for the presence of BVDV by co-cultivation of the freshly prepared buffy-coats with susceptible cells or a cell-line. No freezing was allowed before co-cultivation. Plasma was collected and provided to Man-Gene from each sample.
Clinical Observations Observation of HeifersAnimals were examined daily from Day 0-42 post-inoculation for the presence of clinical symptoms by a sufficiently trained veterinarian.
All clinical signs were recorded and described by its nature, consistence/touch, severity (mild, medium or severe) location, size of the area affected, and they will be scored according to agreed and standard definitions. Special attention was paid to respiratory signs (respiration, its rate; nasal or ocular discharge; conjunctivitis, sneezing, coughing, etc.) and diarrhea.
Rectal TemperaturesRectal temperatures were measured daily in each heifer, at the same hour of the day (preferably in the morning) from 5 days prior to the inoculation till 21 days post-infection. Daily measurement of rectal temperature was continued until each animal had rectal temperatures below or equal to 39° C. for at least 3 consecutive days.
Detection of Interrupted PregnancyPregnancy was confirmed and suspicion for abortion or resorption of the fetus was established by rectal examination. A trained veterinarian examined all animals at inoculation, 1 and 2 months post-inoculation. The examination was carried out according to the generally accepted veterinary practice. Heifers were examined daily for any sign of abortion until termination of the study (8-12 weeks post-challenge).
Termination of the StudyThe study was terminated by slaughtering the heifers and extracting the fetuses. Fetuses and fetal material were transferred into closed transport containers marked with the number of the cow and the date/time. Containers were transported to a selected necropsy room. Necropsy of the heifers was not required. Necropsy was performed on fetuses, findings recorded, and a panel of samples collected as described below.
Post-Mortem ExaminationA detailed necropsy of the experimental animals was done in each case of death. Post-mortem examinations were carried out by an experienced veterinary surgeon and the data were recorded on appropriate data sheets. Further laboratory tests were performed according to the clinical signs and lesions observed. If the diagnosis of the necropsy referred to a disease caused by microbial agent the diagnosis was verified by an appropriate test, specific for the agent. Each tissue sample was collected in at least 2 separate, labeled containers and snap-frozen in liquid nitrogen. Samples were stored at −70° C. until required.
Aborted Fetuses and Study TerminationAt least the following tissue samples were collected from the fetuses: exudate from the peritoneal cavity or thorax, if present; mesenteric lymph nodes; spleen; thymus; cerebellum; kidney; bone marrow from the sternum; and sample from the placenta, if available.
Dead or Sacrificed HeifersAt least the following tissue samples were collected: blood for buffy coat, if available; blood for serum, if available; Peyer's patches; mesenteric lymph nodes; spleen; kidney; uterus, including a sample from the placenta, if available.
Storage and Transport of Samples
Samples were sent for laboratory analysis as required by the sponsor. The choice of samples and the timing of transport were agreed with the study monitor or the project manager. As a matter of general principle, samples coming from aborted material or from new-born calves were investigated as soon as possible.
Results MortalityHeifer No. 626 (Group 1) died on Day 13 PI (post-inoculation). The following table summarizes the observed clinical signs and lesions revealed during necropsy:
These clinical and gross-pathological findings are consistent with BVDV induced lesions, therefore it may be concluded that the reason of death was the BVDV infection.
Abortions After InfectionOne heifer had clinical abortion in each group. Heifer No. 615 (Group 1) aborted on Day 38 PI, Heifer No. 469 (Group 2) aborted on Day 39 PI. Both fetuses showed the signs of autolysis, and they were estimated to die at least 3-7 days before the abortion (around 32-35 DPI). In Group 1, no fetus was found in Heifer No. 526 during the slaughter examination at termination. Gross-pathology of the uterus revealed the following: the right uterine horn was slightly enlarged, and the remains of placenta with progressed autolysis was retained in the lumen. The findings on the uterus of Heifer No. 526 is consistent with a “silent” abortion, most likely due to the BVD infection.
Clinical Observation of HeifersA summary of the clinical observation data and duration of clinical signs in the groups are presented below.
Clinical Signs and the Days Post-Inoculation (DPI) When They Were ObservedGroup 1 (XIKE-A)
Group 2 (XIKE-B)
All Group 1 animals infected with XIKE-A exhibited a broad spectrum of clinical signs. Respiratory signs appeared first accompanied by loss of appetite, and a few days later heifers developed diarrhea with the exception of Heifer No. 526. One heifer died and another one aborted (see before) after infection. All these signs are consistent with the symptoms expected after infection with a virulent BVDV strain.
All Group 2 animals infected with XIKE-B were free of clinical signs. At the same time, one heifer had abortion during the observation period.
Rectal TemperaturesNo abnormal temperature changes were detected before the infection of the animals. In Group 2, all temperature values remained within the physiological range from Day 0 to Day 21 after infection. All Group 1 animals showed elevated rectal temperature after infection that were detected between Days 7-11 PI.
Findings at Study TerminationAt study termination, fetuses were examined at slaughter. No fetus was recovered from Heifer No. 526 (see section 10.2 “Abortions after Infection”). The following findings were observed at the necropsy of the fetuses:
The findings suggest that 2 Group 1 animals (Heifers No. 598 and No. 618) and one Group 2 animal (Heifer No. 619) died several weeks before extraction, and so they can be considered abortions.
Abortions Modified by Post-Mortem FindingsAfter the post-mortem examination it was not clear why some of the heifers had not had abortions. Dead fetuses should be considered as abortions, therefore the clinical picture was modified after the termination of the study as follows:
Group 1
Group 2
WBC counting was interrupted on Day 26 PI, as all animals became negative for virus isolation for this time point. 0 DPI values were considered as individual baseline for comparison. In Group 2, the leukocyte counts never went to 40% or more below the baseline value until the end of the observation period (26 DPI). In Group 1, one animal (Heifer No. 598) had WBC count below the 40% baseline for one day.
SerologyNone of the selected animals had BVDV specific antibody in their sera before the infection. After infection, all surviving Group 1 heifers developed BVDV specific antibodies detected from 3 weeks PI and lasted until the end of the observation period in all study animals. In Group 2, 4 out of the 5 heifers had BVDV specific antibodies detected from 4 weeks PI. Measurable antibody response lasted only in 3 animals until the end of the observation period. Titers were lower in Group 2 than in Group 1.
Virus Detection by Co-Cultivation Buffy CoatsBVDV was detected in both groups. The duration of virus detection is summarized below. All samples were co-cultivated immediately after collection, i.e., without freezing.
The presence of BVD virus in the dead heifer and the fetuses is summarized below:
Heifer:
Fetuses:
Samples were co-cultivated immediately after collection (i.e., without freezing), except “#” marked ones, from which only frozen samples were available.
Summary of BVD Related Clinical and Laboratory DataGroup 1
Group 2
The study aimed to assess the safety of XIKE-A and XIKE-B in pregnant animals. Ten pregnant heifers were selected from a BVDV negative herd. Two groups of 5 heifers were included in the trial: one was inoculated with XIKE-A the other with XIKE-B virus strain. Heifers were between days 60 and 90 of gestation on the day of inoculation. Heifers were monitored for the presence of clinical signs of BVDV infection including abortions during the observation period. Blood samples were collected from the animals for serology, antigen detection and white blood cells were counted. The experiment was terminated 9 weeks after infection. Non-aborted cows were slaughtered and the uterus examined and collected. Fetal organ samples were collected during routine necropsy and examined for BVDV infection.
The presence of fetal infection was the main evaluation parameter, composed from the number of BVDV-related cow mortality, the number of BVDV-related abortions and the number of BVD positive fetuses at termination. In addition to the main parameter, clinical signs characteristic for BVDV infection, viremia, and white blood cell count in cows and rectal temperature after challenge were evaluated. The XIKE-B virus proved to be less pathogenic than XIKE-A, nevertheless BVD-related abortion and infection of the fetus was observed in the XIKE-B group, too. Therefore it can be concluded that the inactivation of the Ems RNase does not prevent fetal infection.
Example 2 BVDV XIKE-A-NdN Fetopathogenicity Assessment in Pregnant HeifersThe Npro gene has been shown to be nonessential for growth of CSFV in tissue culture (Tratschin et al., 1998). Even though a proof for BVDV attenuation in consequence of Npro deletion is still missing, a role of this protein in the interaction between virus and host seemed to be possible and was actually indicated by recent experiments for CSFV (Mayer et al., 2004; Rüggli et al., 2003). We therefore investigated whether the deletion of the major part of the Npro coding sequence leads to a virus that no longer infects the fetus in pregnant heifers. The Npro gene except for the 5′ terminal 4 codons was deleted from the full length cDNA clone pKANE40A according to standard procedures. The resulting mutant full length clone was used as template for in vitro transcription and the resulting cRNA was transfected into MDBK cells as described (Meyer et al., 2002). The recovered virus was amplified in tissue culture and then used in the animal experiment described below. BVDV XIKE-B served as a control since it was shown before that it is able to cross the placenta (Example 1).
Objective(s)/Purpose of the StudyThe study aims to assess the safety of a live attenuated BVDV with a genomic deletion of most of the Npro coding region in pregnant animals.
Materials and Methods applied are as described in Example 1
Study DesignEight pregnant heifers were assigned at random to two groups. They were treated and observed according to the following schedule:
All heifers were healthy and pregnant at study start. All animals proved to be free of BVDV and BVDV antibodies before the initiation of the study.
Preparation and Control of the Virus used for the Infection
Samples were collected throughout the dilution steps and assayed on the day of preparation, i.e., without freezing by co-cultivation on suitable tissue culture. The results of virus titration are shown in the following table.
The table below gives a summary about the animals that had clinical signs during the observation period.
Clinical Signs and the Days Post-Inoculation (DPI) When They Were Observed
Only mild and transient clinical signs were observed in some of the animals in each group. In Group 1, one out of the 5 heifers had loss of appetite on day 8 PI. In Group 2, two out of the 3 animals had clinical signs. Both heifers experienced coughing around day 21 PI that was accompanied with loss of appetite in one of the animals.
Rectal TemperaturesNo abnormal temperature changes were detected before the inoculation of the animals. The few cases of elevated temperatures measured after the inoculation are summarized in the table below.
One animal had slightly elevated temperature in each group, and also one animal had fever in each group. Fever was detected on day 8 or 9 PI. Temperature values always returned to normal value on the following day.
Leukocyte CountsSome leukopenia was observed in all groups between PI days 3-8. The number of animals with at least 40% reduction in white blood cell count was the following:
In compliance with the study protocol, all heifers were free of BVDV antibodies before vaccination. In Group 1 (inoculated with XIKE-A NdN) and Group 2 (inoculated with XIKE-B), complete seroconversion was detected only at study termination (2 months after inoculation).
BVD Virus Isolation from Buffy Coats
No viremia was detected
BVD Virus Isolation from Fetal Tissue Samples
The Npro deletion resulted in a considerable attenuation of the BVDV in comparison to the parental virus XIKE-A that was shown to be highly pathogenic (Meyer et al., 2002). However, the Npro deletion alone is not preventing transmission of a NY93-based virus recombinant to the fetus after inoculation of pregnant cows.
Example 3 BVDV XIKE-B-NdN Fetopathogenicity Assessment in Pregnant HeifersTo be able to test the potential of a combination of RNase inactivation and Npro deletion with regard to BVDV attenuation and fetal transmission, different BVDV-2 mutants with deletions within the Npro coding region were established based on the infectious cDNA clone pKANE40B, the RNase negative mutant of pKANE40A with a deletion of codon 349. The recovered viruses were analyzed with regard to presence of the desired mutations, the absence of second site mutations in the regions flanking the introduced changes, and their growth characteristics in tissue culture. XIKE-B-NdN (V-pK88C), a variant containing a deletion of the complete Npro coding region except for codons 1 to 4 in addition to the RNase inactivating deletion of codon 349 was chosen for an animal experiment since it combined the desired mutations with acceptable growth characteristics. The aim of the study was to assess the safety of a live attenuated BVDV isolate in pregnant animals.
Five BVDV-negative, pregnant heifers were inoculated intranasally with an infective dose of 105 TCID50/animal XIKE-B-NdN (back titration data are depicted in Table 3.1). Clinical data were recorded daily. Blood samples were collected for white blood cell counting, for buffy-coat preparation and serology. After termination of the study, fetal tissues were collected for virus isolation.
Materials and MethodsAs detailed for Example 1.
ResultsNo clinical data were observed (data not shown). Leukocyte counts remained virtually unchanged except for a significant decrease by approximately 40% below the baseline value (day 0) in heifer No. 1015 on a single day (day 6 PI) (data not shown).
Analysis of Buffy Coat PreparationsApproximately 106 leukocytes were cultured in duplicates with MDBK-cells in 24-well tissue culture plates for 5 days. Samples were freeze-thawed twice. 100 μL aliquots of thawed samples were inoculated onto freshly seeded 24-well tissue culture plates and tested for virus by indirect immunofluorescence staining (mAb Code 4, directed against a conserved epitope in nonstructural protein NS3). No BVDV could be isolated from the buffy coat preparations of animals #921, 1013, 1015, 1055 and 1075 (Table 3.2) whereas positive controls clearly showed the correct conduction of the test.
Post-Mortem Examination of Fetal TissuesAfter termination of the study the following fetal tissues were collected for virus isolation: spleen, kidney, thymus, sternum, cerebellum, placenta, intestine, and abdominal fluid. Briefly, tissue suspensions were made in a mortar using sterile sea sand and ice-cold PBS without Ca2+ and Mg2+. Mortars were rinsed with 1 mL ice-cold PBS without Ca2+ and Mg2+ and suspensions were centrifuged for 10 minutes at 2000×g (4° C.). The supernatant was first passed through a disposable 0.45 μm filter holder, followed by a second filter passage (0.2 μm pore size). Virus isolation was carried out in duplicates (400 μl, of fetal tissue suspension or 100 μL of fetal abdominal fluid) on a monolayer of MDBK-cells in a 24 wells tissue culture plate (37° C., 7% CO2). Tissue samples were controlled daily for cytopathic effects or bacterial contamination, and after an incubation time of 5 days plates were frozen and thawed twice. 100 μL of samples were passaged to freshly seeded MDBK-cells. Virus was detected by indirect immunofluorescence staining (mAb Code 4). No BVDV could be detected in the tissue samples or fetal abdominal fluid (Table 3.3).
Serological FindingsSerum neutralization titers were determined before inoculation, 1 month post-inoculation and at termination of the study. Sera from all animals were tested in triplicates for neutralizing antibodies against NY93/C, and the endpoint dilution was read by indirect immunofluorescence staining. Results were expressed as the endpoint dilution, which neutralized approximately 100 TCID50 and calculated by the method of Kaerber. No definite data could be obtained for day 0, and 1 and 2 weeks post-infection as the sera were toxic for MBDK-cells in dilutions up to 1:16 and no neutralization could be detected at higher dilutions. Starting with the third week post-vaccination all animals developed neutralizing antibodies against the homologous BVDV-2 virus NY93/C lasting till the end of the experiment (Table 3.4 and
The data obtained during the animal study clearly show that BVDV XIKE-B-NdN represents a highly attenuated virus. In contrast to wild-type virus or the single mutants XIKE-B or XIKE-A-NdN that show fetal transmission in pregnant heifers at high rates, the double mutant did not cross the placenta. BVDV XIKE-B-NdN as well as similar double mutants are extremely suitable for the use in a live attenuated vaccine.
Two possible problems have to be faced with regard to vaccination with attenuated virus mutants BVDV XIKE-B or BVDV XIKE-B-NdN. First, there is a general problem concerning crossprotection between BVDV-1 and BVDV-2. At least vaccination with inactivated BVDV-1 vaccines did not prevent the transmission of BVDV-2 to the fetus in pregnant animals. Since protection against fetal infection represents the major aim of anti-BVDV vaccination, such vaccines cannot be regarded to induce a protective immunity on a broad range. The question therefore was, whether vaccination with live attenuated BVDV-2 can prevent virus transmission to the fetus. Second, the reduced growth rates of BVDV XIKE-B-NdN might result in only a low level of protection not able to prevent transplacental infection of the fetus in pregnant heifers. To address these problems, an animal study was started. The animals (2 groups of 10 animals each) were vaccinated either with BVDV XIKE-B or XIKE-B-NdN (intended dosage: 1 mL of supernatant with 105 TCID50 of virus; backtitration is shown in Table 3.5). None of the animals showed significant clinical signs after the vaccination except for one animal of the nonvaccinated control group with mild coughing for one day. Rectal temperature values were below 39° C. except for one animal of the nonvaccinated control group that had 39.1° C. for one day. Buffy coat samples prepared after vaccination were analyzed for the presence of virus as described above. The experiments showed that only 5 of the 20 animals contained virus in the blood for 1 or 2 days at 4 to 8 days post-infection (Table 3.6).
Four weeks after vaccination, insemination of the animals was carried out. Challenge infections were performed 60 to 90 days later using either a BVDV-1 strain (BVDV KE-9, heterologous challenge, animals vaccinated with XIKE-B) or a heterologous BVDV-2 strain (BVDV KE-13, homologous challenge, animals vaccinated with XIKE-B-NdN) (intended dosage: 105 TCID50 in 6 mL; backtitration is shown in Table 3.7). From each group of vaccinated animals 5 pregnant heifers were randomly selected for the challenge infection. Animals vaccinated with BVDV XIKE-B were challenged with the BVDV-1 strain KE-9, whereas heifers vaccinated with BVDV XIKE-B/NdN were challenged with BVDV-2 KE-13. In addition, two nonvaccinated control animals were infected with each of the challenge viruses.
The vaccinated animals did not show viremia or clinical symptoms upon challenge infection. The challenge was successful as all non-vaccinated controls were BVDV positive (Table 3.8). Only mild signs of disease were observed in the control groups. The white blood cell counts were nearly normal (not shown).
Serum neutralization titers were determined before inoculation, 1 month post-inoculation, before challenge, 1 month after challenge and at termination of the study. Sera from all animals were tested in triplicates for neutralizing antibodies against KE9 and NY93/C (1456 Nase), and the endpoint dilution was read by indirect immunofluorescence staining. Results were expressed as the endpoint dilution, which neutralized approximately 100 TCID50 and calculated by the method of Kaerber. At some of the higher antibody titers, the used endpoint dilution was not high enough. Against KE9, only animals vaccinated with XIKE-B developed low antibody titers starting about week 4. At challenge, all animals had antibody titers, which increased considerably starting around week 4 post-challenge. XIKE-B vaccinated animals had higher antibody titers then those vaccinated with XIKE-B-NdN vaccinated. All animals developed about the same neutralization titer against NY93/C four weeks post-vaccination, with marginally lower titers in XIKE-B-NdN vaccinated animals. After challenge all animals had high antibody titers.
Analysis of tissue samples obtained after termination of the study from the fetuses revealed that the material obtained from the vaccinated animals gave negative results whereas transmission had occurred in all 4 control animals (Table 3.9). Thus, it is clear that the established BVDV-2 mutants are well suited as efficient cross protective vaccine viruses.
The challenge was successful as all non-vaccinated controls were BVDV viremic and fetuses of all non-vaccinated controls were BVDV positive.
Both isolates gave full protection under the present test and assay conditions. Isolate XIKE-B, with the single genetic marker was shown to cross-protect against type 1 BVDV challenge in terms of BVD viremia and transmission to the fetus after challenge. Isolate XIKE-B-NdN with the double genetic marker was able to fully protect against a heterologue type 2 BVDV challenge strain in terms of BVD viremia and transmission to the fetus after challenge.
Isolate XIKE-B (type 2 isolate) was shown to cross-protect against type 1 BVDV challenge in terms of BVD viremia and transmission to the fetus after challenge under the present test and assay conditions (n=4).
Isolate XIKE-B-NdN (type 2 isolate) fully protected against a heterologues type 2 BVDV challenge strain in terms of BVD viremia and transmission to the fetus after challenge under the present test and assay conditions (n=5).
Example 4 Establishment of Npro MutantsFurther analyses of BVDV-2 mutants with Npro deletions. Different mutants with deletions in the Npro-coding region of the genome were established. Initially, only true deletions or a deletion accompanied by a point mutation were introduced.
[Npro]1−[C-term]; A
[Npro]3−[C-term]; B
[Npro]4−[C-term]; C
[Npro]6−[C-term]; D
[Npro]4−[C-term*] E
In the formulas, [Npro]x represents the number of residues of the aminoterminus of Npro that are left in the mutated polyprotein amino acids, [C-term] is the complete polyprotein except for Npro (starting with the C protein and ending with NS5B), and [C-term*] is the same as [C-term] but with a mutation at position 2 of the C protein (N instead of D).
The growth rates of the recovered viruses were considerably lower than those of wild-type XIKE-A or the RNase negative mutant XIKE-B. There are two possible explanations for this finding: (i) dependent on the virus strain, sequences of variable length of the Npro-coding region are necessary for efficient translation initiation (Myers et al., 2001; Tautz et al., 1999), and (ii) the fusion of additional sequences to the aminoterminus of the capsid protein interferes with capsid protein function.
To obtain better growing Npro deletion mutants, a second set of mutants was generated with either a bovine ubiquitin gene or a fragment of the bovine LC3-coding sequence replacing the major part of the Npro gene. These constructs allow efficient translation and generate a capsid protein with the correct amino terminus.
[Npro]22−[PS]−[C-term]
wherein PS is ubiquitin or LC3 and C-term is the complete polyprotein except for Npro (starting with the C protein and ending with NS5B).
The growth rates of these mutants were more similar to what was determined for XIKE-A. It even seemed that the two RNase positive viruses according to the formula [Npro]22−[PS]−[C-term] named V-pK87F and V-pK87G showed no significant growth retardation at all, whereas the RNase negative counterpart V-pK88G once again was somewhat hampered in propagation but to a lesser extend than the formerly described mutants.
Further examples of Npro deletion mutants may be:
MESDEGSK . . .
MELFSSDEGSK . . .
MELFSNESDEGSK . . .
MELFSNELSDEGSK . . .
MELFSNELLSDEGSK . . .
MELFSNELLYSDEGSK . . .
MELFSNELLYKSDEGSK . . .
MELFSNELLYKTSDEGSK . . .
MELFSNELLYKT represents the aminoterminal sequence of Npro of the BVDV isolate NewYork93/C.
It may also be possible to use variants of this sequence with one or several mutations. Especially the naturally occurring variations as found in other pestiviruses can be expected to be functional. Therefore, the complete list of the tested or proposed variants with the different parts of the aminoterminal end of Npro can be enlarged by equivalent sets with amino acid exchanges. Below, typical examples of the respective sequences are given for several pestiviruses but the possible variations are not limited to these examples.
BVDV NewYork93/C: MELFSNELLYKT BVDV CP13: MELISNELLYKT BVDV SD1: MELITNELLYKT— CSFV Brescia: MELNHFELLYKT BDV X818: MELNKFELLYKTThus, these variants for example may include: MELI−[PS]0−[C-term];
MELIS−[PS]0−[C-term]; MELISN−[PS]0−[C-term]; MELISNE−[PS]0−[C-term]; MELISNEL−[PS]0−[C-term]; MELISNELL−[PS]0−[C-term]; MELISNELLY−[PS]0−[C-term]; MELISNELLYK−[PS]0−[C-term]; MELISNELLYKT−[PS]0−[C-term]; MELIT−[PS]0−[C-term]; MELITN−[PS]0−[C-term]; MELITNE−[PS]0−[C-term]; MELITNEL−[PS]0−[C-term]; MELITNELL−[PS]0−[C-term]; MELITNELLY−[PS]0−[C-term]; MELITNELLYK−[PS]0−[C-term]; MELITNELLYKT−[PS]0−[C-term];These formulas may also have [PS]1, i.e., PS may also be one of the PS as described herein. Sequences belonging to the Npro protein are in italics. Amino acid exchanges with regard to the sequence of BVDV NewYork93/C are in bold.
Further examples can be found, e.g., by using the GenBank accession numbers given in Becher et al., 2003, Virology 311, 96-104) or by standard sequence data searches.
A further possibility could be the use of a processing signal (PS) inserted between the (residual) sequence and the aminoterminus of the capsid protein. The PS leads to a cleavage that generates a functional capsid protein. The configuration of such constructs could be as follows:
[Npro]22−PS−[C-term]
where PS is a processing signal and can either be a target for a protease (e.g., ubiquitin, LC3 as defined herein or a protease or an unstable peptide leading to processing at its own carboxyterminus like e.g., intein (Chong et al. 1998 and references therein) or 3C of picornaviruses, 2A of cardioviruses or aphtoviruses, p15 of rabbit hemorrhagic disease virus, or the corresponding protease of other caliciviruses (Proter, 1993, and references therein; Meyers et al., 2000 and references therein).
When using a PS, a large number of different variants are possible since the PS ensures the generation of the correct amino terminus of the capsid protein C. Thus, when using a PS construct, all kinds of deletions or mutations of the Npro sequence are expected to result in viable mutants as long as the reading frame is not shifted or translation stopped by an in frame stop codon. As an example we established a viable CSFV N′ deletion mutant according to the formula
[Npro]29—PS—[C-term]
Especially interesting could be Npro mutations blocking the proteolytic activity of the protein. Rümenapf et al., 1998, have published the identification of the active site residues of the protease for CSFV Alfort Tübingen. The respective amino acids (glutamic acid at position 22, histidine at position 49 and cysteine at position 69) are conserved for other pestiviruses. Thus, exchanges of any amino acid expect for serine or threonine for the cysteine at position 69 will result in destruction of the protease activity. Similarly, changing the glutamic acid at position 22 will most likely result in inactivation of the protease unless the new amino acid is aspartic acid. Similarly most if not all exchanges at position 49 will lead to an inactive protease).
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Claims
1. An attenuated classical swine fever virus (CSFV) having at least one mutation in the coding sequence for glycoprotein Ems and at least another mutation in the coding sequence for Npro.
2. The classical swine fever virus according to claim 1, wherein the mutation in the coding sequence for glycoprotein Ems leads to inactivation of RNase activity residing in Ems and/or the mutation in the coding sequence for Npro leads to inactivation of the Npro.
3. The classical swine fever virus according to claim 1, wherein the mutations are selected from the group of deletions, insertion mutations, and substitution mutations.
4. The classical swine fever virus according to claim 2, wherein the mutations are selected from the group of deletions, insertion mutations, and substitution mutations.
5. The classical swine fever virus according to claim 1, wherein the mutation(s) are deletions.
6. The classical swine fever virus according to claim 2, wherein the mutation(s) are deletions.
7. The classical swine fever virus according to claim 1, wherein the mutation(s) in the coding sequence for glycoprotein Ems are located in the encoding nucleotide sequence corresponding to amino acids at position 295 to 307 and/or position 338 to 357.
8. The classical swine fever virus according to claim 1, wherein the mutation in the coding sequence for glycoprotein Ems is a deletion or substitution of the histidine at position 346.
9. The classical swine fever virus according to claim 1, wherein the mutation(s) in the coding sequence for glycoprotein Ems are located in the nucleotide sequence coding for the conserved Ems sequence SLHGIWPEKIC (SEQ ID NO: 15) and/or RHEWNKHGWCNW (SEQ ID NO: 16).
10. The classical swine fever virus according to claim 1, wherein the mutation(s) in the coding sequence for glycoprotein Erns are two mutations located in the nucleotide sequence coding for the conserved Ems sequence SLHGIWPEKIC (SEQ ID NO: 15) and/or RHEWNKHGWCNW (SEQ ID NO: 16).
11. The classical swine fever virus according to claim 1, wherein the mutation in the coding sequence for glycoprotein Ems is a single mutation located in the conserved Ems sequence SLHGIWPEKIC (SEQ ID NO: 15) or RHEWNKHGWCNW (SEQ ID NO: 16).
12. The classical swine fever virus according to claim 1, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
- [Npro]x−[PS]y−[C-term]
- wherein:
- [Npro] is the Npro portion of the polyprotein, wherein x is the number of amino acids of the Npro present in the polyprotein;
- [PS] is a processing signal selected from the group consisting of: ubiquitin, LC3, SUMO-1, NEDD8, GATE-16 or GABA(A)RAP), Intein, picornavirus 3C, caridovirus 2A, or p15 of rabbit hemorrhagic disease virus;
- [C-term] is the complete virus polyprotein except for Npro, but including the capsid (C)-protein and any other protein present in the virus polyprotein including the carboxyterminal NSSB;
- y is 0 or 1, where 0 means [PS] is absent and 1 means [PS] is present; and
- x is 0 to 12 amino acids if y is 0, or 0 to 168 amino acids if y is 1.
13. The classical swine fever virus according to claim 12, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
- [Npro]1−[PS]0−[C-term].
14. The classical swine fever virus according to claim 12, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
- [Npro]3−[PS]0−[C-term].
15. The classical swine fever virus according to claim 12, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula: [Npro]3−[PS]0[−C-term] and the mutation in the coding sequence for glycoprotein Ems is a single mutation located in the conserved Ems sequence SLHGIWPEKIC (SEQ ID NO: 15) or RHEWNKHGWCNW (SEQ ID NO: 16).
16. The classical swine fever virus according to claim 12, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
- [Npro]4−[PS]0−[C-term].
17. The classical swine fever virus according to claim 12, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula:
- [Npro]6−[PS]0−[C-term].
18. The classical swine fever virus according to claim 12, wherein the mutation(s) in the coding sequence for Npro lead to an encoded polyprotein as characterized by the following formula: wherein [C-term]* is [C-term] wherein in the C-protein the amino acid at position 2 is changed from D to N.
- [Npro]4−[PS]0−[C-term],
19. The classical swine fever virus according to claim 12, wherein the mutation(s) in the coding sequence for Npro leads to an encoded polyprotein is characterized by the following formula:
- [Npro]x−[PS]1−[C-term],
- wherein PS is ubiquitin or LC3.
20. The classical swine fever virus according to claim 12, wherein mutation(s) in the coding sequence for Npro leads to an encoded polyprotein as characterized by a formula selected from the group consisting of:
- M−[PS]0−[C-term];
- MEL−[PS]0−[C-term];
- MELN−[PS]0−[C-term];
- MELNH−[PS]0−[C-term];
- MELHF−[PS]0−[C-term];
- MELNHFE−[PS]0−[C-term];
- MELNHFEL−[PS]0−[C-term];
- MELNHFELL−[PS]0−[C-term];
- MELNHFELLY−[PS]0−[C-term];
- MELNHFELLYK−[PS]0−[C-term]; and
- MELNHFELLYKT−[PS]0−[C-term].
21. The classical swine fever virus according to claim 12, wherein the mutation(s) in the coding sequence for Npro leads to an encoded polyprotein as characterized by the following formula: wherein [C-term]* is [C-term] wherein in the C-protein the amino acid at position 2 is changed from D to N.
- [Npro]x−[PS]0−ME−[PS]0−[C-term*],
22. The classical swine fever virus according to claim 12, wherein the mutation(s) in the coding sequence for Npro leads to an encoded polyprotein as characterized by the following formula:
- [Npro]22−[PS]1−[C-term],
- wherein PS is ubiquitin or LC3.
23. The classical swine fever virus according to one of claims 12, wherein the [PS]0 is replaced by [PS]1, and wherein the PS is selected from the group of consisting of: ubiquitin, LC3, SUMO-1, NEDD8, GATE-16, GABA(A)RAP, intein, picornavirus 3C, caridovirus 2A, and p15 of rabbit hemorrhagic disease virus.
24. A composition comprising the virus according to claim 1 and a solution.
25. The composition according to claim 24, which induces an immunological response in an animal.
26. The composition according to claim 24, which is a vaccine.
27. The composition according to claim 26, further comprising a pharmaceutically acceptable carrier or excipient.
28. A nucleic acid molecule comprising the nucleic acid encoding a classical swine fever virus according to claim 1, or a fragment, functional variant, variant based on the degenerative nucleic acid code, fusion molecule, or a chemical derivative thereof.
29. The nucleic acid molecule according to claim 28, wherein the nucleotide molecule is DNA.
30. The nucleic acid molecule according to claim 29, wherein the nucleotide molecule is RNA.
31. A method for attenuating a classical swine fever virus, wherein at least one mutation in the coding sequence for glycoprotein Ems and at least another mutation in the coding sequence for Npro is generated in a pestivirus.
32. The method according to claim 31, the method comprising:
- (a) reversely transcribing a wild type classical swine fever to obtain a cDNA;
- (b) cloning the cDNA;
- (c) introducing mutations selected from deletions, insertion mutations, and/or substitution mutations into the cDNA, wherein the mutations are located in the coding sequence encoding glycoprotein Ems and the protease Nxo; and
- (d) incorporating the cDNA into a plasmid or into a DNA virus capable of directing the transcription of the classical swine fever virus cDNA into RNA in vitro or upon infection of suitable cells.
33. A method of treatment of disease caused by classical swine fever virus, the method comprising administering to an animal in need thereof an effective amount of the attenuated classical swine fever virus according to claim 1.
34. A method for attenuating a classical swine fever virus, wherein at least one mutation in the coding sequence for glycoprotein Ems and at least another mutation in the coding sequence for Npro is generated in the classical swine fever virus and wherein the attenuated virus does not cross the placenta in animals infected with the attenuated virus.
35. The method according to claim 34, the method comprising:
- (a) reversely transcribing a wild type classical swine fever virus to obtain a cDNA;
- (b) cloning the cDNA;
- (c) introducing mutations selected from deletions, insertion mutations, and/or substitution mutations into the cDNA, wherein the mutations are located in the coding sequence encoding glycoprotein Ems and the protease NPpro; and
- (d) incorporating the cDNA into a plasmid or into a DNA virus capable of directing the transcription of classical swine fever virus cDNA into RNA in vitro or upon infection of suitable cells.
Type: Application
Filed: Oct 18, 2012
Publication Date: Feb 14, 2013
Applicant: BOEHRINGER INGELHEIM VETMEDICA GMBH (Ingelheim)
Inventor: Boehringer Ingelheim Vetmedica Gmbh (Ingelheim)
Application Number: 13/655,278
International Classification: C12N 7/04 (20060101); A61P 31/14 (20060101); C12N 15/40 (20060101); A61P 37/04 (20060101); A61K 39/187 (20060101); C12N 15/63 (20060101);