Influenza is a leading cause of death among American adults. Each year, about 36,000 people die from influenza, and more than 200,000 people are hospitalized. Influenza is a highly contagious disease that is spread by coughing, sneezing and through direct physical contact with objects that carry the virus such as doorknobs and telephones. Symptoms of influenza include fever, extreme fatigue, headache, chills and body aches; about 50 percent of infected people have no symptoms but are still contagious. Immunization is 70-90 percent effective in preventing influenza in healthy people under the age of 65, as long as the antigenicities of the circulating virus strain match those of the vaccine.
Vaccination is the main method for preventing influenza, and both live attenuated and inactivated (killed) virus vaccines are currently available. Live virus vaccines, typically administered intranasally, activate all phases of the immune system and can stimulate an immune response to multiple viral antigens. Thus, the use of live viruses overcomes the problem of destruction of viral antigens that may occur during preparation of inactivated viral vaccines. In addition, the immunity produced by live virus vaccines is generally more durable, more effective, and more cross-reactive than that induced by inactivated vaccines, and live virus vaccines are less costly to produce than inactivated virus vaccines. However, the mutations in attenuated virus are often ill-defined, and reversion is a concern.
In one aspect, the present disclosure provides a nucleic acid sequence comprising SEQ ID NO:1.
In one aspect, the present disclosure provides a nucleic acid sequence comprising SEQ ID NO:2.
In one aspect, the present disclosure provides a nucleic acid sequence comprising SEQ ID NO:3.
In one aspect, the present disclosure provides a composition comprising SEQ ID NO:1, SEQ ID NO:2 or SEQ ID NO: 3, operably linked to (i) a promoter, and (ii) a transcription termination sequence.
In one aspect, the present disclosure provides a recombinant influenza virus comprising a mutation in the M gene. In some embodiments, the recombinant influenza virus comprises SEQ ID NO:1, SEQ ID NO:2, or SEQ ID NO: 3. In some embodiments, the mutation in the M gene results in failure of the virus to express the M2 protein, or causes the virus to express a truncated M2 protein having the amino acid sequence of SEQ ID NO:4. In some embodiments, the mutation in the M gene does not revert to wild-type or to a non-wild-type sequence encoding a functional M2 protein for at least 10 passages in an in vitro host cell system. In some embodiments, the virus is an influenza A virus. In some embodiments, the virus is non-pathogenic in a mammal infected with the virus. In some embodiments, the in vitro cell system comprises Chinese Hamster Ovary cells. In some embodiments, the in vitro cell system comprises Vero cells.
In one aspect, the present disclosure provides a cell comprising the recombinant influenza virus of any one of claims 5-10. In some embodiments, the cell is in vitro. In some embodiments, the cell is in vivo.
In one aspect, the present disclosure provides a composition comprising: a recombinant influenza virus comprising a mutation in the M gene. In some embodiments, the composition comprises SEQ ID NO:1, SEQ ID NO: 2, or SEQ ID NO:3. In some embodiments, the mutation in the M gene results in failure of the virus to express the M2 protein, or causes the virus to express a truncated M2 protein having the amino acid sequence of SEQ ID NO:4. In some embodiments, the virus is an influenza A virus. In some embodiments, the composition is non-pathogenic to a mammal administered the composition. In some embodiments, the composition elicits a detectable immune response in a mammal within about three weeks after administration of the composition to the mammal.
In one aspect, the present disclosure provides a vaccine comprising: a recombinant influenza virus comprising a mutation in the M gene. In some embodiments, the vaccine comprises SEQ ID NO:1, SEQ ID NO:2, or SEQ ID NO: 3. In some embodiments, the mutation in the M gene results in failure of the virus to express the M2 protein, or causes the virus to express a truncated M2 protein having the amino acid sequence of SEQ ID NO:4. In some embodiments, the virus is an influenza A virus. In some embodiments, the vaccine is non-pathogenic to a mammal administered the vaccine. In some embodiments, the vaccine elicits a detectable immune response in a mammal within about three weeks after administration of the vaccine to the mammal. In some embodiments, the vaccine comprises at least two different influenza viral strains in addition to the recombinant virus. In some embodiments, the vaccine comprises at least one influenza B virus or influenza B virus antigen. In some embodiments, the vaccine comprises at least one influenza C virus or influenza C virus antigen. In some embodiments, the vaccine comprises one or more viruses or viral antigens comprising human influenza A and pandemic influenza viruses from non-human species. In some embodiments, the vaccine comprises the human influenza A virus is selected from the group comprising H1N1, H2N2 and H3N2.
In one aspect, the present disclosure provides a method for propagating a recombinant influenza virus, comprising: contacting a host cell with a recombinant influenza virus SEQ ID NO:1, SEQ ID NO:2 or SEQ ID NO: 3; incubating the host cell for a sufficient time and under conditions suitable for viral replication, and isolating progeny virus particles.
In one aspect, the present disclosure provides a method of preparing a vaccine, comprising: placing a host cell in a bioreactor; contacting the host cell with a recombinant virus SEQ ID NO:1, SEQ ID NO:2 or SEQ ID NO: 3; incubating the host cell for a sufficient time and under conditions suitable for viral propagation; isolating the progeny virus particles; and formulating the progeny virus particles for administration as a vaccine.
In one aspect, the present disclosure provides a method for immunizing a subject, comprising: administering a composition comprising a recombinant influenza virus comprising mutation in the M gene, wherein the mutation in the M gene results in failure of the virus to express the M2 protein, or causes the virus to express a truncated M2 protein having the amino acid sequence of SEQ ID NO:4.
In one aspect, the present disclosure provides a method for reducing the likelihood or severity of infection by influenza A virus in a subject comprising: administering a composition comprising a recombinant influenza virus comprising mutation in the M gene, wherein the mutation in the M gene results in failure of the virus to express the M2 protein, or causes the virus to express a truncated M2 protein having the amino acid sequence of SEQ ID NO:4. In some embodiments, the recombinant influenza virus comprises SEQ ID NO:1, SEQ ID NO:2, or SEQ ID NO:3. In some embodiments, the method comprises providing at least one booster dose of the composition, wherein the at least one booster dose is provided at three weeks after a first administration. In some embodiments, the method comprises administering the composition intranasally, intramuscularly or intracutaneously. In some embodiments, the method comprises administering is performed intracutaneously. In some embodiments, the method comprises administering is performed using a microneedle delivery device.
In one aspect, the present disclosure provides a method for intracutaneous administration of an immunogenic composition comprising: (a) providing a microneedle delivery device comprising (i) a puncture mechanism; (ii) an immunogenic composition layer comprising a plurality of microneedles capable of puncturing skin and allowing an immunogenic composition to be administered intracutaneously; and (b) depressing the puncture mechanism; wherein the immunogenic composition comprises a recombinant influenza virus comprising a mutation in the M gene, and wherein the mutation in the M gene results in failure of the virus to express the M2 protein, or causes the virus to express a truncated M2 protein having the amino acid sequence of SEQ ID NO:4. In some embodiments, the recombinant influenza virus comprises SEQ ID NO:1, SEQ ID NO:2, or SEQ ID NO:3. In some embodiments, the microneedle array is initially positioned inside of a device housing, and upon actuation of a lever allows the microneedles to extend through the device bottom and insert into the skin thereby allowing infusion of the vaccine fluid into the skin.
In one aspect, the present disclosure provides a recombinant influenza virus comprising a mutation in the M gene, wherein the virus does not replicate in an unmodified host cell selected from the group consisting of a Chinese Hamster Ovary (CHO) cell, a Vero cell, a or Madin-Darby canine kidney cell. In some embodiments, the mutation in the M gene results in failure of the virus to express the M2 protein, or causes the virus to express a truncated M2 protein having the amino acid sequence of SEQ ID NO:4.
In one aspect, the present disclosure provides a recombinant cell comprising a nucleic acid encoding an influenza virus M2 ion channel gene, wherein the nucleic acid is expressed in the cell.
In one aspect, the present disclosure provides a recombinant cell comprising a 2,6-sialic acid receptor gene.
In one aspect, the present disclosure provides a recombinant cell comprising a cellular genome or an expression vector that expresses (i) a viral M2 ion channel gene, and (ii) a 2,6-sialic acid receptor gene. In some embodiments, the cell is a eukaryotic cell. In some embodiments, the eukaryotic cell is a Chinese Hamster Ovary cell or a Vero cell. In some embodiments, the recombinant cell further comprises a human influenza virus, wherein the virus does not express a functional M2 protein.
In one aspect, the present disclosure provides a method for producing recombinant influenza viral particles, comprising (A) infecting the cell of one of claims 47-52 with human influenza virus, wherein the cell either (i) constitutively expresses the functional M2 ion channel protein, or (ii) is induced after viral infection to express the functional M2 ion channel protein, and wherein the virus successfully replicates only in the presence of the functional M2 ion channel proteins expressed by the cell; and (B) isolating the progeny virus particles. In some embodiments, the method further comprises formulating the isolated viral particles into a vaccine. In some embodiments, the virus comprises a human influenza virus, and wherein the virus does not express a functional M2 protein.
The following terms are used herein, the definitions of which are provided for guidance.
As used herein, the singular forms “a,” “an,” and “the” designate both the singular and the plural, unless expressly stated to designate the singular only.
The term “about” and the use of ranges in general, whether or not qualified by the term about, means that the number comprehended is not limited to the exact number set forth herein, and is intended to refer to ranges substantially within the quoted range while not departing from the scope of the invention. As used herein, “about” will be understood by persons of ordinary skill in the art and will vary to some extent on the context in which it is used. If there are uses of the term which are not clear to persons of ordinary skill in the art given the context in which it is used, “about” will mean up to plus or minus 10% of the particular term.
As used herein “subject” and “patient” are used interchangeably and refer to an animal, for example, a member of any vertebrate species. The methods and compositions of the presently disclosed subject matter are particularly useful for warm-blooded vertebrates including mammals and birds. Exemplary subjects may include mammals such as humans, as well as mammals and birds of importance due to being endangered, of economic importance (animals raised on farms for consumption by humans) and/or of social importance (animals kept as pets or in zoos) to humans. In some embodiments, the subject is a human. In some embodiments, the subject is not human.
As used herein, the terms “effective amount” or “therapeutically effective amount” or “pharmaceutically effective amount” refer to a quantity sufficient to achieve a desired therapeutic and/or prophylactic effect, e.g., an amount which results in the prevention of, disease, condition and/or symptom(s) thereof. In the context of therapeutic or prophylactic applications, the amount of a composition administered to the subject will depend on the type and severity of the disease and on the characteristics of the individual, such as general health, age, sex, body weight and tolerance to the composition drugs. It will also depend on the degree, severity and type of disease or condition. The skilled artisan will be able to determine appropriate dosages depending on these and other factors. In some embodiments, multiple doses are administered. Additionally or alternatively, in some embodiments, multiple therapeutic compositions or compounds (e.g., immunogenic compositions, such as vaccines) are administered.
As used herein, the terms “isolated” and/or “purified” refer to in vitro preparation, isolation and/or purification of a nucleic acid (e.g., a vector or plasmid), polypeptide, virus or cell such that it is not associated with unwanted in vivo substances, or is substantially purified from unwanted in vivo substances with which it normally occurs. For example, in some embodiments, an isolated virus preparation is obtained by in vitro culture and propagation, and is substantially free from other infectious agents. As used herein, “substantially free” means below the level of detection for a particular compound, such as unwanted nucleic acids, proteins, cells, viruses, infectious agents, etc. using standard detection methods for that compound or agent.
As used herein the term “recombinant virus” refers to a virus that has been manipulated in vitro, e.g., using recombinant nucleic acid techniques, to introduce changes to the viral genome and/or to introduce changes to the viral proteins. For example, in some embodiments, recombinant viruses may include both wild-type, endogenous, nucleic acid sequences and mutant and/or exogenous nucleic acid sequences. Additionally or alternatively, in some embodiments, recombinant viruses may include modified protein components, such as mutant or variant matrix, hemagglutinin, neuraminidase, nucleoprotein, non-structural and/or polymerase proteins.
As used herein the term “recombinant cell” or “modified cell” refer to a cell that has been manipulated in vitro, e.g., using recombinant nucleic acid techniques, to introduce nucleic acid into the cell and/or to modify cellular nucleic acids. Examples of recombinant cells includes prokaryotic or eukaryotic cells carrying exogenous plasmids, expression vectors and the like, and/or cells which include modifications to their cellular nucleic acid (e.g., substitutions, mutations, insertions, deletions, etc., into the cellular genome). An exemplary recombinant cell is one which has been manipulated in vitro to express an exogenous protein, such as a viral M2 protein.
As used herein the terms “mutant,” “mutation,” and “variant” are used interchangeably and refer to a nucleic acid or polypeptide sequence which differs from a wild-type sequences. In some embodiments, mutant or variant sequences are naturally occurring. In other embodiments, mutant or variant sequence are recombinantly and/or chemically introduced. In some embodiments, nucleic acid mutations include modifications (e.g., additions, deletions, substitutions) to RNA and/or DNA sequences. In some embodiments, modifications include chemical modification (e.g., methylation) and may also include the substitution or addition of natural and/or non-natural nucleotides. Nucleic acid mutations may be silent mutations (e.g., one or more nucleic acid changes which code for the same amino acid as the wild-type sequence) or may result in a change in the encoded amino acid, result in a stop codon, or may introduce splicing defects or splicing alterations. Nucleic acid mutations to coding sequences may also result in conservative or non-conservative amino acid changes.
As used herein, the term “vRNA” refers to the RNA comprising a viral genome, including segmented or non-segmented viral genomes, as well as positive and negative strand viral genomes. vRNA may be wholly endogenous and “wild-type” and/or may include recombinant and/or mutant sequences.
As used herein, the term “host cell” refers to a cell in which a pathogen, such as a virus, can replicate. In some embodiments, host cells are in vitro, cultured cells (e.g., CHO cells, Vero cells, MDCK cells, etc.) Additionally or alternatively, in some embodiments, host cells are in vivo (e.g., cells of an infected vertebrate, such as an avian or mammal). In some embodiments, the host cells may be modified, e.g., to enhance viral production such as by enhancing viral infection of the host cell and/or by enhancing viral growth rate. By way of example, but not by way of limitation, exemplary host cell modifications include recombinant expression of 2-6-linked sialic acid receptors on the cell surface of the host cell, and/or recombinant expression of a protein in the host cells that has been rendered absent or ineffective in the pathogen or virus.
As used herein, the term “infected” refers to harboring a disease or pathogen, such as a virus. An infection can be intentional, such as by administration of a virus or pathogen (e.g., by vaccination), or unintentional, such as by natural transfer of the pathogen from one organism to another, or from a contaminated surface to the organism.
As used herein, the term “attenuated,” as used in conjunction with a virus, refers to a virus having reduced virulence or pathogenicity as compared to a non-attenuated counterpart, yet is still viable or live. Typically, attenuation renders an infectious agent, such as a virus, less harmful or virulent to an infected subject compared to a non-attenuated virus. This is in contrast to killed or completely inactivated virus.
As used herein, the term “type” and “strain” as used in conjunction with a virus are used interchangeably, and are used to generally refer to viruses having different characteristics. For example, influenza A virus is a different type of virus than influenza B virus. Likewise, influenza A H1N1 is a different type of virus than influenza A H2N1, H2N2 and H3N2. Additionally or alternatively, in some embodiments, different types of virus such as influenza A H2N1, H2N2 and H3N2 may be termed “subtypes.”
As used herein, “M2KO” or “M2KO(ΔTM)” refers to SEQ ID NO:1, a virus comprising SEQ ID NO:1, or a vaccine comprising a virus comprising SEQ ID NO:1, depending on the context in which it is used. For example, in describing mutations of the M2 gene demonstrated herein, “M2KO” or “M2KO(ΔTM)” refers to SEQ ID NO:1. When describing the viral component of a vaccine, “M2KO” or “M2KO(ΔTM)” refers to a recombinant influenza virus which possesses internal 6 genes of PR8 (nucleoprotein (NP), polymerase genes (PA, PB1, PB2), non-structural (NS), matrix (M)), but which does not express functional M2 protein. When describing a vaccine, “M2KO” or “M2KO(ΔTM)” refers to a vaccine comprising the M2KO(ΔTM) recombinant virus.
As used herein, “M2KO(ΔTM) virus” encompasses a recombinant influenza virus which possesses internal 6 genes of PR8 (nucleoprotein (NP), polymerase genes (PA, PB1, PB2), non-structural (NS), matrix (M)), but which does not express functional M2 protein, alone or in combination with other viral components and/or genes encoding other viral components. In some embodiments, the M2KO(ΔTM) virus comprises genes of other influenza viruses. In some embodiments, the virus comprises the HA and NA genes of Influenza A/Brisbane/10/2007-like A/Uruguay/716/2007(H3N2). In some embodiments, the M2KO(ΔTM) virus comprises the HA and NA genes of the A/Vietnam/1203/2004 (H5N1) virus. In some embodiments, the M2KO(ΔTM) virus comprises the HA and NA genes of the A/California/07/2009 (CA07) (H1N1pdm) virus.
A. General
Influenza is a leading cause of death among American adults. The causal agent of influenza are viruses of the family orthomyxoviridae including influenza A virus, influenza B virus and influenza C virus, with influenza A being the most common and most virulent in humans.
The influenza A virus is an enveloped, negative-strand RNA virus. The genome of influenza A virus is contained on eight single (non-paired) RNA strands the complements of which code for eleven proteins (HA, NA, NP, M1, M2, NS1, NEP, PA, PB1, PB1-F2, PB2). The total genome size is about 14,000 bases. The segmented nature of the genome allows for the exchange of entire genes between different viral strains during cellular cohabitation. The eight RNA segments are as follows. 1) HA encodes hemagglutinin (about 500 molecules of hemagglutinin are needed to make one virion); 2) NA encodes neuraminidase (about 100 molecules of neuraminidase are needed to make one virion); 3) NP encodes nucleoprotein; 4) M encodes two proteins (the M1 and the M2) by using different reading frames from the same RNA segment (about 3000 M1 molecules are needed to make one virion); 5) NS encodes two proteins (NS1 and NEP) by using different reading frames from the same RNA segment; 6) PA encodes an RNA polymerase; 7) PB1 encodes an RNA polymerase and PB1-F2 protein (induces apoptosis) by using different reading frames from the same RNA segment; 8) PB2 encodes an RNA polymerase.
There are several subtypes of influenza A, named according to an H number (for the type of hemagglutinin) and an N number (for the type of neuraminidase). Currently, there are 16 different H antigens known (H1 to H16) and nine different N antigens known (N1 to N9). Each virus subtype has mutated into a variety of strains with differing pathogenic profiles; some pathogenic to one species but not others, some pathogenic to multiple species. Exemplary Influenza A virus subtypes that have been confirmed in humans, include, but are not limited to H1N1 which caused the “Spanish Flu” and the 2009 swine flu outbreak; H2N2 which caused the “Asian Flu” in the late 1950s; H3N2 which caused the Hong Kong Flu in the late 1960s; H5N1, considered a global influenza pandemic threat through its spread in the mid-2000s; H7N7; H1N2 which is currently endemic in humans and pigs; and H9N2, H7N2, H7N3, H5N2, H10N7.
Some influenza A variants are identified and named according to the known isolate to which they are most similar, and thus are presumed to share lineage (e.g., Fujian flu virus-like); according to their typical host (example Human flu virus); according to their subtype (example H3N2); and according to their pathogenicity (example LP, Low Pathogenic). Thus, a flu from a virus similar to the isolate A/Fujian/411/2002(H3N2) can be called Fujian flu, human flu, and H3N2 flu.
In addition, influenza variants are sometimes named according to the species (host) the strain is endemic in or adapted to. The main variants named using this convention are: bird flu, human flu, swine influenza, equine influenza and canine influenza. Variants have also been named according to their pathogenicity in poultry, especially chickens, e.g., Low Pathogenic Avian Influenza (LPAI) and Highly Pathogenic Avian Influenza (HPAI).
B. Life Cycle and Structure
The life cycle of influenza viruses generally involves attachment to cell surface receptors, entry into the cell and uncoating of the viral nucleic acid, followed by replication of the viral genes inside the cell. After the synthesis of new copies of viral proteins and genes, these components assemble into progeny virus particles, which then exit the cell. Different viral proteins play a role in each of these steps.
The influenza A particle is made up of a lipid envelope which encapsulates the viral core. The inner side of the envelope is lined by the matrix protein (M1), while the outer surface is characterized by two types of glycoprotein spikes: hemagglutinin (HA) and neuraminidase (NA). M2, a transmembrane ion channel protein, is also part of the lipid envelope. See e.g.,
The HA protein, a trimeric type I membrane protein, is responsible for binding to sialyloligosaccharides (oligosaccharides containing terminal sialic acid linked to galactose) on host cell surface glycoproteins or glycolipids. This protein is also responsible for fusion between viral and host cell membranes, following virion internalization by endocytosis.
Neuraminidase (NA), a tetrameric type II membrane protein, is a sialidase that cleaves terminal sialic acid residues from the glycoconjugates of host cells and the HA and NA, and thus is recognized as receptor-destroying enzyme. This sialidase activity is necessary for efficient release of progeny virions from the host cell surface, as well as prevention of progeny aggregation due to the binding activity of viral HAs with other glycoproteins. Thus, the receptor-binding activity of the HA and the receptor-destroying activity of the NA likely act as counterbalances, allowing efficient replication of influenza.
The genome segments are packaged into the core of the viral particle. The RNP (RNA plus nucleoprotein, NP) is in helical form with three viral polymerase polypeptides associated with each segment.
The influenza virus life cycle begins with binding of the HA to sialic acid-containing receptors on the surface of the host cell, followed by receptor-mediated endocytosis.
C. Role of the M2 Protein
As described above, spanning the viral membrane are three proteins: hemagglutinin (HA), neuramimidase (NA), and M2. The extracellular domains (ectodomains) of HA and NA are quite variable, while the ectodomain domain of M2 is essentially invariant among influenza A viruses. Without wishing to be bound by theory, in influenza A viruses, the M2 protein which possesses ion channel activity, is thought to function at an early state in the viral life cycle between host cell penetration and uncoating of viral RNA. Once virions have undergone endocytosis, the virion-associated M2 ion channel, a homotetrameric helix bundle, is believed to permit protons to flow from the endosome into the virion interior to disrupt acid-labile M1 protein-ribonucleoprotein complex (RNP) interactions, thereby promoting RNP release into the cytoplasm. In addition, among some influenza strains whose HAs are cleaved intracellularly (e.g., A/fowl plagues/Rostock/34), the M2 ion channel is thought to raise the pH of the trans-Golgi network, preventing conformational changes in the HA due to conditions of low pH in this compartment. It was also shown that the M2 transmembrane domain itself can function as an ion channel. M2 protein ion channel activity is thought to be essential in the life cycle of influenza viruses, because amantadine hydrochloride, which blocks M2 ion channel activity, has been shown to inhibit viral replication. However, a requirement for this activity in the replication of influenza A viruses has not been directly demonstrated. The structure of the M2 protein is shown in
Although influenza B and C viruses are structurally and functionally similar to influenza A virus, there are some differences. For example, influenza B virus does not have an M2 protein with ion channel activity. Instead, the NB protein, a product of the NA gene, likely has ion channel activity and thus a similar function to the influenza A virus M2 protein. Similarly, influenza C virus does not have an M2 protein with ion channel activity. However, the CM1 protein of the influenza C virus is likely to have this activity.
III. M2 Viral Mutants
In one aspect, influenza A viruses harboring a mutant M2 vRNA sequence are disclosed. Typically, such mutants do not have M2 ion channel activity, exhibit attenuated growth properties in vivo, cannot produce infectious progeny and are non-pathogenic or show reduced pathogenesis in infected subjects. The mutant viruses are immunogenic, and when used as a vaccine, provide protection against infection with a counterpart wild-type and/or other pathogenic virus. Additionally, the M2 mutants disclosed herein are stable, and do not mutate to express a functional M2 polypeptide, regardless of the host cell used. Additionally or alternatively, in some embodiments, the M1 protein of these mutants is produced without detectable alteration to its function. In some embodiments, viruses harboring the mutant M2 nucleic acid sequences can not replicate in a host cell in which a corresponding wild-type virus could be propagated. By way of example, but not by way of limitation, in some embodiments, the wild-type virus can be grown, propagated and replicate in culturing MDCK cells, CHO cells and/or Vero cells, while the corresponding virus harboring a mutant M2 sequence cannot grow, replicate or be propagated in the same type of cells.
As noted above, in some embodiments, the M2 mutant virus is stable, and does not mutate or revert to wild-type or to a non-wild-type sequence encoding a functional M2 protein in a host cell. For example, in some embodiments, the M2 mutant virus is stable for 2 passages, 3 passages, 5 passages, 10 passages, 12 passages, 15 passages, 20 passages, 25 passages or more than 25 passages in a host cell. In some embodiments, the host cell is an unmodified host cell. In other embodiments, the host cell is a modified host cell, such as a MDCK cell which expresses the M2 protein.
In some embodiments, the M2 mutants include one or more nucleic acid substitutions and/or deletions. In some embodiments, the mutations are localized in nucleic acids which code for one or more of the extracellular domain of the M2 protein, the transmembrane domain of the M2 proteins and/or the cytoplasmic tail of the M2 protein. Additionally or alternatively, in some embodiments, one or more nucleic acid mutations results in a splice variant, one or more stop codons and/or one or more amino acid deletions of the M2 peptide In some embodiments, viruses carrying the mutant M2 nucleic acid produce a non-functional M2 polypeptide. In some embodiments, viruses carrying the mutant M2 nucleic acid do not produce an M2 polypeptide. In some embodiments, viruses carrying the mutant M2 nucleic acid produce a truncated M2 polypeptide. In some embodiments, truncated M2 polypeptide has the amino acid sequence MSLLTEVETPIRNEWGCRCNGSSD.
Three exemplary, non-limiting M2 viral mutants (M2-1, M2-2 and M2-3) are provided below in Tables 1-3. In the tables, lower case letters correspond to the M2 sequence; upper case letters correspond to the M1 sequence; mutant sequence (e.g., stop codons, splice defect) are in bold, underlined. Underlined (lower case) bases in the M2-2 mutant indicate the region deleted in the M2-1 and M2-3 mutants.
The M2 polypeptide sequence produced from this mutant is as follows:
No M2 polypeptide sequence is produced from this mutant.
No M2 polypeptide sequence is produced from this mutant.
Additionally or alternatively, in some embodiments, M2 mutations are introduced into the cytoplasmic tail.
For example, Pekosz et al JVI, 2005; 79(6): 3595-3605, replaced two codons with stop codons at amino acid position 70, but the virus soon reverted. Another exemplary M2 cytoplasmic tail mutation is termed M2del11. In the M2del11 mutant, 11 amino acid residues are deleted from carboxyl end of cytoplasmic tail. This truncation is due to the introduction of two stop codons, and a full length M2 polypeptide is not made. While this mutant is stable when passaged in M2 expressing MDCK cells (M2CK), it reverts to full length M2 during passaging in normal MDCK cells (J Virol. 2008 82(5):2486-92). Without wishing to be bound by theory, it is likely that reversion occurs with selective pressure in the MDCK cells.
Another M2 cytoplasmic tail mutant, M2Stop90ala78-81 did not reduce virus titer but ala70-77 did (JVI 2006; 80 (16) p8178-8189). Alanine-scanning experiments further indicated that amino acids at positions 74 to 79 of the M2 tail play a role in virion morphogenesis and affect viral infectivity. (J Virol. 2006 80(11):5233-40.)
Accordingly, presented herein are novel cytoplasmic mutants, with characteristics different than those described above. For example, in some embodiments, the cytoplasmic mutants are stable (do not revert to express a full-length M2 polypeptide) in MDCK cells. In some embodiments, the cytoplasmic mutants are stable for 2 passages, 3 passages, 5 passages, 10 passages, 15 passages, 20 passages, 25 passages or more than 25 passages in a host cell.
The wild-type M2 polypeptide is shown below in Table 4. For each of the sequences, the bold text indicates the transmembrane domain. The extracellular domain is first (left), followed by the transmembrane domain (center) and the cytoplasmic tail sequence (right).
M2-4 (M2del FG #1) was generated but was not passagable in normal MDCK cells, but may be passagable in a modified host cell (e.g., a cell expressing a wild-type M2 polypeptide). M2-5 (M2del FG #2) and M2-6 (FG #3) were generated and passaged in normal MDCK cells. The nucleotide sequence of the M gene of these viruses are stable at least to passage 10 in MDCK cells. These mutants could be propagated and passaged in other cells as well (e.g., cells that support influenza replication). It was also found that these mutants are not attenuated and are pathogenic.
As described in the Examples below, the M2 mutant viruses described herein do not replicate in the respiratory tract or disseminate to other organs in the ferret model and are not transmitted in the ferret model. Vaccines comprising M2 mutant elicit robust immune responses in mammals and protect mammals against influenza virus challenge. M2KO virus elicits both humoral and mucosal immune responses in mice, and protects mice from lethal homosubtypic and heterosubtypic challenge. Vaccines comprising M2 mutant virus as described herein provide effective protection against influenza challenge and have the advantage of being attenuated in mammalian hosts. These findings demonstrate that the M2 mutant viruses described herein are useful for vaccines against influenza.
A. Producing “First Generation” Mutant Viruses
Mutant virus, such as those carrying mutant M2 nucleic acid, can be generated by plasmid-based reverse genetics as described by Neumann et al., Generation of influenza A viruses entirely from clone cDNAs, Proc. Natl. Acad. Sci. USA 96:9345-9350 (1999), herein incorporated by reference in its entirety. Briefly, eukaryotic host cells are transfected with one or more plasmids encoding the eight viral RNAs. Each viral RNA sequence is flanked by an RNA polymerase I promoter and an RNA polymerase I terminator. Notably, the viral RNA encoding the M2 protein includes the mutant M2 nucleic acid sequence. The host cell is additionally transfected with one or more expression plasmids encoding the viral proteins (e.g., polymerases, nucleoproteins and structural proteins), including a wild-type M2 protein. Transfection of the host cell with the viral RNA plasmids results in the synthesis of all eight influenza viral RNAs, one of which harbors the mutant M2 sequence. The co-transfected viral polymerases and nucleoproteins assemble the viral RNAs into functional vRNPs that are replicated and transcribed, ultimately forming infectious influenza virus having a mutant M2 nucleic acid sequence, yet having a functional M2 polypeptide incorporated into the viral lipid envelope.
Alternative methods of producing a “first generation” mutant virus include a ribonucleoprotein (RNP) transfection system that allows the replacement of influenza virus genes with in vitro generated recombinant RNA molecules, as described by Enami and Palese, High-efficiency formation of influenza virus transfectants, J. Virol. 65(5):2711-2713, which is incorporated herein by reference.
The viral RNA is synthesized in vitro and the RNA transcripts are coated with viral nucleoprotein (NP) and polymerase proteins that act as biologically active RNPs in the transfected cell as demonstrated by Luytjes et al., Amplification, expression, and packaging of a foreign gene by influenza virus, Cell 59:1107-1113, which is incorporated herein by reference.
The RNP transfection method can be divided into four steps: 1) Preparation of RNA: plasmid DNA coding for an influenza virus segment is transcribed into negative-sense RNA in an in vitro transcription reaction; 2) Encapsidation of the RNA: the transcribed RNA is then mixed with gradient purified NP and polymerase proteins isolated from disrupted influenza virus to form a biologically active RNP complex; 3) Transfection and rescue of the encapsidated RNA: the artificial ribonucleocapsid is transfected to the cells previously infected with a helper influenza virus that contains a different gene from the one being rescued; the helper virus will amplify the transfected RNA; 4) Selection of transfected gene: because both the helper virus and the transfectant containing the rescued gene are in the culture supernatant, an appropriate selection system using antibodies is necessary to isolate the virus bearing the transfected gene.
The selection system allows for the generation of novel transfectant influenza viruses with specific biological and molecular characteristics. Antibody selection against a target surface protein can then be used for positive or negative selection.
For example, a transfectant or mutant virus that contains an M2 gene that does not express an M2 protein can be grown in a suitable mammalian cell line that has been modified to stably express the wild-type functional M2 protein. To prevent or inhibit replication of the helper virus expressing the wild-type M2 gene, and therefore the M2e protein at the membrane surface, antibodies against M2e can be used. Such antibodies are commercially available and would inhibit the replication of the helper virus and allow for the transfectant/mutant virus containing the mutant M2 to grow and be enriched in the supernatant. Inhibition of influenza virus replication by M2e antibodies has been described previously in Influenza A virus M2 protein: monoclonal antibody restriction of virus growth and detection of M2 in virions, J Virol 62:2762-2772 (1988) and Treanor et al, Passively transferred monoclonal antibody to the M2 protein inhibits influenza A virus replication in mice, J. Virol. 64:1375-1377 (1990).
Additionally or alternatively, the same antibodies can be used to ‘capture’ the helper virus and allow for the enrichment of the transfectant. For example, the antibodies can be used to coat the bottom of a tissue culture dish or can be used in a column matrix to allow for enrichment for the transfectant in the supernatant or eluate.
The transfectant virus can be grown in M2 expressing cells in multi-well plates by limit dilution and then be identified and cloned, for example, by creating replica plates. For example, one-half of an aliquot of a given well of the multi-well plate containing the grown virus can be used to infect MDCK cells and the other half to infect MDCK cells that express M2 protein. Both the transfectant virus and helper virus will grow in MDCK cells that express M2 protein. However, only helper virus will grow in standard MDCK cells allowing for identifying the well in the multi-well plate that contains the transfectant. The transfectant virus can be further plaque purified in the cells that express M2 protein.
B. Propagating Viral Mutants
In some embodiments, viral mutants described herein are maintained and passaged in host cells. By way of example, but not by way of limitation, exemplary host cells appropriate for growth of influenza viral mutants, such as influenza A viral mutants include any number of eukaryotic cells, including, but not limited to Madin-Darby canine kidney cells (MDCK cells), simian cells such as African green monkey cells (e.g., Vero cells), CV-1 cells and rhesus monkey kidney cells (e.g., LLcomk.2 cells), bovine cells (e.g., MDBK cells), swine cells, ferret cells (e.g., mink lung cells) BK-1 cells, rodent cells (e.g., Chinese Hamster Ovary cells), human cells, e.g., embryonic human retinal cells (e.g., PER-C6®), 293T human embryonic kidney cells and avian cells including embryonic fibroblasts.
Additionally or alternatively, in some embodiments, the eukaryotic host cell is modified to enhance viral production, e.g., by enhancing viral infection of the host cell and/or by enhancing viral growth rate. For example, in some embodiments, the host cell is modified to express, or to have increased expression, of 2,6-linked sialic acid on the cell surface, allowing for more efficient and effective infection of these cells by mutant or wild-type influenza A viruses. See e.g., U.S. Patent Publication No. 2010-0021499, and U.S. Pat. No. 7,176,021, herein incorporated by reference in their entirety. Thus, in some illustrative embodiments, Chinese Hamster Ovary Cells (CHO cells) and/or Vero cells modified to express at least one copy of a 2,6-sialyltransferase gene (ST6GAL 1) are used. By way of example, but not by way of limitation, the Homo sapiens ST6 beta-galatosamide alpha-2,6-sialyltransferase gene sequence denoted by the accession number BC040009.1, is one example of a ST6Gal gene that can be integrated into and expressed by a CHO cell. One or more copies of a polynucleotide that encodes a functional ST6Gal I gene product can be engineered into a cell. That is, cells which have been stably transformed to express 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, or more than 12 copies of a ST6Gal I gene may be used. A single expression cassette may include one or more copies of the ST6Gal I gene to be expressed, which is operably linked to regulatory elements, such as promoters, enhancers, and terminator and polyadenylation signal sequences, to facilitate the expression of the ST6Gal I gene or its copies. Alternatively, a single expression cassette may be engineered to express one copy of an ST6Gal I gene, and multiple expression cassettes integrated into a host cell genome. Accordingly, in some embodiments, at least one ST6Gal I gene is incorporated into the genome of a host cell, such that the cell expresses the ST6Gal I gene and its enzymatic protein product. Depending on the copy number, a single host cell may express many functional ST6Gal I gene proteins.
Suitable vectors for cloning, transfecting and producing stable, modified cell lines are well known in the art. One non-limiting example includes the pcDNA3.1 vectors (Invitrogen).
Additionally or alternatively, in some embodiments, the eukaryotic host cell is modified to produce a wild-type version of a mutant viral gene, thereby providing the gene to the virus in trans. For example, a viral strain harboring a mutant M2 protein may exhibit an enhanced growth rate (e.g., greater viral production) when passaged in host cells producing the wild-type M2 protein. In some embodiments, the a viral strain harboring a mutant M2 protein may not grow or replicate in a cell which does not express a wild-type M2 gene. In addition, such host cells may slow or prevent viral reversion to a functional M2 sequence, because, for example, there is no selective pressure for reversion in such a host.
Method for producing both expression vectors and modified host cells are well known in the art. For example, an M2 expression vector can be made by positioning the M2 nucleic acid sequence (M2 ORF sequence; this is “wild-type” M2's start codon to stop codon (Table 5)) below in a eukaryotic expression vector.
Host cells (e.g., MDCK cells) can then be transfected by methods known in the art, e.g., using commercially available reagents and kits, such as TransIT® LT1 (Mirus Bio, Madison, Wis.). By way of example, but not by way of limitation, cells can be selected and tested for M2 expression by cotransfection with a detectable marker or a selectable marker (e.g., hygromycin-resistance) and/or by screening, for example, with indirect immunostaining using an M2 antibody. M2 expression can be determined by indirect immunostaining, flow cytometry or ELISA.
By way of example, but not by way of limitation, 293T human embryonic kidney cells and Madin-Darby canine kidney (MDCK) cells were maintained in Dulbecco's modified Eagle's medium supplemented with 10% fetal calf serum and in minimal essential medium (MEM) containing 5% newborn calf serum, respectively. All cells were maintained at 37° C. in 5% CO2. Hygromycin-resistant MDCK cells stably expressing M2 protein from A/Puerto Rico/8/34 (H1N1) were established by cotransfection with plasmid pRHyg, containing the hygromycin resistance gene, and plasmid pCAGGS/M2, expressing the full-length M2 protein, at a ratio of 1:1. The stable MDCK cell clone (M2CK) expressing M2 was selected in medium containing 0.15 mg/mL of hygromycin (Roche, Mannheim, Germany) by screening with indirect immunostaining using an anti-M2 (14C2) monoclonal antibody (Iwatsuki et al. JVI, 2006, vol. 80, No. 1, p. 5233-5240). The M2CK cells were cultured in MEM supplemented with 10% fetal calf serum and 0.15 mg/mL of hygromycin. In M2CK cells, the expression levels and localization of M2 were similar to those in virus-infected cells (data not shown). M2 expressing Vero cells can be made in a similar fashion.
In some embodiments, cells and viral mutants are cultured and propagated by methods well known in the art. By way of example, but not by way of limitation, in some embodiments, host cells are grown in the presence of MEM supplemented with 10% fetal calf serum. Cells expressing M2 are infected at an MOI of 0.001 by washing with PBS followed by adsorbing virus at 37° C. In some embodiments, viral growth media containing trypsin/TPCK is added and the cells are incubated for 2-3 days until cytopathic effect is observed.
Along these lines, disposable bioreactor systems have been developed for mammalian cells, with or without virus, whose benefits include faster facility setup and reduced risk of cross-contamination. The cells described herein, for instance, can be cultured in disposable bags such as those from Stedim, Bioeaze bags from SAFC Biosciences, HybridBag™ from Cellexus Biosytems, or single use bioreactors from HyClone or Celltainer from Lonza. Bioreactors can be 1 L, 10 L, 50 L, 250 L, 1000 L size formats. In some embodiments, the cells are maintained in suspension in optimized serum free medium, free of animal products. The system can be a fed-batch system where a culture can be expanded in a single bag from 1 L to 10 L for example, or a perfusion system that allows for the constant supply of nutrients while simultaneously avoiding the accumulation of potentially toxic by-products in the culture medium.
For long term storage, mutant virus can be stored as frozen stocks.
A. Immunogenic Compositions/Vaccines
There are various different types of vaccines which can be made from the cell-based virus production system disclosed herein. The present disclosure includes, but is not limited to, the manufacture and production of live attenuated virus vaccines, inactivated virus vaccines, whole virus vaccines, split virus vaccines, virosomal virus vaccines, viral surface antigen vaccines and combinations thereof. Thus, there are numerous vaccines capable of producing a protective immune response specific for different influenza viruses where appropriate formulations of any of these vaccine types are capable of producing an immune response, e.g., a systemic immune response. Live attenuated virus vaccines have the advantage of being also able to stimulate local mucosal immunity in the respiratory tract.
In some embodiments, vaccine antigens used in the compositions described herein are “direct” antigens, i.e. they are not administered as DNA, but are the antigens themselves. Such vaccines may include a whole virus or only part of the virus, such as, but not limited to viral polysaccharides, whether they are alone or conjugated to carrier elements, such as carrier proteins, live attenuated whole microorganisms, inactivated microorganisms, recombinant peptides and proteins, glycoproteins, glycolipids, lipopeptides, synthetic peptides, or ruptured microorganisms in the case of vaccines referred to as “split” vaccines.
In some embodiments a complete virion vaccine is provided. A complete virion vaccine can be concentrated by ultrafiltration and then purified by zonal centrifugation or by chromatography. Typically, the virion is inactivated before or after purification using formalin or beta-propiolactone, for instance.
In some embodiments, a subunit vaccine is provided, which comprises purified glycoproteins. Such a vaccine may be prepared as follows: using viral suspensions fragmented by treatment with detergent, the surface antigens are purified, by ultracentrifugation for example. The subunit vaccines thus contain mainly HA protein, and also NA. The detergent used may be cationic detergent for example, such as hexadecyl trimethyl ammonium bromide, an anionic detergent such as ammonium deoxycholate; or a nonionic detergent such as that commercialized under the name TRITON X100. The hemagglutinin may also be isolated after treatment of the virions with a protease such as bromelin, then purified by standard methods.
In some embodiments, a split vaccine is provided, which comprises virions which have been subjected to treatment with agents that dissolve lipids. A split vaccine can be prepared as follows: an aqueous suspension of the purified virus obtained as above, inactivated or not, is treated, under stirring, by lipid solvents such as ethyl ether or chloroform, associated with detergents. The dissolution of the viral envelope lipids results in fragmentation of the viral particles. The aqueous phase is recuperated containing the split vaccine, constituted mainly of hemagglutinin and neuraminidase with their original lipid environment removed, and the core or its degradation products. Then the residual infectious particles are inactivated if this has not already been done.
In some embodiments, inactivated influenza virus vaccines are provided. In some embodiments, the inactivated vaccines are made by inactivating the virus using known methods, such as, but not limited to, formalin or B-propiolactone treatment. Inactivated vaccine types that can be used in the invention can include whole-virus (WV) vaccines or subvirion (SV) (split) vaccines. The WV vaccine contains intact, inactivated virus, while the SV vaccine contains purified virus disrupted with detergents that solubilize the lipid-containing viral envelope, followed by chemical inactivation of residual virus.
Additionally or alternatively, in some embodiments, live attenuated influenza virus vaccines are provided. Such vaccines can be used for preventing or treating influenza virus infection, according to known method steps.
In some embodiments, attenuation is achieved in a single step by transfer of attenuated genes from an attenuated donor virus to an isolate or reassorted virus according to known methods (see, e.g., Murphy, Infect. Dis. Clin. Pract. 2, 174 (1993)). In some embodiments, a virus is attenuated by mutation of one or more viral nucleic acid sequences, resulting in a mutant virus. For example, in some embodiments, the mutant viral nucleic acid sequence codes for a defective protein product. In some embodiments, the protein product has diminished function or no function. In other embodiments, no protein product is produced from the mutant viral nucleic acid.
The virus can thus be attenuated or inactivated, formulated and administered, according to known methods, as an immunogenic composition (e.g., as a vaccine) to induce an immune response in an animal, e.g., an avian and/or a mammal. Methods are well-known in the art for determining whether such attenuated or inactivated vaccines have maintained similar antigenicity to that of the clinical isolate or a high growth strain derived therefrom. Such known methods include the use of antisera or antibodies to eliminate viruses expressing antigenic determinants of the donor virus; chemical selection (e.g., amantadine or rimantidine); HA and NA activity and inhibition; and DNA screening (such as probe hybridization or PCR) to confirm that donor genes encoding the antigenic determinants (e.g., HA or NA genes) or other mutant sequences (e.g., M2) are not present in the attenuated viruses. See, e.g., Robertson et al., Giornale di Igiene e Medicina Preventiva, 29, 4 (1988); Kilbourne, Bull. M2 World Health Org., 41, 643 (1969); and Robertson et al., Biologicals, 20, 213 (1992).
In some embodiments, the vaccine includes an attenuated influenza virus that lacks expression of a functional M2 protein. In some embodiments, the mutant virus replicates well in cells expressing M2 proteins, but in the corresponding wild-type cells, expresses viral proteins without generating infectious progeny virions.
Pharmaceutical compositions of the present invention, suitable for intradermal administration, inoculation or for parenteral or oral administration, comprise attenuated or inactivated influenza viruses, and may optionally further comprising sterile aqueous or non-aqueous solutions, suspensions, and emulsions. The compositions can further comprise auxiliary agents or excipients, as known in the art. See, e.g., Berkow et al., The Merck Manual, 15th edition, Merck and Co., Rahway, N.J. (1987); Goodman et al., eds., Goodman and Gilman's The Pharmacological Basis of Therapeutics, Eighth Edition, Pergamon Press, Inc., Elmsford, N.Y. (1990); Avery's Drug Treatment: Principles and Practice of Clinical Pharmacology and Therapeutics, Third Edition, ADIS Press, LTD., Williams and Wilkins, Baltimore, Md. (1987); and Katzung, ed., Basic and Clinical Pharmacology, Fifth Edition, Appleton and Lange, Norwalk, Conn. (1992).
In some embodiments, preparations for parenteral administration include sterile aqueous or non-aqueous solutions, suspensions, and/or emulsions, which may contain auxiliary agents or excipients known in the art. Examples of non-aqueous solvents are propylene glycol, polyethylene glycol, vegetable oils such as olive oil, and injectable organic esters such as ethyl oleate. Carriers or occlusive dressings can be used to increase skin permeability and enhance antigen absorption. Liquid dosage forms for oral administration may generally comprise a liposome solution containing the liquid dosage form. Suitable forms for suspending liposomes include emulsions, suspensions, solutions, syrups, and elixirs containing inert diluents commonly used in the art, such as purified water. Besides the inert diluents, such compositions can also include adjuvants, wetting agents, emulsifying and suspending agents, or sweetening, flavoring, or perfuming agents.
When a composition of the present invention is used for administration to an individual, it can further comprise salts, buffers, adjuvants, or other substances which are desirable for improving the efficacy of the composition. For vaccines, adjuvants, substances that augment a specific immune response, can be used. Normally, the adjuvant and the composition are mixed prior to presentation to the immune system, or presented separately, but into the same site of the organism being immunized.
In some embodiments, the immunogenic compositions (e.g., vaccines) disclosed herein include multiple, different types of virus or viral antigens, at least one of which includes a mutant M2 gene (e.g., a virus comprising the M2KO(ΔTM) (SEQ ID NO:1) mutation), and/or a corresponding mutation in the M2 functional equivalent of that virus (e.g., the NB protein of influenza B, or the CM1 protein of influenza C). In other embodiments, the immunogenic compositions include a single type of virus or viral antigen which includes a mutant M2 gene (e.g., a virus comprising the M2KO(ΔTM) (SEQ ID NO:1) mutation) and/or a corresponding mutation in the M2 functional equivalent of that virus (e.g., the NB protein of influenza B, or the CM1 protein of influenza C). For example, in some embodiments, the main constituent of an immunogenic compositions such as a vaccine composition includes one or more influenza viruses of type A, B or C, or any combination thereof or any combination of antigens from these viruses, wherein at least one virus includes a mutant M2 gene (e.g., a virus comprising the M2KO(ΔTM) (SEQ ID NO:1) mutation) and/or a corresponding mutation in the M2 functional equivalent of that virus (e.g., the NB protein of influenza B, or the CM1 protein of influenza C) For example, in some embodiments, at least two of the three types, at least two of different subtypes, at least two of the same type, at least two of the same subtype, or a different isolate(s) or reassortant(s) are provided in an immunogenic composition (e.g., a vaccine). By way of example, but not by way of limitation, human influenza virus type A includes H1N1, H2N2 and H3N2 subtypes. In some embodiments, the immunogenic compositions (e.g., vaccines) include a virus comprising a mutant M2 gene (e.g., a virus comprising the M2KO(ΔTM) (SEQ ID NO:1) mutation) and/or a corresponding mutation in the M2 functional equivalent of that virus (e.g., the NB protein of influenza B, or the CM1 protein of influenza C) and about 0.1 to 200 μg, e.g., 10 to 15 μg of hemagglutinin from each of the strains entering into the composition. Heterogeneity in a vaccine may be provided by mixing replicated influenza viruses for at least two influenza virus strains, such as from 2-50 strains, or any range or value therein. In some embodiments, influenza A or B virus strains having a modern antigenic composition are used. In addition, immunogenic compositions (e.g., vaccines) can be provided for variations in a single strain of an influenza virus, using techniques known in the art.
In some embodiments, the vaccine comprises a virus comprising the M2KO(ΔTM) (SEQ ID NO:1) mutation together with other viral components and/or genes expressing other viral components. In some embodiments, the vaccine (e.g., a virus comprising the M2KO(ΔTM) (SEQ ID NO:1) mutation) comprises genes from other viral strains, including but not limited to, for example, HA and NA genes from other viral strains. In some embodiments, the vaccine comprises HA and NA genes from human influenza virus type A subtypes H5N1, H1N1, H2N2 or H3N2. In some embodiments, the vaccine comprises HA and NA genes from, for example, PR8xBrisbane/10/2007, A/Vietnam/1203/2004, or A/California/07/2009 (CA07) viruses.
A pharmaceutical composition according to the present invention may further or additionally comprise at least one chemotherapeutic compound, e.g., for gene therapy, an immunosuppressant, an anti-inflammatory agent or an immunostimulatory agent, or anti-viral agents including, but not limited to, gamma globulin, amantadine, guanidine, hydroxybenzimidazole, interferon-α, interferon-β, interferon-γ, tumor necrosis factor-α, thiosemicarbarzones, methisazone, rifampin, ribavirin, a pyrimidine analog, a purine analog, foscarnet, phosphonoacetic acid, acyclovir, dideoxynucleosides, a protease inhibitor, or ganciclovir.
The composition can also contain variable but small quantities of endotoxin-free formaldehyde, and preservatives, which have been found safe and not contributing to undesirable effects in the organism to which the composition of the invention is administered.
B. Administration
An immunogenic composition (e.g., vaccine) as disclosed herein may be administered via any of the routes conventionally used or recommended for vaccines: parenteral route, mucosal route, and may be in various forms: injectable or sprayable liquid, formulation which has been freeze-dried or dried by atomization or air-dried, etc. Vaccines may be administered by means of a syringe or by means of a needle-free injector for intramuscular, subcutaneous or intradermal injection. Vaccines may also be administered by means of a nebulizer capable of delivering a dry powder or a liquid spray to the mucous membranes, whether they are nasal, pulmonary, vaginal or rectal.
A vaccine as disclosed herein may confer resistance to one or more influenza strains by either passive immunization or active immunization. In active immunization, an inactivated or attenuated live vaccine composition is administered prophylactically to a host (e.g., a mammal), and the host's immune response to the administration protects against infection and/or disease. For passive immunization, the elicited antisera can be recovered and administered to a recipient suspected of having an infection caused by at least one influenza virus strain.
The present invention thus includes methods for preventing or attenuating a disease or disorder, e.g., infection by at least one influenza virus strain. As used herein, a vaccine is said to prevent or attenuate a disease if its administration results either in the total or partial attenuation (i.e., suppression) of a symptom or condition of the disease, or in the total or partial immunity of the individual to the disease.
At least one inactivated or attenuated influenza virus, or composition thereof, of the present invention may be administered by any means that achieve the intended purposes, using a pharmaceutical composition as previously described. For example, administration of such a composition may be by various parenteral routes such as subcutaneous, intravenous, intradermal, intramuscular, intraperitoneal, intranasal, oral or transdermal routes. Parenteral administration can be by bolus injection or by gradual perfusion over time. In some embodiments, an immunogenic composition as disclosed herein is by intramuscular or subcutaneous application.
In some embodiments, a regimen for preventing, suppressing, or treating an influenza virus related pathology comprises administration of an effective amount of a vaccine composition as described herein, administered as a single treatment, or repeated as enhancing or booster dosages, over a period up to and including between one week and about 24 months, or any range or value therein. In some embodiments, an influenza vaccine as disclosed herein is administered annually.
According to the present invention, an “effective amount” of a vaccine composition is one that is sufficient to achieve a desired biological effect. It is understood that, in some embodiments, the effective dosage will be dependent upon the age, sex, health, and weight of the recipient, kind of concurrent treatment, if any, frequency of treatment, and the nature of the effect wanted. The ranges of effective doses provided below are not intended to be limiting and represent exemplary dose ranges. Thus, in some embodiments, the dosage will be tailored to the individual subject, as is understood and determinable by one of skill in the art. The dosage of an attenuated virus vaccine for a mammalian (e.g., human) adult can be from about 103-107 plaque forming units (PFU), or any range or value therein. The dose of inactivated vaccine can range from about 0.1 to 200, e.g., 50 μg of hemagglutinin protein. However, the dosage should be a safe and effective amount as determined by conventional methods, using existing vaccines as a starting point.
C. Intracutaneous Delivery
Live flu vaccines are traditionally delivered intranasally to mimic the natural route of infection and promote a similar immune response to that of natural virus infection. As an alternative, disclosed herein are intradermal delivery methods which involve the use of a novel microneedle device to capitalize on the immunological benefits of intradermal delivery. In some embodiments, an attenuated virus (e.g., an M2 viral mutant) is used in a vaccine composition for intradermal administration. In some embodiments, an M2 viral mutant, which does not produce infectious progeny virus, is provided in a vaccine. Thus, any potential of reassortment with wild-type circulating influenza viruses is virtually eliminated.
In embodiments disclosed herein, intradermal delivery (intracutaneous) administers vaccine to the skin. In some embodiments, intradermal delivery is performed using a microneedle delivery device. As disclosed herein, intracutaneous delivery has numerous advantages. For example, the immunogenicity of the vaccine is enhanced by triggering the immunological potential of the skin immune system. The vaccine has direct access to the potent antigen-presenting dendritic cells of the skin, i.e., epidermal Langerhans Cells and dermal dendritic cells. Skin cells produce proinflammatory signals which enhance the immune response to antigens introduced through the skin. Further, the skin immune system produces antigen-specific antibody and cellular immune responses. Intradermal delivery allows for vaccine dose sparing, i.e., lower doses of antigen may be effective, in light of the above factors, when delivered intracutaneously.
And, because the vaccine is delivered to the skin through the device's microneedle array, the risk of unintended needle-sticks is reduced, and intracutaneous vaccine delivery via microneedle array is relatively painless compared to intramuscular injections with conventional needle and syringe.
Microneedle devices are known in the art, are known in the art, including, for example, those described in published U.S. patent applications 2012/0109066, 2011/0172645, 2011/0172639, 2011/0172638, 2011/0172637, and 2011/0172609. Microneedle devices may be made, for example, by fabrication from stainless steel sheets (e.g., Trinity Brand Industries, Georgia; SS 304; 50 μm thick) by wet etching. In some embodiments, individual microneedles have a length of between about 500 μm and 1000 μm, e.g., about 750 μm, and a width of between about 100 μm to 500 μm, e.g., about 200 μm. Vaccine can then be applied to the microneedles as a coating. By way of example, but not by way of limitation, a coating solution may include 1% (w/v) carboxymethyl cellulose sodium salt (low viscosity, USP grad; Carbo-Mer, San Diego Calif.), 0.5% (w/v) Lutrol F-68 NF (BASF, Mt. Olive, N.J.) and the antigen (e.g., soluble HA protein at 5 ng/ml; live, attenuated virus such as the M2 mutant virus described herein, etc.). To reach a higher vaccine concentration, the coating solution may be evaporated for 5 to 10 minutes at room temperature (˜23° C.). Coating may be performed by a dip coating process. The amount of vaccine per row of microneedles can be determined by submerging the microneedles into 200 μl of phosphate-buffered saline (PBS) for 5 minutes and assaying for the antigen by methods known in the art.
In some embodiments, a microneedle device is used that is made mainly of polypropylene and stainless steel first-cut pieces that fit together with simple snap fits and heat seals. In some embodiments, the device is completely self-contained and includes the vaccine, a pump mechanism, an activation mechanism, and a microneedle unit. These components are hidden within a plastic cover. With the device, vaccine infusion is initiated by pressing an actuation button. Pressing the button simultaneously inserts the microneedles into the skin and initiates the pumping mechanism that exerts pressure on the primary drug container. When a spring mechanism exerts sufficient pressure on the vaccine reservoir, vaccine begins to flow through the microneedle array, and into the skin. In some embodiments, the delivery of the vaccine dose is completed within about 2 minutes after actuation of the device. After infusion is complete, the device is gently removed from the skin.
In some embodiments, a method for intracutaneous administration of an immunogenic composition (e.g., a vaccine) is provided using a microneedle device. In some embodiments, the microneedle device comprises a puncture mechanism and an immunogenic composition layer comprising a plurality of microneedles capable of puncturing skin and allowing an immunogenic composition to be administered intracutaneously. In some embodiments, the method comprises depressing the puncture mechanism. In some embodiments, the immunogenic composition (e.g. vaccine) comprises a virus comprising a nucleic acid sequence encoding a mutant M2 protein that is expressed or a mutant M2 protein that is not expressed; wherein the expressed mutant M2 protein comprises, or consists of, the amino acid sequence of SEQ ID NO: 4. In some embodiments, the microneedle array is initially positioned inside of a device housing, and upon actuation of a lever allows the microneedles to extend through the device bottom and insert into the skin thereby allowing infusion of the vaccine fluid into the skin.
The delivery device described herein may be utilized to deliver any substance that may be desired. In one embodiment, the substance to be delivered is a drug, and the delivery device is a drug delivery device configured to deliver the drug to a subject. As used herein the term “drug” is intended to include any substance delivered to a subject for any therapeutic, preventative or medicinal purpose (e.g., vaccines, pharmaceuticals, nutrients, nutraceuticals, etc.). In one such embodiment, the drug delivery device is a vaccine delivery device configured to deliver a dose of vaccine to a subject. In one embodiment, the delivery device is configured to deliver a flu vaccine. The embodiments discussed herein relate primarily to a device configured to deliver a substance transcutaneously. In some embodiments, the device may be configured to deliver a substance directly to an organ other than the skin.
While the following examples are demonstrated with influenza A, it is understood that the mutations and methods described herein are equally applicable to other viruses which express an M2, an M2-like protein or a protein with the same or similar function as the influenza A M2 protein.
M2 mutants were constructed as follows.
Partial wild-type M genes from PR8 were amplified by PCR using oligo set 1 and oligo set 2 as shown below.
The PCR products were then digested with BsmBI. An expression vector (pHH21) was also digested with BsmBI, and the digested PCR products were ligated into the vector using T4 DNA ligase. E. coli cells were transformed with the vector, and after appropriate incubation, vectors were isolated and purified by methods known in the art. The mutant M2 portion of the vector was characterized by nucleic acid sequencing.
Partial wild-type M genes from PR8 were amplified by PCR using the primer set shown below.
The PCR products were then digested with BsmBI. An expression vector (pHH21) was also digested with BsmBI. A double-stranded DNA fragment was then made by annealing the two nucleotides shown below.
The digested vector, PCR product and double-stranded fragment were then ligated using T4 DNA ligase. E. coli cells were transformed with the vector, and after appropriate incubation, the vectors were isolated and purified by methods known in the art. The mutant M2 portion of the vector was characterized by nucleic acid sequencing.
The partial M2-1 mutant (M2 ectodomain+2 stop codons+TM deletion (PR8 M segment+2 stops (786-791) without 792-842 (TM)) was amplified from PR8 by PCR using the following primers:
The PCR products were then digested with BsmBI. An expression vector (pHH21) was also digested with BsmBI. A double-stranded DNA fragment was then made by annealing the two nucleotides shown below.
The digested vector, PCR product and double-stranded fragment were then ligated using T4 DNA ligase. E. coli cells were transformed with the vector, and after appropriate incubation, the vectors were isolated and purified by methods known in the art. The mutant M2 portion of the vector was characterized by nucleic acid sequencing.
The sequence of each of the three M2 mutant constructs is provided in Tables 1-3.
This example demonstrates the culturing of the PR8 virus comprising the M2KO(ΔTM) (SEQ ID NO:1) mutation. Mutant viruses were generated as reported in Neumann et al., Generation of influenza A viruses entirely from clone cDNAs, Proc. Natl. Acad. Sci. USA 96:9345-9350 (1999), with some modifications. Briefly, 293T cells were transfected with 17 plasmids: 8 Poll constructs for 8 RNA segments, one of which harbors the mutant M2 sequence, and 9 protein-expression constructs for 5 structural proteins as follows: NP (pCAGGS-WSN-NP0/14); M2 (pEP24c); PB1 (pcDNA774); PB2 (pcDNA762); and PA (pcDNA787) of A/Puerto Rico/8/34 (H1N1) virus.
The plasmids were mixed with transfection reagent (2 μL of Trans IT® LT-1 (Mirus, Madison, Wis.) per μg of DNA), incubated at room temperature for 15-30 minutes, and added to 1×106 293 T cells. Forty-eight hours later, viruses in the supernatant were serially diluted and inoculated into M2CK cells. Two to four days after inoculation, viruses in supernatant of the last dilution well in which cells showing clear cytopathic effect (CPE) were inoculated into M2CK cells for the production of stock virus. The M genes of generated viruses were sequenced to confirm the gene and the presence of the intended mutations and to ensure that no unwanted mutations were present.
Mutant M2 viruses were grown and passaged as follows. M2CK host cells were grown in the presence of MEM supplemented with 10% fetal calf serum. Cells were infected at an MOI of 0.001 by washing with PBS followed by adsorbing virus at 37° C. Virus growth media containing trypsin/TPCK was added and the cells were incubated for 2-3 days until cytopathic effect was observed.
Growth kinetics of the PR8 virus with the M2KO(ΔTM) (SEQ ID NO:1) mutation and wild-type PR8 were analyzed in both normal MDCK cells and MDCK cells stably expressing M2 protein (M2CK). Cells were infected with viruses at multiplicity of infection of 10−5. Virus titers in cell supernatant were determined in MDCK or M2CK cells. Wild-type PR8 grew to high titers in both cell types whereas M2KO grew well only in M2CK cells and not at all in MDCK cells (
This example demonstrates that the PR8 virus with the M2KO(ΔTM) (SEQ ID NO:1) mutation produces viral antigens, but not M2 protein, in normal cells. Viral protein expression was evaluated by infecting wild-type MDCK cells with wild-type PR8 or M2KO at a multiplicity of infection (MOI) of 0.5 in medium without trypsin to ensure that viruses complete only one life cycle. Viral proteins in the cell lysates were separated on a 4-12% SDS-PAGE gel and detected by Western blot using PR8 infected mouse sera (Panel A) or anti-M2 monoclonal antibody (14C2, Santa Cruz Biotechnology) (Panel B).
An experiment was performed to demonstrate that M2 mutant viruses are attenuated in vivo. Six weeks old BALB/c, female mice (23 per group) were inoculated intranasally with one of the following mutants: M2KO(yk) as described in J. Virol (2009) 83:5947-5950; M2-1 (TM del M2KO aka M2KO(ΔTM)) and M2-2 (Splice def M2KO) (collectively termed “M2KO variants”). The mutant was administered at a dose of 1.2×104 pfu per mouse. A control group of mice was given PBS. The mice were observed for 14 days after inoculation for any change in body weight and symptoms of infection. Additionally, after 3 days post-inoculation, virus titers were taken from the lungs and nasal turbinates (NT) from 3 mice in each group.
As shown in
Testing was also performed to determine antibody titers from the mice described in Example 5 above and their survival after being challenged with a lethal viral dose. Serum samples were taken 3 weeks after inoculation and anti-virus IgG antibody titers from the serum samples were determined by enzyme-linked immunosorbent assay (ELISA). The humoral response is shown in
In addition, half of the mice within each of the groups were boosted 28 days after inoculation with same amount of M2 mutant virus. Serum was then collected 6 weeks after the first inoculation and IgG titers against the virus were determined. As shown in
49 days after the first inoculation (3 weeks after the boost), the mice were challenged with a lethal dose of PR8 virus (40 mouse 50% lethal dose (MLD50)). As shown in
In another experiment, six weeks after immunization, the M2KO(ΔTM) groups were challenged with homosubtypic or heterosubtypic influenza viruses. Mice were challenged with Aichi (H3N2) virus and scored for survival for 14 days. Results for the heterotypic challenge are shown in
An experiment was performed to show that intradermal vaccine delivery/immunizing will protect a subject from influenza. BALB/c female, 6-7 weeks old mice (5 per group) (Harland Laboratories) were inoculated either intranasally (IN), intramuscularly (IM) or intradermally (ID) with PR8 virus (3.5×107 pfu) at a concentration of 1.8×101, 1.8×102, 1.8×103 or 1.8×104 pfu (50 μl) per mouse. Control mice were also given PBS through the three different routes of administration. Body weight and survival were monitored for 14 days after inoculation. For the mouse experiments, allergy syringes with intradermal bevel needles were used.
Most vaccines are administered by intramuscular or subcutaneous injection using conventional needles and syringes. However, recent studies demonstrate that intradermal vaccine delivery achieves better immunogenicity than intramuscular or subcutaneous administration. Intradermal vaccination delivers antigen directly to the enriched skin immune system and has been shown to be effective for a range of vaccines, including rabies, hepatitis B and influenza. Intradermal delivery may also provide dose sparing, achieving the same immune response using less vaccine than required with intramuscular injection. The current state-of-the-art for intradermal delivery (using conventional needles and syringes) is the Mantoux technique, which requires extensive training, is difficult to perform, and often results in misdirected (subcutaneous) or incomplete administration. The lack of suitable delivery devices has hampered intradermal vaccination research and product development even though superior immune responses with this administration route have been documented.
As shown in Table 12, IN-inoculated mice succumbed to influenza infection at the higher doses of 1.8×103 and 1.8×104 pfu per mouse, with complete survival only at the lowest dose of 1.8×101. However, IM- and ID-inoculated mice at all dosages survived. Table 13 shows the median lethal dose for mice in the IN-inoculated group (MLD50).
apfu: plaque forming unit.
Serum was collected at 2 weeks (
In another experiment, groups of IN-, IM- and ID-inoculated mice (5 mice per group, except for 4 mice in 1.8×103 group) were challenged 8 week after vaccination. Specifically, 1.8×101 IN-inoculated mice, 1.8×103 IM-inoculated mice, 1.8×104 IM-inoculated mice, 1.8×103 ID-inoculated mice and 1.8×104 ID-inoculated mice were challenged. Mice that lost more than 25% of their body weight were euthanized.
As shown in
An evaluation of the ID-inoculated mice (1.8×104) showed that two mice (1 and 5 in
To test the stability of M2 gene of M2KO variants in wild-type cells, the M2KO variants were passaged in wild-type MDCK cells, which lacks M2 protein expression, along with M2CK cells which are M2 protein expressing MDCK cells. All M2KO variants were passageable in M2CK cells without any mutations until at least passage 10. Although, M2-1 (TM del M2KO), M2-2 (Splice def M2KO), and M2-3 (TM del+Splice def M2KO) were not able to be passaged in wild-type MDCK cells (no cytopathic effect (CPE) is seen in wild-type MDCK cells), M2KO(yk) showed CPE even after 4th passage in MDCK cells. M segment RNAs were extracted from M2KO(yk) passage 4 in wild-type MDCK and the cDNA were sequenced. As shown in Table 14, two inserted stop codons of M2KO(yk) were edited and M2KO(yk) passage 4 in wild-type MDCK possessed full length M2 protein gene.
To demonstrate that the M2KO vaccine can stimulate an immune response similar to a natural influenza infection, a vaccine experiment was conducted. Natural influenza infection was represented by a low inoculum of PR8 virus and the standard inactivated flu vaccine was represented by inactivated PR8 virus (Charles River) delivered the standard intramuscular route and intranasally.
Six to seven week old BALB/c mice were immunized intranasally with live virus (10 pfu PR8), PR8 virus comprising M2KO(ΔTM) (104 pfu), or 1 μg inactivated PR8 virus, delivered both intranasally and intramuscularly. Mice given 104 infectious particles of M2KO(ΔTM) intranasally lost no weight and showed no signs of infection. Furthermore, the lungs of mice treated with M2KO(ΔTM) contained no detectable infectious particles three days post-inoculation. Sera was obtained from the immunized mice on day 21 and antibody titers against the hemagglutinin were determined by a standard ELISA assay.
Six weeks after immunization, all groups were challenged with homosubtypic (PR8, H1N1) or heterosubtypic (Aichi, H3N2) influenza viruses. Both M2KO and inactivated vaccinations protected mice from homosubtypic virus infection (
Summary—This example demonstrates that the M2KO(ΔTM) virus does not replicate in the respiratory tract or disseminate to other organs in the ferret model. The M2KO(ΔTM) virus was administered intranasally to 3 male ferrets at a dose level of 1×107 TCID50. As a control, second group of 3 male ferrets was administered A/Brisbane/10/2007 (H3N2) influenza A virus intranasally at a dose of 1×107 TCID50. Following virus inoculation, ferrets were observed until Day 3 post inoculation for mortality, with body weights, body temperatures and clinical signs measured daily. Necropsy was performed on all animals 3 days post inoculation. Organs were collected for histopathology and viral titers.
The control group receiving A/Brisbane/10/2007 (H3N2) exhibited a transient reduction in weight and an increase in body temperature 2 days after inoculation which was not observed in the M2KO(ΔTM) group. Activity levels were also reduced in the A/Brisbane/10/2007 group with sneezing observed on days 2-3 post infection. No changes in activity level or clinical signs associated with virus exposure were observed in the M2KO(ΔTM) group. Histopathological analysis revealed changes in the nasal turbinates in animals exposed to influenza A/Brisbane/10/2007 (H3N2) that were not seen in ferrets exposed to the M2KO(ΔTM) virus. Exposure to A/Brisbane/10/2007 resulted in atrophy of respiratory epithelium, infiltrates of neutrophils and edema in the nasal turbinates. No other organ was affected by the virus inoculation. Under the conditions of the experiment, the M2KO(ΔTM) virus did not induce clinical signs of infection or result in histological changes in the organs analyzed.
Materials and Methods
A. Vaccine Material and Control Virus: The M2KO(ΔTM) virus is a recombinant virus which possesses internal 6 genes of PR8 (nucleoprotein (NP), polymerase genes (PA, PB1, PB2), non-structural (NS), matrix (M)), but which does not express functional M2 protein, as well as HA and NA genes of Influenza A/Brisbane/10/2007-like A/Uruguay/716/2007(H3N2). The A/Brisbane/10/2007 (H3N2) wild type virus served as the control virus and was supplied by IITRI. The viruses were kept frozen at −65° C. until used.
B. Test Article and Positive Control Dose Formulation: The M2KO(ΔTM) virus dosing solution of 1×107 TCID50/mL per 316 μL was prepared by diluting 8 μL of 1×1010 TCID50/mL into 2.528 mL PBS. The A/Brisbane/10/2007 (H3N2) at a titer of 1×107 TCID50/mL per 316 was used undiluted.
C. Animals and Animal Care: Eight male ferrets were purchased from Triple F Farms and six of the ferrets were placed on study. Animals were approximately 4 months of age at the time of study initiation. The animals were certified by the supplier to be healthy and free of antibodies to infectious diseases. Upon arrival the animals were single housed in suspended wire cages with slat bottoms, suspended over paper-lined waste pans. The animal room and cages had been cleaned and sanitized prior to animal receipt, in accordance with accepted animal care practices and relevant standard operating procedures. Certified Teklad Global Ferret Diet #2072 (Teklad Diets, Madison Wis.) and city of Chicago tap water were provided ad libitum and were refreshed at least once daily. Fluorescent lighting in the animal rooms was maintained on a 12-hr light/dark cycle. Animal room temperature and relative humidity were within respective protocol limits and ranged from 22.0 to 25.0° C. and 33 to 56%, respectively, during the study.
D. Animal Quarantine and Randomization: The ferrets were held in quarantine for five days prior to randomization and observed daily. Based on daily observations indicating general good health of the animals the ferrets were released from quarantine for randomization and testing. Following quarantine, ferrets were weighed and assigned to treatment groups using a computerized randomization procedure based on body weights that produced similar group mean values [ToxData® version 2.1.E.11 (PDS Pathology Data Systems, Inc., Basel, Switzerland)]. Within a group, all body weights were within 20% of their mean. Animals selected for the study receive a permanent identification number by ear tag and transponder and individual cage cards also identified the study animals by individual numbers and group. The identifying numbers assigned were unique within the study.
E. Experimental Design: All animal procedures were performed in an animal biosafety level-2 facility in accordance with the protocols approved by the animal care and use committee at IIT Research Institute. 6 male ferrets (Triple F Farms, Sayre Pa.), 4 months of age at the time of study initiation were utilized for the study. Prior to infection, ferrets were monitored for 3 days to measure body weight and establish baseline body temperatures. Temperature readings were recorded daily through a transponder (BioMedic data systems, Seaford, Del.) implanted subcutaneously in each ferret. Blood was collected prior to study initiation via the jugular vein, and serum tested for influenza antibodies. Study animals free of influenza antibodies were randomized and divided into two groups (3 ferrets/group) as shown in Table 15. A group of 3 ferrets was anesthetized and inoculated intranasally with a single dose of 316 μL at 1×107 TCID50 of M2KO(ΔTM) virus. A control group (3 ferrets) was inoculated with 316 μL at 1×107 TCID50 of A/Brisbane/10/2007 (H3N2). Ferrets were observed daily to monitor body weight, body temperature and clinical symptoms. On Day 3 post-inoculation, ferrets (3 ferrets per group) were euthanized and necropsied. The following tissue samples were collected: nasal turbinates, trachea, lungs, kidneys, pancreas, olfactory bulbs, brains, livers, spleens, small and large intestines. One part of the collected samples was fixed with buffered neutral formalin for histological evaluation and the other part of the samples were stored at −65° C. for virus titration.
F. Virus Inoculation: Ferrets were inoculated with either the M2KO(ΔTM) virus or wild type A/Brisbane/10/2007 (H3N2) influenza A virus. A vial of frozen stock was thawed and diluted to the appropriate concentration in phosphate buffered saline solution. Ferrets were anesthetized with ketamine/xylazine and the virus dose administered intranasally in a volume of 316 μL for the M2KO(ΔTM) virus and 316 μL for the A/Brisbane/10/2007 (H3N2) virus. To confirm the inoculation titer of the A/Brisbane/10/2007 (H3N2) virus, a TCID50 assay was performed at IITRI on a portion of the prepared viral challenge solution. The viral titer assay was performed according to Illinois Institute of Technology Research Institute (IITRI) Standard Operating Procedures.
G. Moribundity/Mortality Observations: Following challenge, all animals were observed twice daily for mortality or evidence of moribundity. Animals were observed for 3 days post-challenge. Animals were euthanized by overdose with Sodium Pentobarbital 150 mg/kg, administered intravenously.
H. Body Weights and Body Weight Change: Body weights of animals were recorded upon receipt (random 10% sample), at randomization (Day −3 to 0), and daily after virus inoculation.
I. Clinical Observations: The change in temperature (in degrees Celsius) was determined daily for each ferret. Clinical signs of, inappetence, respiratory signs such as dyspnea, sneezing, coughing, and rhinorrhea and level of activity was assessed daily. A scoring system based on that described by Reuman, et al., “Assessment of signs of influenza illness in the ferret model,” J. Virol, Methods 24:27-34 (1989), was used to assess the activity level as follows: 0, alert and playful; 1, alert but playful only when stimulated; 2, alert but not playful when stimulated; and 3, neither alert nor playful when stimulated. A relative inactivity index (RII) was calculated as the mean score per group of ferrets per observation (day) over the duration of the study.
J. Euthanasia: Study animals were euthanized by an intravenous dose of sodium pentobarbital 150 mg/kg. Death was confirmed by absence of observable heartbeat and respiration. Necropsies were performed on all study animals.
K. Necropsy: Nasal turbinates, trachea, lungs, kidneys, pancreas, olfactory bulbs, brain, liver, spleen, small and large intestines were harvested. One portion of each tissue was fixed in formalin and the other portion given to IITRI staff for freezing and storage. Tissue harvested for titers are: right nasal turbinates, upper 1/3 of trachea, right cranial lung lobe, right kidney, right arm of pancreas (near duodenum), right olfactory bulb, right brain, right lateral lobe of liver, right half of spleen (end of spleen seen on opening the abdominal cavity), small intestine and large intestine.
L. Histopathological analysis: Tissues were processed through to paraffin blocks, sectioned at approximately 5-microns thickness, and stained with hematoxylin and eosin (H & E).
M. Serum Collection: Pre-vaccination (Day −3) serum was collected from all ferrets. Ferrets were anesthetized with a ketamine (25 mg/kg) and xylazine (2 mg/kg) mixture. A sample of blood (approximately 0.5-1.0 mL) was collected via the vena cava from each ferret and processed for serum. Blood was collected into Serum Gel Z/1.1 tubes (Sarstedt Inc. Newton, N.C.) and stored at room temperature for not more than 1 hour before collecting serum. Serum Gel Z/1.1 tubes were centrifuged at 10,000×g for 3 minutes and the serum collected. Individual pre-inoculation serum samples were collected and two aliquots made from each sample. One aliquot was tested prior to the initiation of the study to confirm ferrets are free of antibodies to influenza A viruses and one aliquot of the serum stored at −65° C.
N. Hemagglutination Inhibition (HI) Assay: Serum samples were treated with receptor-destroying enzyme (RDE) (Denka Seiken, Tokyo, Japan) to eliminate inhibitors of nonspecific hemagglutination. RDE was reconstituted per the manufacturer's instructions. Serum was diluted 1:3 in RDE and incubated 18-20 hours in a 37° C.±2° C. water bath. After the addition of an equal volume of 2.5% (v/v) sodium citrate, the samples were incubated in a 56±2° C. water bath for 30±5 minutes. 0.85% NaCl was added to each sample to a final serum dilution of 1:10 after the RDE treatment. The diluted samples were then diluted into four two-fold dilutions (1:10 to 1:80) in duplicate in phosphate buffered saline (PBS) then incubated with 4 hemagglutinating units of A/Brisbane/10/2007 (H3N2) influenza A virus. After incubation, 0.5% chicken red blood cells were added to each sample and incubated. Presence or absence of hemagglutination was then scored.
O. Virus Titers: The concentration of infectious virus in the pre- and post-challenge virus inoculum samples was determined by TCID50 in Madin-Darby Canine Kidney (MDCK) cells. Briefly, samples kept at −65° C. were thawed and centrifuged to remove cellular debris. The resulting supernatant were diluted 10-fold in triplicate in 96-well microtiter plates in Dulbecco's Modified Eagle Medium (DMEM) (Gibco, Carlsbad, Calif., USA) containing Pencillin/Streptomycin, 0.1% Gentamicin, 3% NaCO3, 0.3% BSA fraction V (Sigma St. Louis, Mo.), 1% MEM vitamin solution (Sigma) and 1% L-glutamine (Mediatech, Manassas, Va., USA). After 10-fold serial dilutions were made, 100 L was transferred into respective wells of a 96-well plate which contained a monolayer of MDCK cells. Plates were incubated at 37° C.±2° C. in 5±2% CO2 70% humidity. After 48 hours, the wells were observed for cytopathogenic effect (CPE). Supernatant from each well (50 μl) was transferred to a 96 well plate and the hemagglutination (HA) activity determined and recorded. The HA activity of the supernatant was assessed by HA assay with 0.5% packed turkey red blood cells (cRBCs). TCID50 titers were calculated using the method of Reed LJ and Muench H, “A simple method for estimating 50% endpoints,” Am. J. Hygiene 27: 493-497 (1938).
P. Data Analysis: Body weights and body weight gains (losses) and changes in body temperature were determined for each individual animal expressed as mean and standard deviations of the mean for each test group.
Results
After inoculation with either the M2KO(ΔTM) virus or A/Brisbane/10/2007 (H3N2) influenza A virus, ferrets were monitored for survival and clinical signs of infection. Results are presented in Table 16A and 16B. All ferrets survived infection with M2KO(ΔTM) virus and A/Brisbane/10/2007 (H3N2). Ferrets inoculated with A/Brisbane/10/2007 presented respiratory signs (sneezing) on Day 2 and 3. The relative inactivity index of ferrets inoculated with A/Brisbane/10/2007 was 0.67; whereas ferrets inoculated with M2KO(ΔTM) showed no reduction activity level with a relative inactivity index of 0.0.
Changes in body weight and temperature after virus inoculation are shown in
aHemagglutination inhibition (HI) antibody titers to homologous virus in ferret serum prior to virus inoculation.
bClinical signs were observed for 3 days after virus inoculation. Except for lethargy, findings for clinical signs are given as no. of ferrets with sign/total no. Respiratory signs included sneezing.
cDetermined twice daily for 3 days of observation based on the scoring system and was calculated as the mean score per group of ferrets per observation (day) over the 3-day period. The relative inactivity index before inoculation was 0.
Conclusion
This example shows that by Day 3 post inoculation, the M2KO(ΔTM) virus does not induce clinical signs of disease or histopathological changes associated with infection of wild type virus. This shows that the M2KO(ΔTM) virus of the present technology is useful for intranasal influenza vaccines.
Summary—This example demonstrates the immune response elicited by the M2KO(ΔTM) vaccine and the protective effects of the vaccine in the ferret model. The M2KO(ΔTM) virus was administered intransally to 12 male ferrets at a dose level of 1×107 TCID50. As a control, a second group of 12 male ferrets was administered the FM #6 virus intranasally at a dose of 1×107 TCID50. A third group of ferrets was administered OPTI-MEM™ as a placebo control. A prime only or prime-boost vaccination regimen was utilized for each treatment group. Ferrets receiving the prime-boost vaccination regimen were administered the prime vaccine (Day 0) and the boost vaccination 28 days later (Day 28). Ferrets receiving only the prime vaccine were administered a single vaccination on the same day as the booster vaccine was given to the prime-boost ferrets (Day 28). Following each vaccination, ferrets were observed for 14 days post inoculation for mortality, with body weights, body temperatures and clinical signs measured daily. Nasal washes were collected from ferrets on days 1, 3, 5, 7 and 9 post-prime vaccination to look for viral shedding. Nasal washes and serum were collected weekly from all ferrets post-vaccination to evaluate antibody levels over time.
All animals were challenged intranasally on Day 56 with 1×107 TCID50 of A/Brisbane/10/2007 (H3N2). Following challenge, ferrets were monitored for 14 days post inoculation for mortality, with body weights, body temperatures and clinical signs measured daily. Nasal washes were collected on days 1, 3, 5, 7, 9 and 14 post challenge from ferrets in each group for viral titers. Additionally, serum was collected post-challenge (day 70) from surviving ferrets for analysis. Necropsy was performed on 3 ferrets per group 3 days post challenge. Organs were collected for histopathology and viral titers.
No vaccine related adverse events were observed among the 5 groups. After challenge, the placebo control group exhibited an increase in body temperature 2 days after challenge and a reduction in weight. A reduction in weight was also observed in M2KO(ΔTM) and FM #6 vaccinated groups; however, the reduction was to less than that observed in the OPTI-MEM™ group. Activity levels were not reduced in any groups; however sneezing was observed in all groups after challenge. Histopathological analysis revealed an increase in severity of mixed cell infiltrates in the lung of vaccinated ferrets when compared to the lung infiltrates in the OPTI-MEM™ control group. In the nasal turbinates, animals receiving a prime or prime plus boost regimen of either M2KO(ΔTM) or FM #6 had lower severity of atrophy of respiratory epithelium when compared to the OPTI-MEM™ control group. Vaccination with the M2KO(ΔTM) virus appeared to provides similar protection against viral challenge as the FM #6 virus.
Materials and Methods
A. Vaccine Material: The M2KO(ΔTM) virus is a recombinant virus which possesses internal 6 genes of PR8 (nucleoprotein (NP), polymerase genes (PA, PB1, PB2), non-structural (NS), matrix (M)), but which does not express functional M2 protein, as well as HA and NA genes of Influenza A/Brisbane/10/2007-like A/Uruguay/716/2007(H3N2). The FM #6 virus is clone #6 of the A/Uruguay/716/2007 (H3N2) influenza A virus from FluMist® (2009-2010 formula). The M2KO(ΔTM) virus and FM #6 virus were administered intranasally to the animals in a 316 μL dose of 1×107 TCID50 (50% Tissue Culture Infectious Doses).
B. Test Article and Positive Control Dose Formulation: The M2KO(ΔTM) virus dosing solution of 1×107 TCID50/mL per 316 μL was prepared by diluting 120 μL of 1×109 TCID50/mL into 3.680 mL PBS. The FM #6 virus at a titer of 1×107 TCID50/mL per 316 μL was prepared by diluting 120 μL of 1×109 TCID50/mL into 3.680 mL PBS.
C. Animals and Animal Care: Thirty-six male ferrets were purchased from Triple F Farms and 30 of the ferrets were placed on study. Animals were approximately 4 months of age at the time of study initiation. The animals were certified by the supplier to be healthy and free of antibodies to infectious diseases. Upon arrival the animals were single housed in suspended wire cages with slat bottoms, suspended over paper-lined waste pans. The animal room and cages had been cleaned and sanitized prior to animal receipt, in accordance with accepted animal care practices and relevant standard operating procedures. Certified Teklad Global Ferret Diet #2072 (Teklad Diets, Madison Wis.) and city of Chicago tap water were provided ad libitum and were refreshed at least three time per week. Fluorescent lighting in the animal rooms was maintained on a 12-hr light/dark cycle. Animal room temperature and relative humidity were within respective protocol limits and ranged from 20.0 to 25.0° C. and 30 to 63%, respectively, during the study.
D. Animal Quarantine and Randomization: The ferrets were held in quarantine for seven days prior to randomization and observed daily. Based on daily observations indicating general good health of the animals the ferrets were released from quarantine for randomization and testing. Following quarantine, ferrets were weighed and assigned to treatment groups using a computerized randomization procedure based on body weights that produced similar group mean values [ToxData® version 2.1.E.11 (PDS Pathology Data Systems, Inc., Basel, Switzerland)]. Within a group, all body weights were within 20% of their mean. Animals selected for the study receive a permanent identification number by ear tag and transponder and individual cage cards also identified the study animals by individual numbers and group. The identifying numbers assigned were unique within the study.
E. Experimental Design: To assess the M2KO(ΔTM) vaccine efficacy, ferrets were immunized with M2KO(ΔTM) virus, cold adapted live attenuated virus (FM #6) or mock immunized by medium (OPTI-MEM™). The animals body weight, body temperature and clinical symptoms were monitored and immunological responses evaluated. 30 male ferrets (Triple F Farms, Sayre Pa.), 4 months of age at the time of study initiation were utilized for the study. All animal procedures were performed in an animal biosafety level-2 or biosafety level-3 facility in accordance with the protocols approved by the animal care and use committee at IIT Research Institute. Prior to inoculation, ferrets were monitored for 3 days to measure body weight and establish baseline body temperatures. Temperature readings were recorded daily through a transponder (BioMedic data systems, Seaford, Del.) implanted subcutaneously in each ferret. Blood was collected prior to study initiation, and serum tested for influenza antibodies. Only ferrets with HAI (hemagglutination inhibition) titers 40 to A/Brisbane/10/2007 (H3N2) were considered seronegative and used in this study. Study animals were randomized and divided into 5 groups (6 ferrets/group) as shown in Table 17. Two groups (1 & 3) received the M2KO(ΔTM) virus and 2 groups (2 & 4) received the FM #6 virus. One group (5) was mock immunized with OPTI-MEM™. Within each vaccine group, ferrets were divided into two vaccine regimens, six receiving a prime vaccination only (Prime only) and six receiving a prime vaccination followed by a booster vaccine 28 days after prime vaccination (Prime/Boost). Prime/Boost Groups: Ferrets were inoculated intranasally with a single dose of 316 μL of 1×107 TCID50 of M2KO(ΔTM) virus on days 0 and 28. Control groups were inoculated intranasally with 316 μL of 1×107 TCID50 (same dose as M2KO(ΔTM)) of FM #6 or mock inoculated with 316 μL of OPTI-MEM™ on days 0 and 28. Ferret body temperatures, weights, and clinical symptoms were monitored daily for 14 days post-inoculations. Nasal washes were collected from all ferrets, including OPTI-MEM™ control group, on days 1, 3, 5, 7, 9 and 14 post prime vaccination for virus titration in cells and on days 21 and 49 for antibody titration. Nasal wash samples were kept at −65° C. Blood was collected prior to inoculation (day −3 to −5) and days 7, 14, 21 35, 42, and 49 and serum kept at −65° C. until measurement of antibody titer by ELISA and HI assay.
Prime only Groups: Ferrets were inoculated intranasally with a single dose of 316 μL of 1×107 TCID50 of M2KO(ΔTM) virus on day 28. Control groups were inoculated intranasally with 316 μL of 1×107 TCID50 (same dose as M2KO(ΔTM)) of FM #6 or mock inoculated with 316 μL of OPTI-MEM™ on day 28. Ferret body temperatures, weights, and clinical symptoms were monitored daily for 14 days post-inoculation. Nasal washes were collected from all ferrets on days 29, 31, 33, 35, 37, and 42 for virus titration in cells and on day 49 for antibody titration. Nasal wash samples were kept at −65° C. Blood was collected prior to inoculation (day 23 to 25) and days 35, 42, and 49 and serum was kept at −65° C. until measurement of antibody titer by ELISA and HAI assay. All ferrets were challenged with a dose of 316 μL of 1×107 TCID50 of wild-type A/Brisbane/10/2007 (H3N2) influenza virus on day 56, 4 weeks after the prime/boost vaccine was administered. Ferret body weight, body temperature and clinical symptoms were monitored for 14 days after challenge and nasal washes and organs collected. Nasal washes were collected from challenged ferrets on days 1, 3, 5, 7, 9, and 14 post-challenge (days 57, 59, 61, 63, 65, and 70) and the samples kept at −65° C. for virus titration in cells. On Day 3 post-challenge (day 59), the animals (3 animals per group, total 15 animals) were euthanized and the following tissue samples collected: nasal turbinates, trachea, and lungs. One part of the collected samples was fixed with buffered neutral formalin for histological evaluation and the other part of the samples was stored at −65° C. for virus titration. Blood was collected 14 days post-challenge (day 70) and all surviving animals were euthanized.
1Intranasally inoculated with a dose of 1 × 107 TCID50
2Nasal Washes only collected from animals after prime vaccination.
3Organs (nasal turbinated, trachea and lung) collected from 3 ferrets per group for histology and viral titers.
F. Virus Inoculation: Ferrets were inoculated with either the M2KO(ΔTM) virus or FM #6 influenza A virus. A vial of frozen stock was thawed and diluted to the appropriate concentration in phosphate buffered saline solution. Ferrets were anesthetized with ketamine/xylazine and the virus dose administered intranasally in a volume of 316 μL for the M2KO(ΔTM) virus and 316 μL for the FM #6 virus. To confirm the inoculation titer of the M2KO(ΔTM) and FM #6 viruses, aliquots of the dosing solutions were collected prior to dosing (pre-dose) and after dosing (post-dose). The aliquots were stored at −65° C. for virus titration.
G. Challenge Virus: Influenza A virus, strain A/Brisbane/10/2007, serotype H3N2 was used to challenge the ferrets. The virus was stored at approximately −65° C. prior to use. The dose level of challenge virus used was prepared at 1×107 TCID50 in a volume of 316 μL. A quantitative viral infectivity assay, TCID50 assay was performed at IITRI on a portion of the prepared viral challenge solution. The viral titer assay was performed according to IITRI Standard Operating Procedures.
H. Moribundity/Mortality Observations: Following challenge, all animals were observed twice daily for mortality or evidence of moribundity. Animals were observed for 14 days after vaccine inoculation and for 14 days after challenge.
I. Body Weights and Body Weight Change: Body weights were recorded within two days of receipt and at randomization. All study animals were weighed prior to inoculation, daily for 14 days following each vaccination and assessed daily for 14 days post challenge. Prior to inoculation, ferrets were monitored for 3-5 days to measure establish baseline body temperatures. Temperature readings were recorded daily for 14 days following each vaccination and recorded daily for 14 days post challenge through a transponder (BioMedic data systems, Seaford, Del.) implanted subcutaneously in each ferret. The change in temperature (in degrees Celsius) was calculated at each time point for each animal.
J. Clinical Observations: The change in temperature (in degrees Celsius) was determined daily for each ferret. Clinical signs of, inappetence, respiratory signs such as dyspnea, sneezing, coughing, and rhinorrhea and level of activity was assessed daily. A scoring system based on that described by Reuman, et al., “Assessment of signs of influenza illness in the ferret model,” J. Virol, Methods 24:27-34 (1989), was used to assess the activity level as follows: 0, alert and playful; 1, alert but playful only when stimulated; 2, alert but not playful when stimulated; and 3, neither alert nor playful when stimulated. A relative inactivity index (RII) was calculated as the mean score per group of ferrets per observation (day) over the duration of the study.
K. Survival Checks: Two survival checks were performed daily on all study animals throughout the study. Both survival checks occurred simultaneously with the clinical observations. The second check was performed later within the same day.
L. Nasal Washes: Ferrets were anesthetized with a ketamine (25 mg/kg) and xylazine (2 mg/kg) mixture, and 0.5 ml of sterile PBS containing penicillin (100 U/ml), streptomycin (100 μg/ml), and gentamicin (50 μg/ml) was injected into each nostril and collected in a specimen cup when expelled by the ferret. The nasal wash was collected into a cryovial and the recovered volume recorded.
M. Euthanasia: Study animals were euthanized by an intravenous dose of sodium pentobarbital 150 mg/kg. Death was confirmed by absence of observable heartbeat and respiration.
N. Necropsy: Necropsy was performed by Charles River Laboratories, Pathology Associates (PAI). The PAI team was comprised of a supervising pathologist and two prosectors. Nasal turbinates, trachea and lungs were harvested. One portion of each tissue was fixed in formalin and the other portion given to IITRI staff for freezing and storage. Tissue harvested for titers are: right nasal turbinates, upper ⅓ of trachea and right cranial lung lobe.
O. Histopathological analysis: Following each necropsy, tissues were transported to the PAI Chicago facility. Upon receipt, partial tissues from all 15 ferrets were processed through to paraffin blocks, sectioned at approximately 5-microns thickness, and stained with hematoxylin and eosin (H & E). All paraffin H & E slides were evaluated microscopically.
P. Serum Collection: Pre-vaccination serum (days −3 to −5 for groups 3, 4, and 5, and days 23 to 25 for groups 1 and 2) serum was collected from the ferrets. Post inoculation, serum was collected on days 7, 14, 21, 35, 42, 49, and 70 from groups 3, 4, and 5. Serum was collected on days 35, 42, 49, and 70 from groups 1 and 2. Ferrets were anesthetized with a ketamine (25 mg/kg) and xylazine (2 mg/kg) mixture. A sample of blood (approximately 0.5-1.0 mL) was collected via the vena cava from each ferret and processed for serum. Blood was collected into Serum Gel Z/1.1 tubes (Sarstedt Inc. Newton, N.C.) and stored at room temperature for not more than 1 hour before collecting serum. Serum Gel Z/1.1 tubes were centrifuged at 10,000×g for 3 minutes and the serum collected.
Q. Hemagglutination Inhibition (HI) Assay: Serum samples were treated with receptor-destroying enzyme (RDE) (Denka Seiken, Tokyo, Japan) to eliminate inhibitors of nonspecific hemagglutination. RDE was reconstituted per the manufacturer's instructions. Serum was diluted 1:3 in RDE and incubated 18-20 hours in a 37° C.±2° C. water bath. After the addition of an equal volume of 2.5% (v/v) sodium citrate, the samples were incubated in a 56±2° C. water bath for 30±5 minutes. 0.85% NaCl was added to each sample to a final serum dilution of 1:10 after the RDE treatment. The diluted samples were then diluted into four two-fold dilutions (1:10 to 1:80) in duplicate in phosphate buffered saline (PBS) then incubated with 4 hemagglutinating units of A/Brisbane/10/2007 (H3N2) influenza A virus. After incubation, 0.5% avian red blood cells were added to each sample and incubated for 30±5 minutes. Presence or absence of hemagglutination was then scored.
R. Virus Titers: The concentration of infectious virus in the pre- and post-challenge virus inoculum samples was determined by TCID50 assay in Madin-Darby Canine Kidney (MDCK) cells. Briefly, samples kept at −65° C. were thawed and centrifuged to remove cellular debris. The resulting supernatant were diluted 10-fold in triplicate in 96-well microtiter plates in Dulbecco's Modified Eagle Medium (DMEM) (Gibco, Carlsbad, Calif., USA) containing Pencillin/Streptomycin, 0.1% Gentamicin, 3% NaCO3, 0.3% BSA fraction V (Sigma St. Louis, Mo.), 1% MEM vitamin solution (Sigma) and 1% L-glutamine (Mediatech, Manassas, Va., USA). After 10-fold serial dilutions were made, 100 μL was transferred into respective wells of a 96-well plate which contained a monolayer of MDCK cells. Plates were incubated at 37° C.±2° C. in 5±2% CO2 70% humidity. After 48 hours, the wells were observed for cytopathogenic effect (CPE). Supernatant from each well (50 μl) was transferred to a 96 well plate and the hemagglutination (HA) activity determined and recorded. The HA activity of the supernatant was assessed by HA assay with 0.5% packed turkey red blood cells (tRBCs). TCID50 titers were calculated using the method of Reed LJ and Muench H, “A simple method for estimating 50% endpoints,” Am. J. Hygiene 27: 493-497 (1938).
S. Data Analysis: Body weights and body weight gains (losses) and changes in body temperature were determined for each individual animal expressed as mean and standard deviations of the mean for each test group.
Results
After intranasal vaccination with either the M2KO(ΔTM) virus or the FM #6 virus, ferrets were monitored daily for clinical signs of infection. Nasal washes were collected after prime vaccination to monitor viral shedding and serum collected to measure serum antibody titers. Results are presented in Tables 18A, 18B, and 18C.
aHemagglutination inhibition (HI) antibody titers to homologous virus in ferret serum prior to virus inoculation.
bClinical signs were observed for 3 days after virus inoculation. Except for lethargy, findings for clinical signs are given as no. of ferrets with sign/total no. Respiratory signs included sneezing.
cDetermined twice daily for 3 days of observation based on the scoring system and was calculated as the mean score per group of ferrets per observation (day) over the 3-day period. The relative inactivity index before inoculation was 0.
All ferrets survived vaccination with M2KO(ΔTM) virus and FM #6 virus. After prime vaccination, two ferrets inoculated with M2KO(ΔTM) virus presented respiratory signs (sneezing) on Day 8. After boost vaccination, ferrets inoculated with the FM #6 virus presented respiratory signs (sneezing) 7 days post vaccination. Sneezing was also observed in the OPTI-MEM™ ferrets on day 4 post boost. After prime vaccination, the relative inactivity index of ferrets inoculated with M2KO(ΔTM) virus and FM #6 virus was 0.07 and 0.27, respectively. This reduction in activity was only observed in one group per virus after prime vaccination. After boost vaccination no reduction in activity level was observed. Changes in body weight and temperature after virus inoculation are shown in
a Clinical signs were observed for 3 days after virus inoculation. Except for lethargy, findings for clinical signs are given as no. of ferrets with sign/total no. Respiratory signs included sneezing.
bDetermined twice daily for 3 days of observation based on the scoring system and was calculated as the mean score per group of ferrets per observation (day) over the 3-day period. The relative inactivity index before inoculation was 0.
After challenge with A/Brisbne/10/2007 (H3N2), a 2-4% loss of body weight was observed on Day 2 post challenge in all animals. Throughout the 14 day observation period animal body weights remained below their initial weight. OPTI-MEM™ ferrets lost the most weight (8%). Weight loss among vaccinated ferrets was dependent on the vaccine regimen. Ferrets receiving the prime only regimen of M2KO(ΔTM) or FM #6 lost a maximum of 5% and 4% respectively. Ferrets receiving a booster lost a maximum of 3% for the FM #6 group and 2% for the M2KO(ΔTM) group. Elevated body temperatures post challenge were observed on Day 2 in OPTI-MEM™ ferrets and on Day 1 ferrets receiving the prime only regimens of M2KO(ΔTM) or FM #6 (
To determine if the vaccination would prevent replication of challenge virus in the respiratory tract and reduce organ pathology tissues of challenged ferrets were histologically examined on day 3 post inoculation. Changes in the lungs of animals receiving the M2KO(ΔTM) prime only or prime/boost regimen were associated with increase in severity of mixed cell infiltrates in the lung when compared to the OPTI-MEM™ group. Minor differences in lung infiltrate incidences were observed between the M2KO(ΔTM) prime group and the M2KO(ΔTM) prime/boost group. An increase in the severity of mixed cell infiltrates in the lung was also seen in the FM #6 prime group and FM #6 prime/boost group when compared to the OPTI-MEM™ group. A slight increase in severity in lung mixed cell infiltrates was observed in the FM #6 prime/boost group over the FM #6 prime only group. In the nasal turbinates, animals receiving the prime or prime/boost of the M2KO(ΔTM) virus had lower severity of atrophy of respiratory epithelium when compared to the OPTI-MEM™ group. There were no differences in atrophy of the nasal turbinates when comparing prime versus prime/boost M2KO(ΔTM) groups. A slight increase in severity of atrophy of respiratory epithelium in animals receiving the FM #6 prime/boost regimen was observed versus animals FM #6 prime only regimen; the severity of atrophy of respiratory epithelium in all FM #6 animals was lower than that seen in the OPTI-MEM™ group. There was a decrease in incidence of neutrophilic infiltrates into the nasal cavity (lumen) in the M2KO(ΔTM) prime and prime/boost groups compared to the OPTI-MEM™ group. Neutrophilic luminal infiltrates in the M2KO(ΔTM) prime only group was interpreted as not different from the OPTI-MEM™ group. There was a slight increase in severity of luminal neutrophilic infiltrates in the FM #6 prime only and prime/boost groups when compared to the OPTI-MEM™ group. The concentrations of pre- and post-challenge virus dosing solutions were 1070.83 TCID50/mL and 1070.25 TCID50/mL, respectively, indicating good stability of the challenge material throughout administration.
Conclusion
This example shows that intranasal administration of the M2KO(ΔTM) virus was not associated with any vaccine related adverse events (elevated body temperature, loss of weight or clinical signs). These results show that the M2KO(ΔTM) virus of the present technology is useful for use in an intranasal influenza vaccine.
Summary—This example demonstrates that the M2KO(ΔTM) virus is not transmitted in the ferret model. The M2KO(ΔTM) virus was administered intransally to 3 female ferrets at a dose level of 1×107 TCID50. As a control, a second group of 3 female ferrets was administered the A/Brisbane/10/2007 (H3N2) virus intranasally at a dose of 1×107 TCID50. Twenty four hours after inoculation, each donor ferret was introduced into a transmission chamber with two naive ferrets (a direct contact and aerosol contact). Following inoculation, ferrets were observed for 14 days post inoculation for mortality, with body weights, body temperatures and clinical signs measured daily. Nasal washes were collected from all inoculated donor ferrets on days 1, 3, 5, 7, 9 and from all contact (direct and aerosol) ferrets on days 2, 4, 6, 8, 10 to look for viral shedding. Nasal washes and serum were collected from all ferrets at the inoculation of the study (Day 14) to evaluate antibody levels. No clinical signs of infection were observed in the M2KO(ΔTM) group; however, ferrets in the A/Brisbane/1 0/2007 (H3N2) group had weight loss, increased body temperatures and were sneezing. After inoculation with Brisbane/1 0, the donor ferrets exhibited an increase in body temperature 2 days after challenge and a reduction in weight. Activity levels were not reduced in any groups. Ferrets in direct contact with the donor ferrets showed progressive weight gain until day 4 post inoculation. A similar trend was observed in the aerosol contact ferrets beginning on day 6 post inoculation. The loss in body weight in the contact ferrets correlated with an increase in body temperature. Inoculation with the M2KO(ΔTM) virus does not elicit clinical signs of infection in inoculated animals. Spread to contact ferrets is unlikely.
Materials and Methods
A. Vaccine Material: The M2KO(ΔTM) virus is a recombinant virus which possesses internal 6 genes of PR8 (nucleoprotein (NP), polymerase genes (PA, PB1, PB2), non-structural (NS), matrix (M)), but which does not express functional M2 protein, as well as HA and NA genes of Influenza A/Brisbane/10/2007-like A/Uruguay/716/2007(H3N2). M2KO(ΔTM) virus was administered intranasally to the animals in a 316 μL dose of 1×107 TCID50 (50% Tissue Culture Infectious Doses).
B. Test Article Dose Formulation: The M2KO(ΔTM) virus dosing solution of 1×107 TCID50/mL per 316 μL was prepared by diluting 45 of 1×109 TCID50/mL into 1.377 mL PBS.
C. Animals and Animal Care: 22 female ferrets were purchased from Triple F Farms and 18 of the ferrets were placed on study. Animals were approximately 4 months of age at the time of study initiation. The animals were certified by the supplier to be healthy and free of antibodies to infectious diseases. Upon arrival the animals were single housed in suspended wire cages with slat bottoms, suspended over paper-lined waste pans. The animal room and cages had been cleaned and sanitized prior to animal receipt, in accordance with accepted animal care practices and relevant standard operating procedures. Certified Teklad Global Ferret Diet #2072 (Teklad Diets, Madison Wis.) and city of Chicago tap water were provided ad libitum and were refreshed at least once daily. Fluorescent lighting in the animal rooms was maintained on a 12-hr light/dark cycle. Animal room temperature and relative humidity were within respective protocol limits and ranged from 23.0 to 25.0° C. and 36 to 50%, respectively, during the study.
D. Animal Quarantine and Randomization: The ferrets were held in quarantine for seven days prior to randomization and observed daily. Based on daily observations indicating general good health of the animals the ferrets were released from quarantine for randomization and testing. Following quarantine, ferrets were weighed and assigned to treatment groups using a computerized randomization procedure based on body weights that produced similar group mean values [ToxData® version 2.1.E.11 (PDS Pathology Data Systems, Inc., Basel, Switzerland)]. Within a group, all body weights were within 20% of their mean. Animals selected for the study receive a permanent identification number by ear tag and transponder and individual cage cards also identified the study animals by individual numbers and group. The identifying numbers assigned were unique within the study.
E. Experimental Design: To assess the transmissibility of the M2KO(ΔTM) virus, ferrets were inoculated with M2KO(ΔTM) virus or A/Brisbane/10/2007 (H3N2) virus. The animals body weight, body temperature, clinical symptoms and viral shedding were monitored and immunological responses evaluated. 18 female ferrets (Triple F Farms, Sayre Pa.), 4 months of age at the time of study initiation were utilized for the study. All animal procedures were performed in an animal biosafety level-2 or level 3 facility. Prior to inoculation, ferrets were monitored for 3 days to measure body weight and establish baseline body temperatures. Temperature readings were recorded daily through a transponder (BioMedic data systems, Seaford, Del.) implanted subcutaneously in each ferret. Blood was collected prior to study initiation, and serum tested for influenza antibodies. Only ferrets with HI titers 40 to A/Brisbane/1 0/2007 (H3N2) virus were considered seronegative and used in this study. Study animals were randomized and divided into 2 groups (9 ferrets/group, 3/transmission chamber) as shown in Table 20. Ferrets in group 1 (Chambers A-C) were assigned to receive the M2KO(ΔTM) virus. Ferrets in group 2 (Chambers A-C) were assigned to receive the A/Brisbane/1 0/2007 (H3N2) virus. Within each group, ferrets were divided into inoculated donors or naive contacts.
1Each chamber consisted of three female ferrets: an infected donor ferret and 2 naïve contact ferrets (1 direct contact and 1 aerosol contact).
2Intranasally inoculated with a single dose of 316 μl of 1 × 107 TCID50 of M2KO or 1 × 107 TCID50 of A/Brisbane/10/2007 (H3N2) virus.
Each group was housed in separate rooms, and individuals working with the animals followed a strict work flow pattern to prevent cross contamination between the two groups In each group, one donor ferret was inoculated intranasally with a single dose of 316 μL of 1×107 TCID50 of M2KO(ΔTM) (Group1) or 1×107 TCID50 of A/Brisbane/10/2007 (H3N2) virus (Group 2). Twenty-four hours post inoculation; each donor was placed in the same cage with 1 naive ferret (direct contact), dual housed within a wire cage. An additional ferret (aerosol contact) was placed in a separate adjacent wire cage (single housed) within the transmission chamber separated from the donor's cage by a distance of 10-12 cm. Ferret body temperatures, weights, and clinical symptoms were monitored daily for 14 days post-inoculation. Nasal washes were collected from all inoculated donor ferrets on days 1, 3, 5, 7, 9 and from all contact (direct and aerosol) ferrets on days 2, 4, 6, 8, 10 for virus titration in cells. Nasal washes were collected from all ferrets on day 14 for antibody titration. Nasal wash samples were kept at −65° C.
F. Transmission Chambers: Each transmission chamber was 2 cubic meters. A computerized air handling unit was used for HEPA filtration and to monitor and control environmental conditions within the transmission chambers. To provide directional airflow, HEPA-filtered air was supplied through an inlet port located at one end of the chamber, exited through an outlet port at the opposite end the chamber, HEPA filtered and exhausted into the room. Air exchange rate was 20 complete air changes per hour for each chamber, airflow was maintained as <0.1 m/sec. Chambers were maintained at a negative pressure of −0.15 inches of water. Ferrets were housed in wire cages with slat bottoms which were suspended over paper-lined waste pans. Ferrets were either dual housed in 32×24×14 cages or single housed in 24×24×14 wire cages which were placed inside each HEPA-filtered transmission chamber.
G. Virus Inoculation: Ferrets were inoculated with the M2KO(ΔTM) virus. A vial of frozen stock was thawed and diluted to the appropriate concentration in phosphate buffered saline solution. Ferrets were anesthetized with ketamine/xylazine and the virus dose administered intranasally in a volume of 316 μL for the M2KO(ΔTM). To confirm the inoculation titer of the M2KO(ΔTM) virus, aliquots of the dosing solutions were collected prior to dosing (pre-dose) and after dosing (post-dose). The aliquots were stored at 65° C. for virus titration.
H. Challenge Virus: Influenza A virus, strain A/Brisbane/10/2007, serotype H3N2 was used to inoculate the control ferrets. The virus was stored at approximately −65° C. prior to use. The dose level of challenge virus used was prepared at 1×1 07 TCID50 in a volume of 316 μL. A quantitative viral infectivity assay, TCID50 assay was performed at IITRI on a portion of the prepared viral challenge solution. The viral titer assay was performed according to IITRI Standard Operating Procedures.
I. Moribundity/Mortality Observations: Following challenge, all animals were observed twice daily for mortality or evidence of moribundity. Animals were observed for 14 days after vaccine inoculation and for 14 days after challenge.
J. Body Weights and Body Weight Change: Body weights were recorded within two days of receipt and at randomization. All study animals were weighed prior to inoculation, daily for 14 days following each vaccination and assessed daily for 14 days post challenge. Prior to inoculation, ferrets were monitored for 3-5 days to measure establish baseline body temperatures. Temperature readings were recorded daily for 14 days following each vaccination and recorded daily for 14 days post challenge through a transponder (BioMedic data systems, Seaford, Del.) implanted subcutaneously in each ferret. The change in temperature (in degrees Celsius) was calculated at each time point for each animal.
K. Clinical Observations: The change in temperature (in degrees Celsius) was determined daily for each ferret. Clinical signs of, inappetence, respiratory signs such as dyspnea, sneezing, coughing, and rhinorrhea and level of activity was assessed daily. A scoring system based on that described by Reuman, et al., “Assessment of signs of influenza illness in the ferret model,” J. Virol, Methods 24:27-34 (1989), was used to assess the activity level as follows: 0, alert and playful; 1, alert but playful only when stimulated; 2, alert but not playful when stimulated; and 3, neither alert nor playful when stimulated. A relative inactivity index (RII) was calculated as the mean score per group of ferrets per observation (day) over the duration of the study.
L. Survival Checks: Two survival checks were performed daily on all study animals throughout the study. Both survival checks occurred simultaneously with the clinical observations. The second check was performed later within the same day.
M. Nasal Washes: Ferrets were anesthetized with a ketamine (25 mg/kg) and xylazine (2 mg/kg) mixture, and 0.5 ml of sterile PBS containing penicillin (100 U/ml), streptomycin (100 and gentamicin (50 was injected into each nostril and collected in a specimen cup when expelled by the ferret.
N. Euthanasia: Study animals were euthanized by an intravenous dose of sodium pentobarbital 150 mg/kg. Death was confirmed by absence of observable heartbeat and respiration. Necropsies were performed on all study animals.
O. Serum Collection: Pre-vaccination serum (days −3 to −5) and post inoculation serum (day 14) was collected from all ferrets. Ferrets were anesthetized with a ketamine (25 mg/kg) and xylazine (2 mg/kg) mixture. A sample of blood (approximately 0.5-1.0 mL) was collected via the vena cava from each ferret and processed for serum. Blood was collected into Serum Gel Z/1.1 tubes (Sarstedt Inc. Newton, N.C.) and stored at room temperature for not more than 1 hour before collecting serum. Serum Gel Z/1.1 tubes were centrifuged at 10,000×g for 3 minutes and the serum collected. Individual pre-inoculation serum samples were collected and two aliquots made from each sample. One aliquot was tested prior to the initiation of the study to confirm ferrets are free of antibodies to influenza A viruses and one aliquot of the serum stored at −65° C.
P. Hemagglutination Inhibition (HI) Assay: Serum samples were treated with receptor-destroying enzyme (RDE) (Denka Seiken, Tokyo, Japan) to eliminate inhibitors of nonspecific hemagglutination. RDE was reconstituted per the manufacturer's instructions. Serum was diluted 1:3 in RDE and incubated 18-20 hours in a 37° C.±2° C. water bath. After the addition of an equal volume of 2.5% (v/v) sodium citrate, the samples were incubated in a 56±2° C. water bath for 30±5 minutes. 0.85% NaCl was added to each sample to a final serum dilution of 1:10 after the RDE treatment. The diluted samples were then diluted into four two-fold dilutions (1:10 to 1:80) in duplicate in phosphate buffered saline (PBS) then incubated with 4 hemagglutinating units of A/Brisbane/10/2007 (H3N2) influenza A virus. After incubation, 0.5% avian red blood cells were added to each sample and incubated for 30±5 minutes. Presence or absence of hemagglutination was then scored.
Q. Virus Titers: The concentration of infectious virus in the pre- and post-challenge virus inoculum samples was determined by TCID50 assay in Madin-Darby Canine Kidney (MDCK) cells. Briefly, samples kept at −65° C. were thawed and centrifuged to remove cellular debris. The resulting supernatant were diluted 10-fold in triplicate in 96-well microtiter plates in Dulbecco's Modified Eagle Medium (DMEM) (Gibco, Carlsbad, Calif., USA) containing Pencillin/Streptomycin, 0.1% Gentamicin, 3% NaCO3, 0.3% BSA fraction V (Sigma St. Louis, Mo.), 1% MEM vitamin solution (Sigma) and 1% L-glutamine (Mediatech, Manassas, Va., USA). After 10-fold serial dilutions were made, 1 OOflL was transferred into respective wells of a 96-well plate which contained a monolayer of MDCK cells. Plates were incubated at 37° C.±2° C. in 5±2% CO2 70% humidity. After 48 hours, the wells were observed for cytopathogenic effect (CPE). Supernatant from each well (50 μl) was transferred to a 96 well plate and the hemagglutination (HA) activity determined and recorded. The HA activity of the supernatant was assessed by HA assay with 0.5% packed turkey red blood cells (tRBCs). TCID50 titers were calculated using the method of Reed LJ and Muench H, “A simple method for estimating 50% endpoints,” Am. J. Hygiene 27: 493-497 (1938).
R. Data Analysis: Body weights and body weight gains (losses) and changes in body temperature were determined for each individual animal expressed as mean and standard deviations of the mean for each test group.
Results
After inoculation of donor ferrets with either the M2KO(ΔTM) virus or the A/Brisbane/1 0/2007 (H3N2) influenza A virus donor ferrets were introduced into transmission chambers containing naive contact ferrets. Ferrets were monitored daily for clinical signs of infection, nasal washes were collected to monitor viral shedding and serum collected to measure serum antibody titers. All ferrets survived inoculation with M2KO(ΔTM) virus and A/Brisbane/10/2007 (Table 21). No clinical signs of disease were observed in ferrets in the M2KO(ΔTM) group. Two of the three donor ferrets inoculated with A/Brisbane/10/2007 virus presented respiratory signs (sneezing) on Day 6 and 8. Direct contact ferrets in all chambers presented with sneezing on Day 8. No sneezing was observed in the aerosol contact ferrets. A reduction in activity level was not observed.
aHemagglutination inhibition (HI) antibody titers to homologous virus in ferret serum prior to virus inoculation.
bClinical signs were observed for 14 days after virus inoculation. Except for lethargy, findings for clinical signs are given as no. of ferrets with sign/total no. Respiratory signs were sneezing, day of onset for each ferret in parentheses.
cDetermined twice daily for 14 days of observation based on the scoring system and was calculated as the mean score per group of ferrets per observation (day) over the 14-day period. The relative inactivity index before inoculation was 0.
Changes in body weight and temperature after virus inoculation are shown in
Conclusion
This example shows that ferrets inoculated with the A/Brisbane/10/2007 virus exhibited clinical signs of infection (sneezing, loss in body weight and a transient elevated body temperature), whereas ferrets inoculated with the M2KO(ΔTM) virus showed no clinical signs of disease. Therefore, inoculation of donor ferrets with the M2KO(ΔTM) did not appear to cause an infection or transmit virus via contact or via aerosol. These findings show that the M2KO(ΔTM) virus of the present technology is useful for intranasal influenza vaccines.
This examples demonstrates that the M2KO(ΔTM) virus elicits both humoral and mucosal immune responses in mice. The immunogenicity of M2KO(ΔTM) was evaluated in mice and compared to the immune responses generated by other modes of vaccination. An immunogenicity study was performed containing the following groups as outline in Table 22: 1. M2KO(ΔTM) virus, 2. PR8 virus (10 pfu), live vaccine representative, 3. Inactivated PR8 virus (Charles River Laboratories, Wilmington, Mass.), 1 μg, intranasal (IN) 4. Inactivated PR8 virus, 1 μg, intramuscular (IM), or PBS only.
To test the immunogenicity of M2KO(ΔTM) virus, mice were intranasally inoculated with 1.2×104 pfu of M2KO(ΔTM), 10 pfu of wild-type PR8, 1 μg of inactivated whole PR8 (Charles River Laboratories, Wilmington, Mass.), or PBS as control, along with a group intramuscularly administered 1 μg of inactivated whole PR8. Three weeks after the immunization, serum and trachea-lung washes were collected from mice and anti-PR8 immunoglobulin G (IgG) and IgA levels were measured by enzyme linked immunosorbent assay (ELISA). Briefly, ELISA plates were coated by whole inactivated PR8, blocked by bovine serum albumin (BSA), and samples were applied. Mouse IgG and IgA antibodies were detected by horseradish peroxidase labeled anti-mouse IgG- and IgA-goat antibodies (KPL, Inc., Gaithersburg, Md.) and SureBlue TMB (KPL, Inc.) substrate.
As expected, mice in the immunized groups showed significant elevation of anti-PR8 antibodies in serum and trachea-lung wash compare to the PBS only group (
This example demonstrates that the M2KO(ΔTM) virus protects mice from lethal homosubtypic and heterosubtypic challenge. The protective efficacy M2KO(ΔTM) virus was evaluated by challenging the immunized mice with lethal doses of the wild-type PR8 (H1N1; homosubtypic challenge) or mouse-adapted influenza A/Aichi/2/68 (Aichi; H3N2; heterosubtypic challenge) six weeks post-immunization. None of the mice immunized with either M2KO(ΔTM) or 10 pfu of PR8 and subsequently challenged by wild-type PR8 showed any clinical symptoms including weight loss (
For heterosubtypic challenge, mice were challenged by Aichi (H3N2). M2KO(ΔTM) and wild-type PR8 immunized mice survived challenge whereas mice that received inactivated PR8 or PBS succumbed to infection (
The M2KO(ΔTM) virus stimulates both humoral and cellular immune responses and confers protective immunity to animals against lethal homo- and hetero-subtypic challenge as summarized in Table 23.
This example demonstrates the efficacy of the M2KO(ΔTM) virus compared to ive attenuated virus (FluMist®), Fluzone® inactivated flu vaccine. Mice were immunized with M2KO(ΔTM) virus, cold adapted live attenuated virus (FluMist®), Fluzone® inactivated flu vaccine or mock immunized by PBS. M2KO(ΔTM)-H3 virus was constructed by inserting the HA and NA coding sequences of Influenza A/Brisbane/10/2007-like, A/Uruguay/716/2007(H3N2) in to the M2KO(ΔTM) backbone (SEQ ID NO:1). FluMist®-H3, internal genes from the cold-adapted A/AA/6/60 backbone, containing the HA and NA genes of Influenza A/Brisbane/10/2007-like, A/Uruguay/716/2007(H3N2) was plaque purified from the 2009/2010 trivalent vaccine formulation. Fluzone® 2009/2010 formulation was used directly as the trivalent formulation.
Sera was obtained on days 7, 14, 21 post-immunization to compare the kinetics of antibody response by ELISA (
The presence of anti-HA mucosal antibody in sera, lung wash, and nasal turbinates was evaluated by ELISA. M2KO(ΔTM)-H3 and FluMist,® the two live flu vaccines, had higher IgA in the respiratory tract than the inactivated vaccine Fluzone®. (
Six-week-old female BALB/c mice, anesthetized with isoflurane, were infected intranasally on days 0 and 28 with 106 TCID50/50 μl of M2KO(ΔTM)-H3 (described above), FluMist® (2009-2010) (H3N2) IVR-147 (PR8xBrisbane/10/2007). IVR-147 is the wild-type version of the M2KO(ΔTM) virus; i.e. contains a functional M2 protein. Mock-infected control mice received 50 μl PBS instead of virus. Serum was collected weekly from all the mice and analyzed for the presence of anti-HA antibodies by ELISA. As shown in
Body weights of animals were monitored for 14 days after infection. Vaccinated mice did not lose any weight. On day 21 post-boost, 3 mice per group were euthanized and their trachea-lung washes, nasal washes, and sera were collected for antibody titer determinations (
Mice were intranasally challenged with 40MLD50 of A/Aichi/2/68 virus six weeks post-boost. Mice were observed for loss of body weight and survival for 14 days (
Summary: M2KO(ΔTM) is an influenza virus that lacks expression of a functional M2 protein. The M2 protein is crucial for initiation of influenza viral infection and for efficient viral RNA incorporation into progeny virions. M2KO(ΔTM) can enter cells and express viral proteins but cannot make infectious progeny viruses due to deletion of the M2 gene. M2KO(ΔTM) is produced in permissive M2 protein expressing cells but not in non-permissive wild-type cells. M2KO(ΔTM) elicits both mucosal and humoral immunity in mice and protects from both homo and hetero-subtypic lethal challenge.
The H5N1 M2KO(ΔTM) virus contains the HA (avirulent) and NA genes of A/Vietnam/1203/2004 on the M2KO(ΔTM) backbone. By “M2KO(ΔTM) backbone” is meant the sequence of PR8 comprising the M2KO(ΔTM) (SEQ ID NO:1) mutation. The A/Vietnam/1203/2004 HA (avirulent) and NA sequences used are shown below.
Generation of H5N1 M2KO(ΔTM): The avirulent HA and NA of A/Vietnam/1203/2004 (H5N1) were chemically synthesized by GeneArt® Gene Synthesis based on the CDC sequences for each gene (CDC ID: 2004706280, Accession Numbers: EF541467 and EF541403). The sequences of the constructs were confirmed and sub-cloned into appropriate vectors to allow for the generation of seed virus using standard protocols.
M2KO(ΔTM) VN1203avHA,NA (H5N1 M2KO(ΔTM)) virus was amplified in M2CK cells (MDCK cells stably expressing the M2 protein), the supernatant clarified of cell debris and concentrated 100-fold by Centricon Plus-70 (Millipore). This virus was used as the immunogen in the mice study.
Mouse Study Design: Mice (7-8 weeks old, female BALB/c) were intranasally inoculated with H5N1 M2KO(ΔTM) (106 TCID50/mouse), M2KO(ΔTM) CA07HA, NA (106 TCID50/mouse) or VN1203 protein (1.5 μg) administered intramuscularly. Body weight and clinical symptoms were observed for 14 days post-inoculation. Sera was collected on days 7, 14, 21 post-inoculation. Mice were boosted on day 28 with a new prime only group initiated at the same time.
Boost immunization and ‘prime only’ groups: On day 28 the mice previously inoculated with H5N1 M2KO(ΔTM) were boosted with a second immunization of 106 pfu/mouse. At the same time the ‘prime only’ groups were given their first dose. Weight loss was followed for all groups following the day 28 inoculation. The mice that received a boost dose of M2KO(ΔTM) vaccine lost at most 5% of their body weight. The ‘prime only’ group lost up to 10% of their body weight.
15 mice/group for survival assessment after challenge
H5N1 M2KO(ΔTM) elicits IgG antibody titers against HA: Sera was obtained from mice on day 7, 14, 21 post-inoculation and analyzed by ELISA for antibodies against the hemagglutinin. M2KO(ΔTM) generated at least 100 fold higher titers than H5 HA protein (
Mice were challenged with a lethal dose of Vietnam/1203/2004 virus (20 MLD50). All H5N1 M2KO(ΔTM) vaccinated (prime only and prime-boost) mice survived (
The HA and NA cDNA clones of A/California/07/2009 (CA07) (H1N1pdm) were generated by standard molecular biology protocols. The sequences of the constructs were confirmed and sub-cloned into appropriate vectors to allow for the generation of seed M2KO(ΔTM) virus and M2WTCA07/PR8 virus using standard protocols. FluMist® CA07 (H1N1pdm) was plaque purified in MDCK cells from FluMist® 2011-2012 vaccine Lot #B11K1802. The A/California/07/2009 (CA07) HA and NA sequences used are shown below.
Mice (7-8 weeks old, female BALB/c) were intranasally inoculated with M2KO(ΔTM) CA07 (106 TCID50/mouse), M2WT CA07 (106 TCID50/mouse), FluMist® CA07 (106 TCID50/mouse) or OPTI-MEM™ as naïve control. Body weight and clinical symptoms were observed for 14 days post-inoculation.
FIG. 39M2KO(ΔTM) and FluMist® titers in sera collected 7, 14, and 21 days post-inoculation and anti-HA IgG titers were determined by ELISA. M2KO(ΔTM) induced higher responses that were detected earlier than FluMist® responses. By day 21 peak antibody levels were reached by both viruses.
Table 26 shows the virus titers in the lungs and nasal turbinates that were collected on day 3 post-challenge. M2KO(ΔTM) and FluMist® controlled challenge virus replication in the lungs and nasal turbinates to similar levels whereas naïve mice displayed virus titers that were a log higher in both the lung and the nasal turbinates.
Intracellular staining of cells in bronchoalveolar lavage (BAL). BAL was collected 3 days post-challenge and stained with surface markers for immunostaining by flow cytometry to detect CD8+CD4+, CD8+CD4−, CD8−CD4+, CD8−CD4− cell populations. Both CD4+ and CD8+ cell populations were greater in the vaccinated mice than the naïve mice indicating that M2KO(ΔTM) primed for a cellular response similar to FluMist®. M2KO(ΔTM) vaccinated mice had greater CD8+CD4− cell population than FluMist® (49% vs 40%) (
In some embodiments, the M2KO(ΔTM) virus is produced in cells that stably provide M2 protein in trans resulting in a virus that has functional M2 protein in the viral membrane but does not encode M2 in its genome. Therefore, we hypothesize that the M2KO(ΔTM) virus behaves similar to wild-type virus in the initial infection and first round of replication in normal cells. We suggest that mRNA levels of viral antigens are similar to wild-type levels early in infection and stimulate a potent immune response sooner than attenuated replicating viral vaccines.
Human lung carcinoma (A549) cells were infected at a multiplicity of infection of 0.5 with M2KO(ΔTM), FluMist® and wild-type viruses. Unabsorbed virus was removed by washing five times with PBS. After addition of virus growth media, the infected cells were placed in the 35° C. CO2 incubator. No trypsin was added to the growth medium to ensure single-cycle replication for all viruses. Cell monolayers were harvested and RNA extracted at 4, 9 and 22 hours post infection.
Total RNA (100 ng) from control and infected A549 cells were used for quantitative RT-PCR analysis. cDNA was synthesized with oligo-dT primers and Superscript II reverse transcriptase(Invitrogen) and quantified by real-time quantitative PCR analysis using gene-specific primers for an early influenza gene, M1, and a late influenza gene, HA and cytokine IP-10 gene. Reactions were performed using SYBR Green reagent (Invitrogen, Carlsbad) according to the manufacturer's instructions. Reaction efficiency was calculated by using serial 10-fold dilutions of the housekeeping gene γ-actin and sample genes. Reactions were carried out on an ABI 7300 realtime PCR system (Applied Biosystems, Foster City, Calif., USA) and the thermal profile used was Stage 1: 50° C. for 30 min; Stage 2: 95° C. for 15 min; Stage 3: 94° C. for 15 sec, 55° C. for 30 sec; and 72° C. for 30 sec, repeated for 30 cycles. All quantitations (threshold cycle [CT] values) were normalized to that of the housekeeping gene to generate ΔCT, and the difference among the ΔCT value of the sample and that of the reference (wild-type sample) was calculated as −ΔΔCT. The relative level of mRNA expression was expressed as 2-ΔΔCT.
M2KO(ΔTM) virus HA mRNA expression was similar to wild-type M2 virus for H3 (Table 27), PR8 (Table 28) and H1N1pdm (
The M2 gene of PR8 virus was cloned into expression vector pCMV-SC (Stratagene, La Jolla, Calif.) by standard molecular techniques to generate pCMV-PR8-M2. The plasmid was digested with EcoR1 to confirm the presence of the 300 bp M2 gene and the 4.5 Kb vector as shown in
Generation of M2 Vero cells: The pCMV-PR8-M2 plasmid described earlier and containing a neomycin resistant gene, was transfected into Vero cells (ATCC CCL-81) by using the Trans IT-LT1 transfection reagent (Mirus) according to the manufacturer's instructions. Briefly, on the day before transfection, Vero cells were plated at 5×105 cells/100-mm dish. On day 1, 10 μg of plasmid DNA was mixed with 20 μg of Trans IT-LT1 in 0.3 ml of OptiMEM (Invitrogen) and was incubated with these cells at 37° C. in 5% CO2 overnight. On day 2, the transfection mixture was replaced with a complete medium that is modified Eagle's medium (MEM) supplemented with 5% newborn calf serum. The medium also contained 1 mg/ml of geneticin (Invitrogen), a broad spectrum antibiotic that is used to select mammalian cells expressing the neomycin protein. Resistant cells (Vero cells stably expressing M2 gene) began to grow in the selection medium, the medium was replaced with fresh selection medium and geneticin-resistant clones were isolated by limited dilution in TC-96 plates. The surface expression of the M2 protein was demonstrated by immunostaining using a M2 specific monoclonal antibody, 14C2 (Santa Cruz Biotechnology).
Infection of parental and modified M2 Vero cells with M2KO(ΔTM) virus: The ability of M2 Vero cells to serve as production cells for M2KO(ΔTM) virus was tested by infection with M2KO(ΔTM)-PR8 virus. Briefly, monolayers of M2 Vero and parent Vero cells were infected with ten-fold serial dilutions (10−1 to 10−6) of M2KO(ΔTM)-PR8 virus using standard influenza infection procedures. The infected cells were incubated at 35° C. and observed for cytopathic effect (CPE) daily. Only M2 Vero cells displayed CPE indicating virus growth. Supernatant was harvested on day 4 from the 10−3 well and virus titer was determined by TCID50 assay on MDCK cells stably expressing M2 gene (M2CK). M2KO(ΔTM)-PR8 virus titer grown in M2 Vero cells was 106.75 TCID50/ml indicating that M2 Vero cells can serve as production cells for the manufacture of M2KO(ΔTM) vaccine.
This example demonstrates the immunogenicity of the seasonal influenza vaccine, FluLaval (2011-2012 formulation), when administered intramuscularly (IM), intradermally (ID), and using a subcutaneous microneedle device such as that described in published U.S. Patent Application 2011/0172609. Hairless guinea pigs were inoculated on day 0 and select groups were boosted on day 30. Sera was collected on days 0, 30 and 60 and analyzed by enzyme-linked immunosorbent assay (ELISA) for hemagglutinin-specific IgG responses.
Results are shown in
This application is a continuation of U.S. patent application Ser. No. 15/917,926, filed Mar. 12, 2018, which is a continuation of U.S. patent application Ser. No. 15/040,277, filed Feb. 10, 2016, now U.S. Pat. No. 9,919,042, issued Mar. 20, 2018, which is a continuation of U.S. patent application Ser. No. 14/128,415, filed Jan. 7, 2014, now U.S. Pat. No. 9,284,533, issued Mar. 15, 2016, which is the U.S. 371 National Stage Application of PCT International Application No.: PCT/US2012/043606, filed Jun. 21, 2012, which claims the benefit of U.S. Provisional Application No. 61/501,034, filed Jun. 24, 2011, the contents of which are incorporated herein by reference in their entireties.
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