WO2023207717A1 - H5n8禽流感广谱性疫苗的开发及其应用 - Google Patents

H5n8禽流感广谱性疫苗的开发及其应用 Download PDF

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WO2023207717A1
WO2023207717A1 PCT/CN2023/089267 CN2023089267W WO2023207717A1 WO 2023207717 A1 WO2023207717 A1 WO 2023207717A1 CN 2023089267 W CN2023089267 W CN 2023089267W WO 2023207717 A1 WO2023207717 A1 WO 2023207717A1
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recombinant protein
vaccine
amino acid
sequence
alanine
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PCT/CN2023/089267
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French (fr)
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王桂芹
周保罗
王海坤
常小艳
刘冬平
任欢欢
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中科南京生命健康高等研究院
中国科学院上海巴斯德研究所
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Publication of WO2023207717A1 publication Critical patent/WO2023207717A1/zh

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    • C12N2760/16011Orthomyxoviridae
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Definitions

  • the invention belongs to the field of biomedicine and relates to the development and application of a broad-spectrum H5N8 avian influenza vaccine.
  • the invention is an H5N8 avian influenza based on the hemagglutinin of an H5 subtype influenza virus strain as a skeleton protein. Development and application of broad-spectrum vaccines.
  • H5N1, H5N6 and H5N8 highly pathogenic avian influenza have infected nearly a thousand people and killed more than half of them.
  • a recombinant influenza virus formed from the HA of the H5N1 subtype highly pathogenic avian influenza A/goose/Guangdong/1/96 (GS/GD/1/96) strain and other genes of the H6N1 or H9N2 virus was discovered in Hong Kong. causes multiple infections.
  • GS/GD/1/96 highly pathogenic avian influenza A/goose/Guangdong/1/96
  • the infected cases were distributed in 17 countries. These cases were mainly distributed in Asia, followed by Africa.
  • H5N6 highly pathogenic avian influenza has infected 30 people in China, resulting in 6 deaths, with a mortality rate of 20%.
  • seven employees of a farm in southern Russia were infected with the H5N8 highly pathogenic avian influenza virus. This is the first time that human infection with the H5N8 avian influenza virus has been discovered internationally. Scientific researchers isolated the genetic material of the virus from these seven employees. The symptoms of these seven infected people were mild and no one died. Although human-to-human transmission has not yet been found, the possibility of the virus mutating and leading to human-to-human transmission in the future cannot be ruled out. .
  • Vaccine is the most effective means of preventing and controlling H5 subtype highly pathogenic avian influenza epidemics. Since the large-scale epidemic of H5 subtype highly pathogenic avian influenza, a variety of H5 subtype highly pathogenic avian influenza vaccines have been developed for poultry, including inactivated vaccines, vector vaccines and DNA vaccines. Many countries around the world, including my country, have also developed reserve vaccines for human H5 subtype highly pathogenic avian influenza, including inactivated vaccines and vector vaccines. However, the H5 subtype highly pathogenic avian influenza virus has evolved into ten subcategories, among which subcategories 1, 2 and 7 have further differentiated into secondary subcategories, tertiary subcategories, etc.
  • the object of the present invention is to provide a broad-spectrum vaccine for H5 subtype avian influenza.
  • a first aspect of the present invention provides a hemagglutinin recombinant protein, which contains the hemagglutinin skeleton from the first H5 subtype influenza virus strain, and the AS1 from the second H5 subtype influenza virus strain.
  • epitope the AS1 epitope is an AS1 epitope mutant type, and the AS1 epitope mutant type corresponds to the hemagglutinin sequence (amino acid sequence) from the second H5 subtype influenza virus strain in the wild-type AS1 epitope.
  • No.: EPI547678 amino acids at positions 98, 129-138, 153-161, 183, 186-194 and 221-228 amino acids (H3numbering) selected from the following group of amino acids are mutated:
  • Aspartic acid (Asp, D) at position 159 Aspartic acid (Asp, D) at position 159; and/or
  • the first H5 subtype influenza virus strain includes A/common magpie/Hong Kong/5052/2007(H5N1);
  • the second H5 subtype influenza virus strain includes A/chicken/Netherland/14015526/2014 (H5N8).
  • sequence number of the hemagglutinin skeleton amino acid sequence from the first H5 subtype influenza virus strain is ACJ26242.
  • an N-linked glycoprotein glycosylation site "Asn-Ser-Thr” is formed at amino acid positions 158, 159 and 160 of the recombinant protein through mutation of amino acids 159 and 160.
  • (N-S-T)" sequence and an N-sugar chain is formed at the 158th asparagine (Asn, N) site of the recombinant protein, and the N-sugar chain is located at the outer edge of the receptor binding site high variability zone.
  • alanine at position 160 is mutated into threonine (Threonine, Thr, T)
  • aspartic acid at position 159 Aspartic acid
  • Asp, D are mutated to amino acids other than serine and proline (excluding aspartic acid), forming N-linked glycoprotein sugars at amino acid positions 158, 159 and 160 of the recombinant protein.
  • the sylation site "Asn-X-Thr (N-X-T)" sequence (the X amino acid is selected from the following group: glycine, alanine, valine, leucine, isoleucine, phenylalanine, tyrosine, chrom amino acid, threonine, cysteine, methionine, asparagine, glutamine, glutamic acid, lysine, arginine, histidine, or a combination thereof), and in the recombinant protein
  • the asparagine (Asn, N) site at position 158 forms an N-sugar chain, and the N-sugar chain is located in the hypervariable region at the outer edge of the receptor binding site.
  • alanine at position 160 is mutated into serine (Serine, Ser, S), and aspartic acid at position 159 (Aspartic acid, Asp, D) is mutated to amino acids other than serine and proline (excluding aspartic acid), forming N-linked glycoprotein glycosylation at amino acid positions 158, 159 and 160 of the recombinant protein.
  • N-X-Ser (N-X-S) sequence
  • X amino acid is selected from the following group: glycine, alanine, valine, leucine, isoleucine, phenylalanine, tyrosine, tryptophan , serine, threonine, cysteine, methionine, asparagine, glutamine, glutamic acid, lysine, arginine, histidine, or a combination thereof), and in the recombinant protein
  • the asparagine (Asn, N) site at position 158 forms an N-sugar chain, and the N-sugar chain is located in the hypervariable region at the outer edge of the receptor binding site.
  • alanine at position 160 (Alanine, Ala, A) is mutated into serine (Serine, Ser, S) or mutated into threonine (Threonine, Thr, T ), forming an N-linked glycoprotein glycosylation site "Asn-Asp-Ser/Thr (N-D-S/T)" sequence at amino acid positions 158, 159 and 160 of the recombinant protein, and in the The asparagine (Asn, N) site at position 158 of the recombinant protein forms an N-sugar chain, and the N-sugar chain is located in the hypervariable region at the outer edge of the receptor binding site.
  • the mutated amino acids form N-linked glycoprotein glycosylation sites at positions 158, 159, and 160: Asn-X-Ser/Thr (N-X-S/T, where X is proline Any amino acid other than glycine, alanine, valine, leucine, isoleucine, phenylalanine, tyrosine, tryptophan, serine, threonine, cysteine, methionine, methionine, Paragine, glutamine, aspartic acid, glutamic acid, lysine, arginine and histidine).
  • the mutation includes insertion, deletion or substitution of amino acids.
  • the other amino acid sequences of the AS1 epitope mutant type correspond to those of the wild-type AS1 epitope from the second H5 subtype.
  • Position 98, 129-138, 153-161, 183 in the hemagglutinin sequence of influenza virus strain (amino acid sequence number: EPI547678)
  • the sequences shown in amino acids 186-194 and 221-228 (H3numbering) are the same or basically the same.
  • the homology between the hemagglutinin skeleton from the first H5 subtype influenza virus strain and the sequence shown in ACJ26242 is at least 80%, preferably at least 85% or 90%, and more Optimally it is at least 95%, optimally at least 98% or 99%.
  • the substantially identical means that at most 8 (preferably 1-5, more preferably 1-3) amino acids are different, wherein the differences include amino acids Substitution, deletion or addition, and N-glycans are introduced at the 158 amino acid position in the AS1 epitope mutant.
  • the recombinant protein has a structure of Formula I: Z1-Z2(I)
  • Z1 is the hemagglutinin skeleton from the first H5 subtype influenza virus strain A/common magpie/Hong Kong/5052/2007;
  • Z2 is the hemagglutinin skeleton from the second H5 subtype influenza virus strain A/chicken/Netherland/ The AS1 epitope of 14015526/2014;
  • the AS1 epitope is an AS1 epitope mutant, and the AS1 epitope mutant corresponds to the hemagglutination from the second H5 subtype influenza virus strain in the wild-type AS1 epitope.
  • amino acids at positions 98, 129-138, 153-161, 183, 186-194 and 221-228 (H3numbering) in the prime sequence are mutated in amino acids selected from the following group:
  • Aspartic acid (Asp, D) at position 159 Aspartic acid (Asp, D) at position 159; and/or
  • each "-" is independently a connecting peptide or peptide bond.
  • the recombinant protein is selected from the following group:
  • the "substantially the same function" means that the derived polypeptide has the introduction of N-sugar chains and can be immunized to produce neutralizing antibodies with broad spectrum.
  • amino acid sequence of the recombinant protein is shown in SEQ ID NO. 1 or 4.
  • the recombinant protein is a polypeptide having the amino acid sequence shown in SEQ ID NO.: 1 or 4, its active fragment, or its conservative variant polypeptide.
  • the homology between the recombinant protein and the sequence shown in SEQ ID NO.: 1 or 4 is at least 80%, preferably at least 85% or 90%, and more preferably at least 95% , optimally at least 98% or 99%.
  • the recombinant protein is a synthetic or recombinant recombinant protein.
  • the recombinant protein is a recombinant protein expressed by a eukaryotic expression system.
  • the recombinant protein is a recombinant protein expressed in yeast cells.
  • the recombinant protein is a recombinant protein expressed by insect cells.
  • the recombinant protein is a chimeric protein.
  • insect cells are selected from the following group: Sf9, Sf21, Tni, Hi5-Sf cells, or combinations thereof.
  • the yeast includes Pichia pastoris.
  • a second aspect of the present invention provides a vaccine polypeptide, which includes the recombinant protein described in the first aspect of the present invention.
  • the vaccine polypeptide can stimulate primates, rodents and poultry to produce neutralizing antibodies that can neutralize most of the representative strains of the 10 H5 subtypes.
  • the neutralizing antibodies stimulated by the vaccine polypeptide can prevent infection, prevent virus invasion and clear influenza viruses in the body.
  • the vaccine polypeptide induces B cell immunity in primates, rodents and poultry.
  • the primates include humans and non-human primates.
  • a third aspect of the present invention provides a DNA or mRNA vaccine, which contains encoding mRNA for expressing the recombinant protein described in the first aspect of the present invention, and a DNA expression vector.
  • the packaging carrier of the mRNA vaccine is protamine, nanoparticle liposomes, or chemically synthesized polymers.
  • the fourth aspect of the present invention provides an isolated polynucleotide encoding the recombinant protein described in the first aspect of the present invention or the vaccine polypeptide described in the second aspect of the present invention.
  • the fifth aspect of the present invention provides an expression vector, which contains the polynucleotide described in the fourth aspect of the present invention.
  • the sixth aspect of the present invention provides a host cell, the host cell contains the expression vector described in the fifth aspect of the present invention, or the polynucleotide described in the fourth aspect of the present invention is integrated into the genome.
  • the host cells include prokaryotic cells and eukaryotic cells.
  • the host cells include yeast, insect Hi5-Sf cells, Escherichia coli, monkey-derived Vero E6 cells, hamster CHO cells, and DC cells.
  • the seventh aspect of the present invention provides an H5 subtype influenza virus strain, the genome of the virus strain contains an exogenous recombinant protein gene sequence, wherein the recombinant protein gene sequence encodes the first aspect of the present invention. Recombinant protein.
  • influenza virus is H5N8 influenza virus.
  • the eighth aspect of the present invention provides a pharmaceutical composition, which contains the recombinant protein of the first aspect of the present invention, the vaccine polypeptide of the second aspect of the present invention, or the mRNA of the third aspect of the present invention.
  • a DNA vaccine or the polynucleotide described in the fourth aspect of the present invention or the expression vector described in the fifth aspect of the present invention or the host cell described in the sixth aspect of the present invention or the virus strain described in the seventh aspect of the present invention and Pharmaceutically acceptable carriers and/or excipients.
  • the pharmaceutical composition is a vaccine composition.
  • the vaccine composition is monovalent or multivalent.
  • the pharmaceutical composition also contains an adjuvant, preferably various aluminum adjuvants.
  • the molar number or weight ratio of the recombinant protein, immune polypeptide, mRNA or DNA vaccine or virus strain, and adjuvant (such as aluminum) in the pharmaceutical composition is between 1:100, preferably 1 :40 to 1:60.
  • the pharmaceutical composition includes single drugs, compound drugs, or synergistic drugs.
  • the dosage form of the pharmaceutical composition is liquid, solid, or gel.
  • the pharmaceutical composition is administered by a method selected from the group consisting of: subcutaneous injection, intradermal injection, intramuscular injection, intravenous injection, intraperitoneal injection, microneedle injection, oral administration, or oral and nasal spraying and atomization Inhaled.
  • a ninth aspect of the present invention provides a vaccine composition, said composition containing the recombinant protein of the first aspect of the present invention, the vaccine polypeptide of the second aspect of the present invention, or the mRNA of the third aspect of the present invention.
  • a DNA vaccine or the polynucleotide described in the fourth aspect of the present invention or the expression vector described in the fifth aspect of the present invention or the host cell described in the sixth aspect of the present invention or the virus strain described in the seventh aspect of the present invention and Immunologically acceptable carriers and/or excipients.
  • the vaccine composition further contains an adjuvant.
  • the adjuvant includes: granular and non-granular adjuvants.
  • the particulate adjuvant is selected from the group consisting of aluminum salts, water-in-oil emulsions, oil-in-water emulsions, nanoparticles, microparticles, liposomes, immunostimulatory complexes, or combinations thereof.
  • the non-granular adjuvant is selected from the following group: muramyl dipeptide and its derivatives, saponins, lipid A, cytokines, derived polysaccharides, bacterial toxins, microorganisms and their products such as branched bacilli (Mycobacterium tuberculosis, Bacillus Calmette-Guerin), Bacillus parvum, Bacillus pertussis, propolis, or combinations thereof.
  • the adjuvant includes aluminum oxide, saponin, Quil A, muramyl dipeptide, mineral oil or vegetable oil, vesicle-based adjuvant, non-ionic block copolymer or DEAE dextran , cytokines.
  • the vaccine composition includes an injection dosage form.
  • the tenth aspect of the present invention provides the recombinant protein as described in the first aspect of the present invention or the vaccine polypeptide as described in the second aspect of the present invention or the mRNA or DNA vaccine as described in the third aspect of the present invention or the seventh aspect of the present invention.
  • the use of the virus strain or the pharmaceutical composition according to the eighth aspect of the present invention or the vaccine composition according to the ninth aspect of the present invention (a) for preparing antibodies against avian influenza virus hemagglutinin; and/or ( b) For the preparation of drugs for the prevention and/or treatment of avian influenza virus infections or related diseases.
  • the avian influenza virus includes H5 subtype avian influenza virus.
  • the avian influenza virus includes H5N8 virus.
  • the antibody includes an antibody against hemagglutinin of H5 subtype avian influenza virus.
  • the antibody includes an antibody against H5 subtype avian influenza virus.
  • the eleventh aspect of the present invention provides a method for preparing the recombinant protein according to the first aspect of the present invention, comprising the steps:
  • step (i) of the method the transformed yeast colonies are inoculated into BMGY culture medium, and after culture, the supernatant is removed by centrifugation, and the cells are resuspended in BMMY culture medium at 28-30°C ( Preferably 29.5°C), induction culture for 36-48 hours (preferably 48 hours).
  • a twelfth aspect of the present invention provides a method for generating an immune response against avian influenza viruses, including the steps of administering the recombinant protein of the first aspect of the present invention and the vaccine polypeptide of the second aspect of the present invention to a subject in need , the mRNA or DNA vaccine according to the third aspect of the present invention or the virus strain according to the seventh aspect of the present invention or the pharmaceutical composition according to the eighth aspect of the present invention or the vaccine composition according to the ninth aspect of the present invention.
  • the subject includes humans or non-human mammals.
  • the non-human mammals include non-human primates (such as monkeys).
  • the method induces the production of neutralizing antibodies against H5 subtype avian influenza virus in the subject.
  • a thirteenth aspect of the present invention provides a treatment method, which involves administering to a subject in need the recombinant protein described in the first aspect of the present invention, the vaccine polypeptide described in the second aspect of the present invention, and the mRNA or DNA described in the third aspect of the present invention.
  • the treatment method includes a gene therapy method.
  • the treatment method includes transplantation of human DC cells transfected using electroporation technology in vitro and injection of lymphatic mRNA vaccine.
  • Figure 1 is the amino acid sequence of the hemagglutinin of the A/common magpie/Hong Kong/5052/2007 virus strain of the present invention.
  • Figure 2 is a schematic structural diagram of the transfer vector, packaging vector and expression vector used in preparing influenza pseudovirus of the present invention.
  • Figure 3 is a DNA plasmid map for constructing and expressing hemagglutinin in the present invention.
  • Figure 4 shows the spatial conformation and epitope of the hemagglutinin protein of the present invention.
  • the hemagglutinin protein is divided into a head region and a stem region. There are 4 epitopes in the head region, namely AS1, AS2, AS3 and AS4.
  • Figure 5 shows the present invention constructing a recombinant pseudovirus in which the head and rod parts of the hemagglutinin of the A/common magpie/Hong Kong/5052/2007 virus strain are exchanged and the hemagglutinin of the A/Thailand/(KAN-1)/2004 virus strain.
  • Figure 6 shows the present invention's construction of a recombinant pseudovirus with epitope exchange of the hemagglutinin head of the A/common magpie/Hong Kong/5052/2007 virus strain and the hemagglutinin head of the A/Thailand/(KAN-1)/2004 virus strain.
  • Figure 7 is a comparison of the amino acids in different epitopes of the hemagglutinin head of the A/common magpie/Hong Kong/5052/2007 virus strain and the A/Thailand/(KAN-1)/2004 virus strain according to the present invention.
  • Figure 8 is a conservative analysis of amino acids in the head of influenza hemagglutinin of the present invention.
  • the inventor unexpectedly found that the hemagglutinin skeleton from the first H5 subtype influenza virus strain (such as A/common magpie/Hong Kong/5052/2007), from the second H5 subtype influenza virus strain, Recombinant proteins with AS1 epitope mutations (such as amino acid mutations at position 159 and/or 160) of influenza virus strains (such as A/chicken/Netherland/14015526/2014) can effectively induce broad-spectrum neutralizing antibodies , thereby effectively preventing infection by avian influenza viruses (especially the representative strains of most of the 10 subtypes of H5 subtype).
  • the inventor completed the present invention.
  • AxxB means that amino acid A at position xx is mutated to amino acid B, for example, "D159S” means that amino acid D at position 159 is mutated to S, and so on.
  • H3numbering means amino acid numbering using the H3numbering method.
  • H5 subtype highly pathogenic avian influenza is a zoonotic infectious disease caused by influenza A virus of the genus Orthomyxoviridae.
  • Hemagglutinin (HA) can induce antibodies with neutralizing activity, and these antibodies can prevent viral infection, prevent viral invasion and clear influenza viruses in the body. It is the main target protein of type A influenza broad-spectrum vaccine.
  • the hemagglutinin HA of the H5N1 subtype avian influenza virus strain A/common magpie/Hong Kong/5052/2007 is used as the backbone of the influenza vaccine (the HA sequence is shown in Figure 1, SEQ ID NO.: 2 (shown), the epitopes recognized by the neutralizing antibodies induced are concentrated, and the key amino acids in the epitopes are located at or near positions 158, 159 and 160 at the outer edge of the hemagglutinin receptor binding region (H3numbering). Influenza virus hemagglutinin 158, 159 and 160 and their vicinity are located at the outer edge of the receptor binding site. The amino acids are poorly conserved and belong to the hypermutation region of hemagglutinin.
  • the hemagglutinin AS1 epitope of the A/common magpie/Hong Kong/5052/2007 virus strain contains 39 amino acids, as shown in Table 1 (H3 numbering).
  • the hemagglutinin HA of A/common magpie/Hong Kong/5052/2007 is used as the backbone protein, and its AS1 epitope is used for the AS1 epitope of the A/chicken/Netherland/14015526/2014 virus strain.
  • Replace the amino acid sequence of the AS1 epitope is shown in Table 2), and mutate the aspartic acid (Asp, D) at position 159 and the alanine (Alanine, Ala, A) at position 160 of the AS1 epitope.
  • NLAS1HK5052 Construct a recombinant protein immunogen (named NLAS1HK5052, the amino acid sequence is shown in SEQ ID NO.: 1) for serine (Ser, S) and threonine (Threonine, Thr, T).
  • NLAS1HK5052 introduces N-glycans at position 158 of Asparagine, Asn, N in the hypervariable region on the outer edge of the receptor binding site, which can induce broad-spectrum neutralizing antibodies.
  • the glycosylation site of N-linked glycoprotein is a sequence consisting of 3 amino acids: Asn-X-Ser/Thr (N-X-S/T), where X is any amino acid except proline, including glycine and alanine.
  • N-glycans refer to glycans linked to the amide nitrogen of asparagine residues in protein molecules.
  • AS1 epitope differs from the amino acid position in the AS1 epitope of A/chicken/Netherland/14015526/2014 hemagglutinin)
  • the H5N8 mutant vaccine strain prepared by the present invention can neutralize most of the representative strains of the 10 subtypes of H5 subtype (taking the viruses circulating from 1997 to 2014 as an example, as shown in Table 3).
  • the invention provides a hemagglutinin recombinant protein NLAS1HK5052.
  • the recombinant protein contains a hemagglutinin skeleton derived from a first H5 subtype influenza virus strain and a hemagglutinin skeleton derived from a second H5 subtype influenza virus strain.
  • AS1 epitope the AS1 epitope is an AS1 epitope mutant type, and the AS1 epitope mutant type corresponds to the hemagglutinin sequence (amino acid sequence) from the second H5 subtype influenza virus strain in the wild-type AS1 epitope.
  • the sequence number is EPI547678, and the amino acid sequence is as shown in SEQ ID NO.: 3). Selection of amino acids (H3numbering) at positions 98, 129-138, 153-161, 183, 186-194 and 221-228 Amino acids from the following group are mutated:
  • Aspartic acid (Asp, D) at position 159 Aspartic acid (Asp, D) at position 159; and/or
  • the first H5 subtype influenza virus strain of the present invention includes A/common magpie/Hong Kong/5052/2007 (H5N1), which is derived from the hemagglutinin backbone sequence of the first H5 subtype influenza virus strain.
  • the sequence number is ACJ26242 (the amino acid sequence is shown in SEQ ID NO.:2);
  • the second H5 subtype influenza virus strain of the present invention includes A/chicken/Netherland/14015526/2014 (H5N8).
  • the amino acids at positions 158, 159 and 160 of the recombinant protein form an "Asn-Ser-Thr (N-S-T)" sequence, and at position 158 of the recombinant protein
  • the asparagine (Asn, N) site forms an N-sugar chain, and the N-sugar chain is located in the hypervariable region at the outer edge of the receptor binding site.
  • the N-linked glycoprotein glycosylation site Asn-X-Ser/Thr (N-X-S/T, where Any amino acid other than amino acid, including glycine, alanine, valine, leucine, isoleucine, phenylalanine, tyrosine, tryptophan, serine, threonine, cysteine, methionine , asparagine, glutamine, aspartic acid, glutamic acid, lysine, arginine and histidine)
  • N-glycans into asparagine at position 158 to form N-links type glycoprotein, and the N-glycan is located in the hypervariable region at the outer edge of the receptor binding site.
  • the A/common magpie/Hong Kong/5052/2007 hemagglutinin HA sequence (SEQ ID NO.: 2), A/chicken/Netherland/14015526/2014 hemagglutinin HA sequence (SEQ ID NO.: 3) and the amino acid numbering in recombinant protein NLAS1HK5052 (SEQ ID NO.: 1 or 4) are based on The unified H3numbering method facilitates the accurate identification of AS1 epitope amino acid sites and mutated amino acid sites, and can also avoid sequence homology differences caused by amino acid numbering misalignment caused by conventional sequence comparison technology.
  • amino acid sequence of recombinant protein NLAS1HK5052 is shown in SEQ ID NO.1 or 4:
  • the recombinant protein NLAS1HK5052 (SEQ ID NO.: 1 or 4) of the present invention is a synthetic protein or a recombinant protein, that is, it can be a product of chemical synthesis, or it can be obtained from a prokaryotic or eukaryotic host (for example, bacteria, yeast, plant) using recombinant technology produced in.
  • Recombinant proteins of the invention may or may not include an initial methionine residue.
  • the invention also includes fragments, derivatives and analogs of said recombinant proteins.
  • fragment refers to proteins that retain substantially the same biological function or activity of the recombinant protein.
  • the recombinant protein fragments, derivatives or analogs of the present invention can be any suitable recombinant protein fragments, derivatives or analogs of the present invention.
  • conservatively substituted amino acids preferably conservative amino acid residues
  • the active recombinant protein of the present invention has basically the same immunogenicity in stimulating immune responses, and the induced neutralizing antibodies have the activity of neutralizing most of the representative strains of the 10 subtypes of H5 subtype.
  • the recombinant protein is NLAS1HK5052, as shown in SEQ ID NO.: 1 or 4.
  • the recombinant protein of the present invention has higher homology (identity) than the sequence shown in SEQ ID NO.: 1 or 4.
  • the recombinant protein has higher homology (identity) with SEQ ID NO.: 1
  • the homology of the sequence shown in 4 is at least 80%, preferably at least 85%-90%, more preferably at least 95%, optimally at least 98%, optimally, ⁇ 99%.
  • the recombinant protein of the present invention can also be modified.
  • Modified (usually without changing primary structure) forms include chemically derivatized forms of the recombinant protein in vivo or in vitro such as acetylation or carboxylation.
  • Modifications also include glycosylation, such as those resulting from glycosylation modifications during the synthesis and processing of the recombinant protein or during further processing steps. This modification can be accomplished by exposing the recombinant protein to enzymes that perform glycosylation, such as mammalian glycosylases or deglycosylases.
  • Modified forms also include sequences having phosphorylated amino acid residues (eg, phosphotyrosine, phosphoserine, phosphothreonine). Also included are recombinant proteins that have been modified to increase their resistance to proteolysis or to optimize solubility properties.
  • polynucleotide encoding a recombinant protein may include polynucleotides encoding the recombinant protein of the present invention, or may also include polynucleotides that additionally include coding and/or non-coding sequences; nucleotides include ribonucleic acid (RNA, Ribonucleic Acid), and deoxyribonucleic acid (DNA, Deoxyribonucleic Acid).
  • RNA Ribonucleic Acid
  • DNA Deoxyribonucleic Acid
  • the present invention also relates to variants of the above-mentioned polynucleotides, which encode fragments, analogs and derivatives of polypeptides or recombinant proteins having the same amino acid sequence as the present invention.
  • These nucleotide variants include substitution variants, deletion variants, and insertion variants.
  • allelic variants are alternative forms of a polynucleotide Formula, which may be the substitution, deletion or insertion of one or more nucleotides, does not substantially change the function of the recombinant protein it encodes.
  • the invention also relates to polynucleotides that hybridize to the sequences described above and have at least 50%, preferably at least 70%, more preferably at least 80% identity between the two sequences.
  • the invention particularly relates to polynucleotides that hybridize under stringent conditions (or stringent conditions) to the polynucleotides of the invention.
  • stringent conditions refers to: (1) hybridization and elution at lower ionic strength and higher temperature, such as 0.2 ⁇ SSC, 0.1% SDS, 60°C; or (2) adding There are denaturants, such as 50% (v/v) formamide, 0.1% calf serum/0.1% Ficoll, 42°C, etc.; or (3) only the identity between the two sequences is at least 90%, more It is best when hybridization occurs only when the ratio is above 95%.
  • the recombinant proteins and polynucleotides of the invention are preferably provided in isolated form and, more preferably, are purified to homogeneity.
  • the full-length sequence of the polynucleotide of the present invention can usually be obtained through PCR amplification, recombination or artificial synthesis.
  • primers can be designed based on the relevant nucleotide sequences disclosed in the present invention, especially the open reading frame sequence, and commercially available cDNA libraries or cDNA prepared by conventional methods known to those skilled in the art can be used.
  • the library is used as a template to amplify the relevant sequence. When the sequence is long, it is often necessary to perform two or more PCR amplifications, and then splice the amplified fragments together in the correct order.
  • recombination can be used to obtain the relevant sequence in large quantities. This is usually done by cloning it into a vector, transforming it into cells, and then isolating the relevant sequence from the propagated host cells by conventional methods.
  • artificial synthesis methods can also be used to synthesize relevant sequences, especially when the fragment length is short. Often, fragments with long sequences are obtained by first synthesizing multiple small fragments and then ligating them.
  • the DNA sequence encoding the protein of the present invention (or its fragment, or its derivative) can be obtained entirely through chemical synthesis.
  • the DNA sequence can then be introduced into a variety of existing DNA molecules (or vectors) and cells known in the art.
  • mutations can also be introduced into the protein sequences of the invention by chemical synthesis.
  • the method of amplifying DNA/RNA using PCR technology is preferably used to obtain the polynucleotide of the present invention. Especially when it is difficult to obtain full-length cDNA from a library, the RACE method (RACE-rapid amplification of cDNA ends) can be preferably used.
  • the primers used for PCR can be appropriately selected based on the sequence information of the present invention disclosed herein. And can be synthesized by conventional methods.
  • the amplified DNA/RNA fragments can be separated and purified using conventional methods such as by gel electrophoresis.
  • epitopope peptide of the present invention in the present invention, "vaccine polypeptide of the present invention” and “polypeptide of the present invention” can be used interchangeably, and refer to the vaccine polypeptide in accordance with the second aspect of the present invention.
  • vaccine polypeptides also include other forms, such as pharmaceutically acceptable salts, conjugates, or fusion proteins.
  • the vaccine polypeptide includes one or more (such as 1-5, preferably 1-3) amino acid additions to the sequence shown in SEQ ID NO.: 1 or 4, one or more (such as 1 -A derivative polypeptide formed by the substitution of 5, preferably 1-3) amino acids and/or the deletion of 1-3 amino acids, which has substantially the same function as the original polypeptide before derivatization.
  • the vaccine polypeptide includes the sequence shown in SEQ ID NO.: 1 or 4 through the addition of 1-3 amino acids (preferably added at the N-terminus or C-terminus), and/or the substitution of 1-2 amino acids (preferably conservative amino acid substitution) and still have essentially the same function as the original polypeptide before derivatization.
  • conservative amino acid substitutions are based on amino acid substitutions in Table 5.
  • isolated means that a substance has been separated from its original environment (in the case of a natural substance, the original environment is the natural environment).
  • polypeptides in their natural state within living cells are not isolated and purified, but the same polypeptide is isolated and purified if it is separated from other substances that exist in its natural state.
  • isolated peptide means that a polypeptide of the invention is substantially free of other proteins, lipids, carbohydrates or other materials with which it is naturally associated.
  • One skilled in the art can purify polypeptides of the invention using standard protein purification techniques.
  • a substantially purified polypeptide (fusion protein) produces a single major band on a non-reducing polyacrylamide gel.
  • polypeptide of the present invention may be a recombinant polypeptide or a synthetic polypeptide, preferably a synthetic polypeptide.
  • sequence of the vaccine polypeptide is short (such as ⁇ 70aa, more preferably ⁇ 60aa)
  • chemical methods can be used to directly synthesize the relevant peptide sequence.
  • recombinant methods can also be used to obtain the relevant peptide sequences in large quantities. This usually involves cloning the coding sequence encoding the antigen polypeptide or its fusion protein into a vector, then transferring it into cells, and then isolating the relevant antigen peptide or fusion protein from the proliferated host cells through conventional methods.
  • the present invention also provides mRNA vaccines, DNA vaccines or VLPs vaccines for preventing H5 subtype avian influenza viruses.
  • the mRNA vaccine is a kind of RNA with translational activity prepared in vitro. Its main structure includes 5'UTR and 3'UTR and an open reading frame containing the expression of the recombinant protein NLAS1HK5052 (SEQ ID NO.: 1 or 4) of the present invention. Compared with DNA vaccines, it does not need to enter the cell nucleus and has no risk of integration into the genome.
  • the method of mRNA vaccine includes: based on the amino acid sequence of NLAS1HK5052 (SEQ ID NO.: 1 or 4), constructing a template through PCR method or artificial synthesis method and transcribing in vitro to obtain the primary mRNA product, which is further capped, tailed, etc. The structurally complete mRNA enters the body through the delivery system.
  • DNA vaccine is a recombinant eukaryotic expression vector containing the NLAS1HK5052 (SEQ ID NO.: 1 or 4) protein open reading frame.
  • the exogenous NLAS1HK5052 (SEQ ID NO.: 1 or 4) gene can be transcribed in living cells Translated and expressed to induce body-specific humoral and cellular immune responses.
  • the DNA sequence encodes only a single protein gene, and there is basically no possibility of toxicity reversal. It is an injectable DNA molecule.
  • the DNA vaccine method includes: constructing a template sequence through PCR or artificial synthesis based on the amino acid sequence of the recombinant protein NLAS1HK5052 (SEQ ID NO.: 1 or 4), and connecting the sequence to the target vector to form a vaccine that can be
  • the host cell takes up, transcribes and translates the DNA vaccine expressing the corresponding NLAS1HK5052 recombinant protein (SEQ ID NO.: 1 or 4) in vivo.
  • VLPs virus-like particles
  • viruses vaccine methods include: a gene expression vector plasmid encoding the recombinant protein NLAS1HK5052 (SEQ ID NO.: 1 or 4), a gene expression vector encoding A/chicken/Netherland/14015526/2014 ceramide (NA) , transfer vector plasmid and packaging vector plasmid, prepared by co-transfection of cells.
  • an amino acid may have multiple bases, and there may be many nucleotide sequences corresponding to the recombinant protein NLAS1HK5052 (SEQ ID NO.: 1 or 4), but mRNA vaccines, DNA vaccines, and vaccines containing recombinant protein NLAS1HK5052 (SEQ ID NO.: 1 or 4) ID NO.: 1 or 4), the amino acid sequence of the protein finally translated and expressed in vivo is consistent with the amino acid sequence of NLAS1HK5052 (SEQ ID NO.: 1 or 4), or the homology is at least 80%, Preferably it is at least 85%-90%, more preferably at least 95%, most preferably at least 98%, most preferably, ⁇ 99%.
  • the corresponding translation protein AS1 epitope has the introduction of N-glycans.
  • the present invention also provides an inactivated vaccine for preventing H5 subtype avian influenza virus.
  • Inactivated vaccines refer to culturing viruses or bacteria and then using physical (such as heating) or chemical reagents (such as ⁇ -propiolactone) to inactivate them so that they lose their infectivity or toxicity but still maintain immunogenicity.
  • Inactivated vaccines can be composed of whole viruses or bacteria, or they can be composed of their cleaved fragments into split vaccines and further purified until the vaccine contains only the desired antigenic components. Attenuated vaccines mean that the toxicity of pathogenic microorganisms is weakened after various treatments, but their immunogenicity is still retained.
  • Typical methods for inactivated and attenuated vaccines include using reverse genetic technology to co-transfect cells with plasmids based on the nucleotide sequence of H5 subtype avian influenza viruses to obtain avian influenza viruses, and further pass them through cells or chickens.
  • the embryos are inactivated or treated after virus amplification, thereby losing or weakening the infectivity (or toxicity) of the virus.
  • the hemagglutinin protein of influenza virus obtained using reverse genetic technology is a recombinant protein, and the amino acid sequence is consistent with the amino acid sequence of NLAS1HK5052 (SEQ ID NO.: 1 or 4), or The homology is at least 80%, preferably at least 85%-90%, more preferably at least 95%, most preferably at least 98%, most preferably, ⁇ 99%.
  • the corresponding translation protein AS1 epitope has the introduction of N-glycans.
  • the invention also provides a vector comprising the recombinant protein coding sequence of the invention, and a host cell containing the vector.
  • the vector has an expression cassette for expressing the recombinant protein gene, and the expression cassette has the following elements in order from 5’ to 3’: a promoter, a recombinant protein gene, and a terminator.
  • Those of ordinary skill in the art can obtain the above-mentioned optimized gene sequence of the recombinant protein using conventional methods, such as total artificial synthesis or PCR synthesis.
  • a preferred synthesis method is asymmetric PCR.
  • Primers for PCR can be appropriately selected based on the sequence information of the present invention disclosed herein, and can be synthesized by conventional methods.
  • the amplified DNA/RNA fragments can be separated and purified using conventional methods such as by gel electrophoresis.
  • the polynucleotide sequence of the present invention can be used to express or produce the target protein (recombinant protein) through conventional recombinant DNA technology, including the steps:
  • polynucleotide or variant encoding the protein of the present invention, or use a recombinant expression vector containing the polynucleotide to transform or transduce a suitable host cell, preferably yeast.
  • expression vectors containing the DNA sequence encoding the protein of the invention and appropriate transcription/translation control signals preferably commercially available vectors such as pPink ⁇ HC or pMT/BiP/V5-HisA. These methods include in vitro recombinant DNA technology, DNA synthesis technology, in vivo recombination technology, etc.
  • the DNA sequence can be effectively linked to an appropriate promoter in an expression vector to direct mRNA synthesis.
  • the expression vector also includes a ribosome binding site for translation initiation and a transcription terminator.
  • the expression vector preferably contains one or more selectable marker genes to provide phenotypic traits for selection of transformed host cells.
  • a vector containing the above DNA sequence and an appropriate promoter or control sequence can be used to transform appropriate host cells to express the target protein.
  • the host cell capable of expressing the recombinant protein of the present invention can be a prokaryotic cell, such as Escherichia coli; or a lower eukaryotic cell, such as a yeast cell (Pichia pastoris, Saccharomyces cerevisiae); or a higher eukaryotic cell, such as an insect cell; preferably for yeast cells. Transformation of host cells with recombinant DNA can be performed using conventional techniques well known to those skilled in the art.
  • the engineered cells can be methanol-utilizing rapidly (Mut + ) or methanol-utilizing slowly (Mut s ).
  • the engineered cells can be cultured under appropriate conditions to express the protein encoded by the gene sequence of the present invention.
  • the culture medium used in the culture can be selected from various conventional culture media and cultured under conditions suitable for the growth of the host cells.
  • the selected promoter is induced using an appropriate method (such as temperature shift or chemical induction), and the cells are cultured for a further period of time.
  • the fermentation and induction temperature of the recombinant protein of the present invention is maintained at 28-30°C;
  • DO dissolved oxygen
  • the types of feeding materials should include carbon sources such as glycerol, methanol, and glucose, which can be fed separately or mixed.
  • Engineered cells expressing target proteins can be purified using chromatography technology.
  • Chromatography technologies include cation exchange chromatography, anion exchange chromatography, gel filtration chromatography, hydrophobic chromatography, affinity chromatography and other technologies. Commonly used chromatography methods include:
  • Anion exchange chromatography media include (but are not limited to): Q-Sepharose, DEAE-Sepharose. If the salt concentration of the fermentation sample is high and affects the binding with the ion exchange medium, the salt concentration needs to be reduced before performing ion exchange chromatography.
  • the sample can be replaced with an equilibrium buffer by means of dilution, ultrafiltration, dialysis, gel filtration chromatography, etc., until it is similar to the corresponding ion exchange column equilibrium system, and then the sample can be loaded for gradient elution with salt concentration or pH.
  • Hydrophobic chromatography media include (but are not limited to): Phenyl-Sepharose, Butyl-Sepharose, Octyle-Sepharose.
  • the salt concentration of the sample is increased by adding NaCl, (NH 4 ) 2 SO 4 , etc., and then the sample is loaded and eluted by reducing the salt concentration. Removal of impure proteins with large differences in hydrophobicity through hydrophobic chromatography.
  • Hydrophobic chromatography media include (but are not limited to): Sephacryl, Superdex, and Sephadex. Replace the buffer system by gel filtration chromatography, or further purify.
  • Affinity chromatography media include (but are not limited to): HiTrap TM Heparin HP Columns.
  • the recombinant protein (polypeptide) of the present invention can be a recombinant polypeptide or a synthetic polypeptide.
  • the polypeptides of the present invention can be chemically synthesized or recombinant.
  • the polypeptide of the present invention can be artificially synthesized by conventional methods or produced by recombinant methods.
  • a preferred method is to use liquid phase synthesis technology or solid phase synthesis technology, such as Boc solid phase method, Fmoc solid phase method or a combination of the two methods.
  • Solid-phase synthesis can quickly obtain samples, and appropriate resin carriers and synthesis systems can be selected according to the sequence characteristics of the target peptide.
  • the preferred solid phase carrier in the Fmoc system is Wang resin connected to the C-terminal amino acid in the peptide.
  • Wang resin is polystyrene, and the arm between the amino acid and the amino acid is 4-alkoxybenzyl alcohol; use 25% hexahydropyridine /dimethylformamide at room temperature for 20 minutes to remove the Fmoc protecting group, and extend from the C-terminus to the N-terminus one by one according to the given amino acid sequence.
  • trifluoroacetic acid containing 4% p-methylphenol to cleave the synthesized proinsulin-related peptide from the resin and remove the protecting group.
  • the resin can be filtered out and then separated by diethyl ether precipitation to obtain the crude peptide.
  • the desired peptide is purified using gel filtration and reversed-phase high-pressure liquid chromatography.
  • the preferred resin is PAM resin connected to the C-terminal amino acid in the peptide.
  • the PAM resin structure is polystyrene, and the arm between the amino acid and the amino acid is 4-hydroxymethylphenylacetamide; synthesized in Boc
  • TFA/dichloromethane (DCM) to remove the protecting group Boc and neutralize it with diisopropylethylamine (DIEA/dichloromethane).
  • DCM TFA/dichloromethane
  • Various coupling agents and coupling methods known in the field of peptide chemistry can be used to couple each amino acid residue, for example, dicyclohexylcarbodiimide (DCC), hydroxybenzotriazole (HOBt) or 1 ,1,3,3-tetraurea hexafluorophosphate (HBTU) for direct coupling.
  • DCC dicyclohexylcarbodiimide
  • HOBt hydroxybenzotriazole
  • HBTU 1 ,1,3,3-tetraurea hexafluorophosphate
  • the recombinant protein of the present invention is prepared by solid-phase synthesis according to its sequence, and is purified by high-performance liquid chromatography to obtain high-purity target peptide lyophilized powder, which is stored at -20°C.
  • polypeptides of the invention Another approach is to use recombinant techniques to produce the polypeptides of the invention.
  • the polynucleotide of the present invention can be used to express or produce the antigenic peptide of the present invention through conventional recombinant DNA technology. Generally speaking there are the following steps:
  • polynucleotide (or variant) of the recombinant protein of the present invention or use the recombinant expression vector containing the polynucleotide to transform or transduce suitable host cells;
  • the recombinant polypeptide can be expressed within the cell, on the cell membrane, or secreted outside the cell. If desired, the recombinant protein can be isolated and purified by various separation methods utilizing its physical, chemical and other properties. These methods are well known to those skilled in the art. Examples of these methods include, but are not limited to: conventional refolding treatment, treatment with protein precipitating agents (salting out method), centrifugation, osmotic sterilization, ultratreatment, ultracentrifugation, molecular sieve chromatography (gel filtration), adsorption layer analysis, ion exchange chromatography, high performance liquid chromatography (HPLC) and various other liquid chromatography techniques and combinations of these methods.
  • conventional refolding treatment treatment with protein precipitating agents (salting out method), centrifugation, osmotic sterilization, ultratreatment, ultracentrifugation, molecular sieve chromatography (gel filtration), adsorption layer analysis, ion exchange chromatography, high performance liquid
  • polypeptide of the present invention is short, it is possible to concatenate multiple polypeptides together, obtain an expression product in the form of a polymer after recombinant expression, and then form the required small peptide through enzyme digestion or other methods.
  • the invention also provides a method for preparing a vaccine composition, specifically, including the steps:
  • the recombinant protein prepared in the present invention is mixed with a pharmaceutically acceptable vaccine adjuvant to form a vaccine composition.
  • the adjuvant is aluminum adjuvant or GLA adjuvant, preferably aluminum adjuvant.
  • compositions and methods of administration are provided.
  • the present invention also provides a composition containing: (i) the recombinant protein or vaccine polypeptide prepared by the method of the present invention, and (ii) a pharmaceutically or immunologically acceptable excipient or adjuvant .
  • the term “comprising” means that various ingredients can be used together or present in the composition of the present invention. Therefore, the terms “consisting essentially of” and “consisting of” are included in the term “comprising”.
  • compositions of the present invention include pharmaceutical compositions and vaccine compositions.
  • the compositions of the present invention may be monovalent or polyvalent.
  • the pharmaceutical composition or vaccine composition of the present invention can be prepared into various conventional dosage forms, including (but not limited to): injections, granules, tablets, pills, suppositories, capsules, suspensions, sprays, etc.
  • the pharmaceutical composition of the present invention includes an effective amount of the recombinant protein or vaccine polypeptide prepared by the method of the present invention.
  • the recombinant protein or vaccine polypeptide may be monovalent or multivalent.
  • the term "effective amount” refers to an amount of a therapeutic agent that treats, ameliorates, or prevents the target disease or condition, or an amount that exhibits a detectable therapeutic or preventive effect. This effect can be detected, for example, by antigen levels. Therapeutic effects also include a reduction in physiological symptoms. The precise effective amount for a given subject will depend on the size and health of the subject, the nature and extent of the condition, and the therapeutic agent and/or combination of therapeutic agents chosen to be administered. Therefore, it is useless to pre-specify the exact effective amount. However, routine experimentation can be used to determine the effective amount for a given situation.
  • an effective dose is about 0.2 ⁇ g/kg to 2 ⁇ g/kg administered to an individual.
  • compositions may also contain pharmaceutically acceptable carriers.
  • pharmaceutically acceptable carrier refers to a carrier used for the administration of a therapeutic agent (eg, a recombinant protein or other therapeutic agent). This term refers to pharmaceutical carriers that do not themselves induce the production of antibodies that are harmful to the individual receiving the composition and do not exhibit undue toxicity upon administration.
  • Suitable carriers can be large, slowly metabolized macromolecules, such as proteins, polysaccharides, polylactic acid, polyglycolic acid, etc. These vectors are well known to those of ordinary skill in the art. A thorough discussion of pharmaceutically acceptable carriers or excipients can be found in Remington’s Pharmaceutical Sciences (Mack Pub. Co., N.J. 1991).
  • compositions may include liquids such as water, saline, glycerin and ethanol. In addition, these carriers may also contain auxiliary substances, such as wetting agents or emulsifiers, pH buffer substances, etc. Generally, the compositions may be prepared as injectables, such as liquid solutions or suspensions; solid forms suitable for constitution with solutions or suspensions, liquid excipients prior to injection may also be prepared. Liposomes are also included in the definition of pharmaceutically acceptable carriers.
  • the vaccine compositions of the present invention may be prophylactic (i.e., prevent infection) or therapeutic.
  • the vaccine compositions comprise immunogenic antigens (including proteins of the invention or self-assembled virus-like particles) and are usually combined with "pharmaceutically acceptable carriers" that do not themselves induce the production of immune cells that are resistant to the composition. Any carrier of individually harmful antibodies. Suitable carriers are usually large, slowly metabolized macromolecules, such as proteins, polysaccharides, polylactic acid, polyglycolic acid, amino acid polymers, amino acid copolymers, lipid aggregates (such as oil droplets or liposomes), etc. These vectors are well known to those of ordinary skill in the art. Additionally, these carriers can act as immunostimulants ("adjuvants").
  • the antigen can also be coupled to bacterial toxoids (such as toxoids of diphtheria, tetanus, cholera, Helicobacter pylori and other pathogens).
  • Preferred adjuvants that enhance the effect of the immune composition include, but are not limited to: (1) aluminum salts (alum), such as aluminum hydroxide, aluminum phosphate, aluminum sulfate, etc.; (2) oil-in-water emulsion formulations, such as (a) MF59 (see WO90/14837), (b) SAF, and (c) Ribi TM Adjuvant System (RAS) (Ribi Immunochem, Hamilton, MT), (3) saponin adjuvant; (4) Freund's complete adjuvant ( CFA) and Freund's incomplete adjuvant (IFA); (5) Cytokines, such as interleukins (such as IL-1, IL-2, IL-4, IL-5, IL-6, IL-7, IL-12, etc.
  • aluminum salts alum
  • oil-in-water emulsion formulations such as (a) MF59 (see WO90/14837), (b) SAF, and (c) Ribi TM Adjuvant System (RAS
  • interferons such as gamma interferon
  • macrophage colony-stimulating factor M-CFS
  • tumor necrosis factor TNF
  • Bacterial ADP-ribosylation toxins such as cholera toxin CT, pertussis toxin PT or detoxified variants of E. coli heat-labile toxin LT
  • other substances that act as immunostimulants to enhance the effect of the composition see for example WO93/13302 and WO92/19265.
  • Vaccine compositions including immunogenic compositions usually contain diluents such as water, saline, glycerol, ethanol, etc.
  • diluents such as water, saline, glycerol, ethanol, etc.
  • auxiliary substances such as wetting or emulsifying agents, pH buffering substances, etc. may be present in such vehicles.
  • vaccines including immunogenic compositions include an immunologically effective amount of an immunogenic polypeptide, and other required components as described above.
  • immunologically effective amount refers to an amount administered to an individual as a single dose or as part of a continuous dose that is effective for treatment or prophylaxis. The dosage will vary depending on the health condition and It depends on the physiological condition, the type of individual being treated (e.g., human), the ability of the individual's immune system to synthesize antibodies, the degree of protection required, the formulation of the vaccine, the treating physician's assessment of the medical condition, and other relevant factors. This amount is expected to fall within a relatively wide range and can be determined by routine experimentation.
  • the vaccine composition or immunogenic composition may be prepared as an injectable preparation, such as a liquid solution or suspension; it may also be prepared in a solid form suitable for solution or suspension, liquid excipient, prior to injection.
  • the formulation can also be emulsified or encapsulated in liposomes to enhance the adjuvant effect.
  • the composition can be administered directly to the subject.
  • the subject may be a human or a non-human mammal, preferably a human.
  • the virus-like particles of the invention can be administered directly to an individual using known methods. These vaccines are typically administered using the same route of administration as conventional vaccines and/or mimicking pathogen infection.
  • Routes for administering the pharmaceutical composition or vaccine composition of the present invention include (but are not limited to): intramuscular, subcutaneous, intradermal, intrapulmonary, intravenous, nasal, intravaginal, oral or other parenteral administration routes. Routes of administration can be combined, if necessary, or adjusted according to disease conditions. Vaccine compositions may be administered in single or multiple doses, and may include administration of booster doses to induce and/or maintain immunity.
  • Virus-like particle vaccines should be administered in an "effective amount", that is, the amount of virus-like particles is sufficient to trigger an immune response in the chosen route of administration and can effectively protect the host against new coronavirus infection.
  • each dose of vaccine is sufficient to contain from about 1 ⁇ g to 1000 ⁇ g, preferably from 1 ⁇ g to 100 ⁇ g, more preferably from 10 ⁇ g to 50 ⁇ g of protein or VLP after infection of the host cell.
  • Standard research methods including observation of antibody titers and other responses in subjects can be used to determine the optimal dosage for a particular vaccine.
  • the need for a booster dose can be determined by monitoring the level of immunity provided by the vaccine. After assessment of antibody titers in serum, a booster dose of immunization may be indicated.
  • the immune response to the proteins of the invention can be enhanced by administration of adjuvants and/or immunostimulants.
  • a preferred method is to administer the immunogenic composition by injection via the parenteral (subcutaneous or intramuscular) route.
  • the present invention first discovered that the hemagglutinin skeleton from the first H5 subtype influenza virus strain (such as A/common magpie/Hong Kong/5052/2007) and the hemagglutinin skeleton from the second H5 subtype influenza virus strain (such as A/common magpie/Hong Kong/5052/2007) A/chicken/Netherland/14015526/2014)
  • the recombinant protein of the AS1 epitope mutant (such as amino acid mutations at position 159 and/or 160, H3numbering method) can effectively induce broad-spectrum neutralizing antibodies, thereby effectively preventing Infection with avian influenza viruses (especially strains representative of most of the 10 subtypes of the H5 subtype).
  • the present invention selects the hemagglutinin of the H5N1 subtype avian influenza virus strain A/common magpie/Hong Kong/5052/2007 as the skeleton protein (recognizing only a single epitope: AS1), and combines A/chicken/Netherland/ The AS1 epitope of the 14015526/2014 virus strain was transferred to the A/common magpie/Hong Kong/5052/2007 hemagglutinin protein, replacing the original AS1 epitope, and replacing the Aspartic acid at position 159 of the AS1 epitope.
  • ,Asp,D) and alanine (Alanine,Ala,A) at position 160 were mutated to serine (Serine,Ser,S) and threonine (Threonine,Thr,T) respectively, making it outside the receptor binding site.
  • the hypervariable region of the rim forms an N-linked glycoprotein glycosylation site, introduces N-glycans, exposes conserved epitopes, and induces broad-spectrum neutralizing antibodies.
  • alanine at position 160 is mutated, and alanine at position 160 (Alanine, Ala, A) is mutated into serine (Serine, Ser, S) or threonine (Threonine, Thr, T).
  • the amino acid positions 158, 159 and 160 of the recombinant protein form the "Asn-Asp-Ser/Thr (NDS/T)" sequence, and the asparagine (Asn, Asn) at position 158 of the recombinant protein.
  • N) sites form N-glycans, and the N-glycans are located in the hypervariable region at the outer edge of the receptor binding site.
  • the present invention develops a preparation method for H5 subtype avian influenza broad-spectrum vaccine for the first time.
  • the H5N8 mutant vaccine strain prepared by the present invention can neutralize most of the representative strains of the 10 subtypes of H5 subtype (especially the representative strains that were popular between 1997 and 2014).
  • the hemagglutinin sequence number of A/common magpie/Hong Kong/5052/2007 is the sequence of ACJ26242, and the amino acid sequence of the AS1 site (or the amino acid sequence containing the AS1 site) of A/chicken/Netherland/14015526/2014 is derived from the sequence number. It is the sequence of EPI547678, and the expressed nucleotide sequence of the recombinant protein in the method of the present invention is obtained through artificial synthesis.
  • the pseudoviruses representing the 10 subtypes of the H5 subtype and the HA recombinant pseudovirus used in the present invention were obtained from the Shanghai Pasteur Institute of the Chinese Academy of Sciences.
  • HEK293FT cells are human kidney epithelial cells (Invitrogen, 1600 Faraday Avenue, Carlsbad, CA 92008USA) transfected with the adenovirus E1A gene and simultaneously expressing the SV40 large T antigen. They are used for the preparation and protein expression of pseudoviruses and recombinant influenza viruses.
  • MDCK cells canine kidney cells (American Type Culture Collection, ATCC), used for pseudovirus neutralization experiments.
  • HA titer Serially dilute the influenza virus or virus-like particles 2-fold with physiological saline or PBS. Add 50 ⁇ L of each dilution of the virus to a 96-well U-shaped bottom cell culture plate. Add 50 ⁇ L of 0.5% SPF chicken red blood cells to each well. Mix well, incubate at room temperature for about 30 minutes, observe the red blood cell agglutination phenomenon, and obtain the virus dilution per coagulation unit, which is the hemagglutination titer (HA titer).
  • HA titer hemagglutination titer
  • Plasmids for packaging pseudoviruses include gene expression vector plasmids pCMV/R-HA and pCMV/R-NA (used to express influenza virus HA and NA proteins as pseudovirus envelope proteins, or pCMV-VSV-G for Expression of negative control vesicular stomatitis virus G protein (VSV-G)), packaging vector plasmid pCMV/ ⁇ R8.2 (used to express pseudovirus shell protein) and transfer vector plasmid pHR'CMV-luc (used to express Pseudovirus reporter protein), these four plasmids were assembled into pseudoviruses containing HA and NA proteins or control VSV-G pseudoviruses.
  • Packaging vector plasmid and transfer vector plasmid were donated by Professor Luigi Naldini (University Torino Medical School, Torino, Italy). The plasmid structure is shown in Figure 2.
  • the packaging system of influenza pseudovirus is:
  • VSV-G The system of VSV-G versus pseudovirus is:
  • the plasmid and calcium ions form a uniform precipitate.
  • the supernatant containing the pseudovirus is collected. Centrifuge at 4000 rpm for 5 minutes to remove possible cell debris and filter with a 0.45 ⁇ m filter (Millipore Millex, Cat. No. SLHV033RB). Store the filtered pseudovirus supernatant at -80°C for later use.
  • the relative luciferase activity (RLA) expressed by the transfer vector plasmid pHR'CMV-Luc after transducing MDCK cells with pseudovirions was used as the detection standard for the infection ability of influenza virus pseudoviruses.
  • the method is as follows: Plate MDCK cells into a 96-well flat-bottomed cell culture plate with 5,000 cells in each well. After culturing for 20 hours, add different volumes of pseudovirus supernatant to be tested and culture at 37°C and 5% CO2 . After 65 hours, discard the cell supernatant, wash once with PBS, and follow the instructions of the kit (Promega, Luciferase assay system freezer pack, Cat. No.
  • E4530 add 100 ⁇ L of cell lysis solution, freeze and thaw to fully lyse the cells, and then add 50 ⁇ L of luciferin. Enzyme reaction substrate, the measured relative luciferase activity can visually represent the infection titer of the pseudovirus to be tested.
  • influenza pseudovirus library is used to detect the broad spectrum of immune serum, as shown in Table 6.
  • VSV-G pseudovirus was used as control virus.
  • MDCK cells were transduced with pseudovirions incubated with neutralizing antibodies or serum and then the relative luciferase activity (RLA) expressed by the transfer vector plasmid pHR'CMV-Luc was used as the neutralizing antibody or serum to neutralize the corresponding pseudoviral influenza virus.
  • RLA relative luciferase activity
  • the method is as follows: mix the serially diluted antibody or serum sample to be tested with an appropriate amount of the corresponding influenza virus pseudovirus and incubate it at 37°C. One hour later, add the above mixture to the 96-well cell culture plate that has been seeded with MDCK cells in advance, and culture at 37°C and 5% CO2 .
  • Serum inhibition percentage (relative luciferase value of pseudovirus in complete culture medium - relative luciferase value of pseudovirus in complete culture medium containing serially diluted antibodies)/luciferase of pseudovirus in complete culture medium Relative value ⁇ 100%.
  • the indicator of serum neutralization titer used in this study is the IC50 value, which refers to the serum dilution factor when the relative value of luciferase of the pseudovirus decreases by 50%.
  • the software GraphPad Prism was used to calculate the serum dilution factor and fluorescence.
  • the relative values of the enzymes were fitted according to the Sigma curve and the IC50 value was calculated.
  • the concentration of IC50 is calculated by fitting the Sigma curve of the neutralization titer of serially diluted antibodies or serum samples using GraphPad Prism software.
  • pCMV/R vector plasmid The full-length sequence of hemagglutinin (including the transmembrane region and intracellular region) was After mammalian codon optimization, a company (Nanjing GenScript Biotechnology Co., Ltd.) was entrusted to synthesize the entire gene sequence and insert it into the pCMV/R vector (the map of the constructed hemagglutinin DNA plasmid is shown in Figure 3). Escherichia coli ( JM109), after transformation and clonal amplification, plasmid extraction (QIAGEN, Cat. No.
  • the plasmid information is accurate After everything is correct, aliquot the plasmid and store it at -80°C for later use.
  • VLP virus-like particles
  • the system of influenza virus-like particles is:
  • the system for controlling virus-like particles is
  • the plasmid and calcium ions formed a uniform precipitate.
  • the supernatant containing the pseudovirus is collected. Centrifuge at 4000 rpm for 5 minutes to remove possible cell debris and filter with a 0.45 ⁇ m filter (Millipore Millex, SLHV033RB). Store the filtered pseudovirus supernatant at -80°C for later use.
  • the collected cell supernatant containing the virus was centrifuged and filtered, and then centrifuged at 25,000 rpm and 4°C for 2 hours. Fully dissolve the VLP pellet with PBS.
  • the resuspended VLPs were added to discontinuous sucrose density gradients of 30% and 45% (2 ml each). After centrifugation at 110,000xg for 3 hours at 4°C, you can see two turbid liquid bands (upper fuzzy band & lower fuzzy band) in the centrifuge tube.
  • the upper fuzzy band is at the top of this gradient centrifuge tube, which is mainly composed of Gag VLPs without envelope proteins on the surface and some small amounts of impurity proteins; the lower fuzzy band is mainly VLPs with envelope spike proteins on the surface.
  • hemagglutination test (only applicable to viruses containing hemagglutinin protein). poison-like particles) and enzyme-linked immunosorbent assay (ELISA).
  • the method of hemagglutination test is as described in 1.3, which is used to quantify the envelope protein on the surface of virus-like particles.
  • Enzyme-linked immunosorbent assay is used to quantify the matrix protein of virus-like particles.
  • the specific steps are carried out according to the instructions of the HIV-1 antigen ELISA kit (ZeptoMetrix, Cat. No. 0801200). The specific process is as follows: Take out an appropriate amount of HIV-1P24antigen ELISA kit.
  • mice Female BALB/c mice aged 6-8 weeks were randomly divided into 6 groups, and the mice were immunized on days 0, 21, and 42 respectively. The first and second times were immunized with DNA plasmid expressing HA protein, and each mouse was immunized with 100 ⁇ g plasmid in the hind limb muscle. The third time was immunized with surface membrane proteins HA and NA virus-like particles (VLP), and each mouse was immunized in the abdominal cavity. 512 hemagglutination units were immunized as the DDV immunization group; the control group was immunized twice with empty plasmid, and each mouse was immunized with 100 ⁇ g of plasmid in the hind limb muscles. For booster immunization, VLP containing only HIV-1 gag was used to immunize each mouse with intraperitoneal immunization. .
  • the experimental animals immunized with DDV are mice.
  • DDV immunity Insert the hemagglutinin nucleotide base sequence of H5N1 subtype avian influenza virus strain A/common magpie/Hong Kong/5052/2007 into the CMV/R vector, construct a plasmid, immunize mice and ferrets, and use A/ Common magpie/Hong Kong/5052/2007 hemagglutinin and neuraminidase are used as envelope proteins to prepare virus-like particles to enhance immunity.
  • Neutralizing antibodies induced by hemagglutinin of A/common magpie/Hong Kong/5052/2007 are high against virus strain A/common magpie/Hong Kong/5052/2007 and against virus strain A/Thailand/(KAN-1)/2004
  • the neutralizing activity is low.
  • the recombinant protein immunogen was constructed by exchanging amino acids in different regions of the hemagglutinin of the two strains of viruses, and a HA recombinant pseudovirus in which the head and stem were exchanged (recombination in which the head and stem were exchanged) was constructed.
  • the schematic diagram of HA construction is shown in Figure 5), and pseudoviruses with different epitopes exchanged ( Figure 6). This pseudovirus containing recombinant HA was used to detect changes in the neutralizing activity of immune serum, and the epitopes recognized by neutralizing antibodies and the positions of key amino acids were inferred.
  • hemagglutinin-induced neutralizing antibody of A/common magpie/Hong Kong/5052/2007 targets the hemagglutinin head or the stem.
  • HA pseudovirus The results in Table 8 show that the pseudovirus has a complete structure and has hemagglutination activity.
  • the results in Table 9 show that exchanging the stem will not affect the neutralizing titer of the immune serum, while exchanging the head can cause significant changes in the neutralizing titer of the immune serum.
  • the hemagglutinin head contains four antigenic epitopes (as shown in Figure 7A).
  • the HA recombinant pseudovirus with head epitope exchange between A/common magpie/Hong Kong/5052/2007 and A/Thailand/(KAN-1)/2004 strains.
  • the recombinant pseudovirus is shown in Table 10 The structure is complete and has hemagglutination activity, and can be used to analyze the specific epitopes recognized by immune serum.
  • the present invention compared A/common magpie/Hong Kong/5052/2007
  • the amino acid difference between the hemagglutinin AS1 epitope of the A/Thailand/(KAN-1)/2004 virus strain was found to be only 5 amino acids different (as shown in Figure 7B), which are located in the receptor binding site of the hemagglutinin protein.
  • Positions 158, 159 and 160 are located at the outer edge of the head receptor binding site of the hemagglutinin protein, and positions 158, 159 and 160 and their vicinity are amino acid hypervariable regions (Figure 8).
  • the AS1 epitope of the A/chicken/Netherland/14015526/2014 virus strain was transferred to the blood of A/common magpie/Hong Kong/5052/2007.
  • Aspartic acid (Asp, D) and alanine (Alanine, Ala, A) are mutated into serine (Serine, Ser, S) and threonine (Threonine, Thr, T), at the receptor binding site N-glycans were introduced into the hypervariable region on the outer edge of the point, and the constructed HA recombinant immunogen was named NLAS1HK5052.
  • the protein amino acid sequence is the same as SEQ ID NO.:1, where x is Ser.
  • the "DDV" immunization method was used to immunize mice. Mouse serum was collected 14 days after the last immunization, and the broad spectrum of immune serum was analyzed.

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Abstract

提供了一种H5N8禽流感广谱性疫苗的开发及其应用,具体地,提供了重组蛋白疫苗、灭活疫苗和核酸疫苗制备方法及其应用。实验表明,制备的重组蛋白疫苗、灭活疫苗和核酸疫苗可有效防止禽流感病毒的感染。

Description

H5N8禽流感广谱性疫苗的开发及其应用 技术领域
本发明属于生物医药领域,涉及H5N8禽流感广谱性疫苗的开发及其应用,具体地,本发明是基于一种H5亚型流感病毒毒株的血凝素为骨架蛋白的一种H5N8禽流感广谱性疫苗的开发及其应用。
背景技术
H5N1、H5N6和H5N8高致病性禽流感已经引起了近千人感染,造成半数以上的人死亡。1997年,由H5N1亚型高致病性禽流感A/goose/Guangdong/1/96(GS/GD/1/96)病毒株的HA与H6N1或H9N2病毒的其他基因形成的重组流感病毒在香港引起多人感染。至2020年底共有H5N1高致病性禽流感862人感染,455人死亡,死亡率为52.8%,感染的病例分布在17个国家,这些病例主要分布在亚洲,其次是非洲。H5N6高致病性禽流感在中国有30人感染,6人死亡,死亡率为20%。另外,2020年12月,俄罗斯南部的养殖场7名员工感染了H5N8高致病性禽流感病毒,这是国际上首次发现人感染H5N8禽流感病毒。科研人员从这7名员工身上分离出了该病毒的遗传物质,这7名感染者症状较轻,无人死亡,虽尚未发现人传人现象,但是不排除今后病毒发生变异并导致人传人的可能。现在散发的人类感染H5亚型高致病性禽流感感染病例,致死率超过50%,如果病毒持续进化,具备了持续稳定的人与人之间传播能力,它将引起全球的大流行,给人类的健康带来严重的威胁。
疫苗是H5亚型高致病性禽流感疫情最有效的防控手段。自H5亚型高致病性禽流感大规模流行以来,多种禽用H5亚型高致病性禽流感疫苗被研发出来,包括灭活疫苗、载体疫苗和DNA疫苗等。全球包括我国在内的多个国家也进行了人用H5亚型高致病性禽流感储备疫苗的开发,包括灭活疫苗和载体疫苗。但H5亚型高致病性禽流感的病毒已经进化出了十个亚类,其中,1、2和7亚类则进一步分化出二级亚类、三级亚类等。多个亚类同时流行和新的亚类持续地出现,不同亚类之间、甚至同亚类不同时间和不同地域流行的病毒株之间的血清交叉反应弱,导致现有的禽用和人用H5亚型高致病性禽流感疫苗无法提供的很好的保护效果。
因此,本领域迫切需要开发一种H5亚型禽流感广谱性疫苗。
发明内容
本发明的目的在于提供一种H5亚型禽流感广谱性疫苗。
本发明的第一方面,提供了一种血凝素重组蛋白,所述重组蛋白含有来自第一H5亚型流感病毒毒株的血凝素骨架,来自第二H5亚型流感病毒毒株的AS1表位,所述AS1表位为AS1表位突变型,所述AS1表位突变型在野生型的AS1表位的对应于来自第二H5亚型流感病毒毒株的血凝素序列(氨基酸序列号:EPI547678)中的98位,129-138位,153-161位,183位,186-194位和221-228位氨基酸(H3numbering)的选自下组的氨基酸发生突变:
第159位的天冬氨酸(Aspartic acid,Asp,D);和/或
第160位的丙氨酸(Alanine,Ala,A);
并且,所述第一H5亚型流感病毒毒株包括A/common magpie/Hong  Kong/5052/2007(H5N1);
所述第二H5亚型流感病毒毒株包括A/chicken/Netherland/14015526/2014(H5N8)。
在另一优选例中,所述来自第一H5亚型流感病毒毒株的血凝素骨架氨基酸序列的序列号为ACJ26242。
在另一优选例中,通过159位和160位氨基酸突变,在所述重组蛋白的158位、159位和160位氨基酸位置形成N-连接型糖蛋白糖基化位点“Asn-Ser-Thr(N-S-T)”序列,并且在所述重组蛋白的第158位的天冬酰胺(Asparagine,Asn,N)位点形成N-糖链,且所述N-糖链位于受体结合位点外缘的高变区。
在另一优选例中,通过159位和160位氨基酸突变,160位丙氨酸(Alanine,Ala,A)突变为苏氨酸(Threonine,Thr,T),159位的天冬氨酸(Aspartic acid,Asp,D)突变为除丝氨酸和脯氨酸以外的氨基酸(不包含天冬氨酸),在所述重组蛋白的158位、159位和160位氨基酸位置形成N-连接型糖蛋白糖基化位点“Asn-X-Thr(N-X-T)”序列(X氨基酸选自下组:甘氨酸、丙氨酸、缬氨酸、亮氨酸、异亮氨酸、苯丙胺酸、酪氨酸、色氨酸、苏氨酸、半胱氨酸、蛋氨酸、天冬酰胺、谷氨酰胺、谷氨酸、赖氨酸、精氨酸、组氨酸、或其组合),并且在所述重组蛋白的第158位的天冬酰胺(Asparagine,Asn,N)位点形成N-糖链,且所述N-糖链位于受体结合位点外缘的高变区。
在另一优选例中,通过159位和160位氨基酸突变,160位丙氨酸(Alanine,Ala,A)突变为丝氨酸(Serine,Ser,S),159位的天冬氨酸(Aspartic acid,Asp,D)突变为除丝氨酸和脯氨酸以外的氨基酸(不包含天冬氨酸),在所述重组蛋白的158位、159位和160位氨基酸位置形成N-连接型糖蛋白糖基化位点“Asn-X-Ser(N-X-S)”序列(X氨基酸选自下组:甘氨酸、丙氨酸、缬氨酸、亮氨酸、异亮氨酸、苯丙胺酸、酪氨酸、色氨酸、丝氨酸、苏氨酸、半胱氨酸、蛋氨酸、天冬酰胺、谷氨酰胺、谷氨酸、赖氨酸、精氨酸、组氨酸、或其组合),并且在所述重组蛋白的第158位的天冬酰胺(Asparagine,Asn,N)位点形成N-糖链,且所述N-糖链位于受体结合位点外缘的高变区。
在另一优选例中,通过仅对160位氨基酸进行突变,160位丙氨酸(Alanine,Ala,A)突变为丝氨酸(Serine,Ser,S)或者突变为苏氨酸(Threonine,Thr,T),在所述重组蛋白的158位、159位和160位氨基酸位置形成N-连接型糖蛋白糖基化位点“Asn-Asp-Ser/Thr(N-D-S/T)”序列,并且在所述重组蛋白的第158位的天冬酰胺(Asparagine,Asn,N)位点形成N-糖链,且所述N-糖链位于受体结合位点外缘的高变区。
在另一优选例中,突变后的氨基酸在158,159,160位点形成N-连接型糖蛋白糖基化位点:Asn-X-Ser/Thr(N-X-S/T,其中X为脯氨酸以外的任何氨基酸,包括甘氨酸、丙氨酸、缬氨酸、亮氨酸、异亮氨酸、苯丙胺酸、酪氨酸、色氨酸、丝氨酸、苏氨酸、半胱氨酸、蛋氨酸、天冬酰胺、谷氨酰胺、天冬氨酸、谷氨酸、赖氨酸、精氨酸和组氨酸)。
在另一优选例中,所述突变包括氨基酸的插入、缺失或替换。
在另一优选例中,所述的AS1表位突变型除所述突变(159位和/或160位)外,其余的氨基酸序列与野生型的AS1表位的对应于来自第二H5亚型流感病毒毒株的血凝素序列(氨基酸序列号:EPI547678)中的98位,129-138位,153-161位,183 位,186-194位和221-228位氨基酸(H3numbering)所示的序列相同或基本相同。
在另一优选例中,所述来自第一H5亚型流感病毒毒株的血凝素骨架与ACJ26242所示序列的同源性至少为80%,较佳地至少为85%或90%,更佳地至少为95%,最佳地至少为98%或99%。
在另一优选例中,所述的基本相同是至多有8个(较佳地为1-5个,更佳地为1-3个)氨基酸不相同,其中,所述的不相同包括氨基酸的取代、缺失或添加,并且AS1表位突变型内158氨基酸位点有N-糖链引入。
在另一优选例中,所述重组蛋白具有包含式I结构:
Z1-Z2(I)
式中,Z1为来自第一H5亚型流感病毒毒株A/common magpie/Hong Kong/5052/2007的血凝素骨架;Z2为来自第二H5亚型流感病毒毒株A/chicken/Netherland/14015526/2014的AS1表位;所述AS1表位为AS1表位突变型,所述AS1表位突变型在野生型的AS1表位的对应于来自第二H5亚型流感病毒毒株的血凝素序列(氨基酸序列号:EPI547678)中的98位,129-138位,153-161位,183位,186-194位和221-228位氨基酸(H3numbering)的选自下组的氨基酸发生突变:
第159位的天冬氨酸(Aspartic acid,Asp,D);和/或
第160位的丙氨酸(Alanine,Ala,A);
其中,各“-”独立地为连接肽或肽键。
在另一优选例中,所述重组蛋白选自下组:
(A)具有SEQ ID NO.:1或4所示氨基酸序列的多肽;
(B)具有与SEQ ID NO.:1或4所示氨基酸序列≥80%同源性(优选地,≥90%的同源性;等优选地≥95%的同源性;最优选地,≥97%的同源性,如98%以上,99%以上)的衍生多肽,且所述衍生多肽与衍生前的原始多肽具有基本相同的功能;
(C)对(A)中多肽的氨基酸序列进行一个或多个氨基酸(比如1-10个,较佳地,1-5个,更佳地,1-3个)添加、取代或氨基酸缺失所形成的衍生多肽,所述衍生多肽与衍生前的原始多肽具有基本相同的功能。
在另一优选例中,所述的“基本相同的功能”指所述的衍生多肽具有N-糖链的引入,可免疫产生具有广谱性的中和抗体。
在另一优选例中,所述重组蛋白的氨基酸序列如SEQ ID NO.1或4所示。
在另一优选例中,所述的重组蛋白为具有SEQ ID NO.:1或4所示氨基酸序列的多肽、其活性片段、或其保守性变异多肽。
在另一优选例中,所述重组蛋白与SEQ ID NO.:1或4所示序列的同源性至少为80%,较佳地至少为85%或90%,更佳地至少为95%,最佳地至少为98%或99%。
在另一优选例中,所述重组蛋白为人工合成的或重组的重组蛋白。
在另一优选例中,所述重组蛋白为真核表达系统表达的重组蛋白。
在另一优选例中,所述重组蛋白为酵母细胞表达的重组蛋白。
在另一优选例中,所述重组蛋白为昆虫细胞表达的重组蛋白。
在另一优选例中,所述重组蛋白为嵌合蛋白。
在另一优选例中,所述昆虫细胞选自下组:Sf9、Sf21、Tni、Hi5-Sf细胞、或其组合。
在另一优选例中,所述酵母包括毕赤酵母。
本发明第二方面提供了一种疫苗多肽,所述疫苗多肽包括本发明第一方面所述的重组蛋白。
在另一优选例中,所述的疫苗多肽可激发灵长动物、啮齿动物和家禽产生可以中和H5亚型10个亚类大部分的代表毒株的中和抗体。
在另一优选例中,所述的疫苗多肽所激发产生的中和抗体能够预防感染、阻止病毒入侵和清除体内的流感病毒。
在另一优选例中,所述的疫苗多肽诱导灵长动物,啮齿动物和家禽产生B细胞免疫。
在另一优选例中,所述的灵长动物包括人、非人灵长类动物。
本发明第三方面提供了一种DNA或mRNA疫苗,所述的疫苗含有用于表达本发明第一方面所述的重组蛋白的编码mRNA、以及DNA表达载体。
在另一优选例中,所述的mRNA疫苗的包装载体为鱼精蛋白、纳米颗粒脂质体、化学合成多聚体。
本发明第四方面提供了一种分离的多核苷酸,所述的多核苷酸编码本发明第一方面所述的重组蛋白或本发明第二方面所述的疫苗多肽。
本发明第五方面提供了一种表达载体,所述表达载体含有本发明第四方面所述的多核苷酸。
本发明第六方面提供了一种宿主细胞,所述的宿主细胞含有本发明第五方面所述的表达载体,或者在基因组中整合有本发明第四方面所述的多核苷酸。
在另一优选例中,所述的宿主细胞包括原核细胞和真核细胞。
在另一优选例中,所述的宿主细胞包括酵母、昆虫Hi5-Sf细胞、大肠杆菌、猴来源Vero E6细胞、仓鼠CHO细胞、DC细胞。
本发明第七方面提供了一种H5亚型流感病毒株,所述病毒株的基因组中包含外源性的重组蛋白基因序列,其中,所述重组蛋白基因序列编码本发明第一方面所述的重组蛋白。
在另一优选例中,所述流感病毒是H5N8流感病毒。
本发明第八方面提供了一种药物组合物,所述的组合物含有本发明第一方面所述的重组蛋白、本发明第二方面所述的疫苗多肽或本发明第三方面所述的mRNA或DNA疫苗或本发明第四方面所述的多核苷酸或者本发明第五方面所述的表达载体或者本发明第六方面所述的宿主细胞或本发明第七方面所述的病毒株,以及药学上可接受的载体和/或辅料。
在另一优选例中,所述的药物组合物为疫苗组合物。
在另一优选例中,所述疫苗组合物为单价或多价。
在另一优选例中,所述的药物组合物还含有佐剂,首选各种铝佐剂。
在另一优选例中,所述药物组合物中的重组蛋白、免疫多肽、mRNA或DNA疫苗或病毒株、和佐剂(如铝)的摩尔数或重量比在1:100之间,优选为1:40到1:60之间。
在另一优选例中,所述的药物组合物包括单方药物、复方药物、或协同药物。
在另一优选例中,所述的药物组合物的剂型为液态、固体、或凝胶态。
在另一优选例中,所述的药物组合物用选自下组的方式施用:皮下注射、皮内注射、肌肉注射、静脉注射、腹腔注射、微针注射、口服、或口鼻腔喷入和雾化 吸入。
本发明第九方面提供了一种疫苗组合物,所述的组合物含有本发明第一方面所述的重组蛋白、本发明第二方面所述的疫苗多肽或本发明第三方面所述的mRNA或DNA疫苗或本发明第四方面所述的多核苷酸或者本发明第五方面所述的表达载体或者本发明第六方面所述的宿主细胞或本发明第七方面所述的病毒株,以及免疫学上可接受的载体和/或辅料。
在另一优选例中,所述的疫苗组合物还含有佐剂。
在另一优选例中,所述佐剂包括:颗粒型和非颗粒型佐剂。
在另一优选例中,所述颗粒型佐剂选自下组:铝盐、油包水乳剂、水包油乳剂、纳米颗粒、微小颗粒、脂质体、免疫刺激复合物,或其组合。
另一优选例中,所述非颗粒型佐剂选自下组:胞壁酰二肽及其衍生物、皂苷、脂质A、细胞因子、衍生多糖、细菌毒素,微生物及其产物如分枝杆菌(结核杆菌、卡介苗)、短小杆菌、百日咳杆菌、蜂胶、或其组合。
在另一优选例中,所述的佐剂包括氧化铝、皂苷、Quil A、胞壁酰二肽、矿物油或植物油、基于囊泡的佐剂、非离子嵌段共聚物或DEAE葡聚糖、细胞因子。
在另一优选例中,所述的疫苗组合物包括注射剂型。
本发明第十方面提供了如本发明第一方面所述的重组蛋白或本发明第二方面所述的疫苗多肽或本发明第三方面所述的mRNA或DNA疫苗或本发明第七方面所述的病毒株或本发明第八方面所述的药物组合物或本发明第九方面所述的疫苗组合物的用途,(a)用于制备针对禽流感病毒血凝素的抗体;和/或(b)用于制备预防和/或治疗禽流感病毒感染或其相关疾病的药物。
在另一优选例中,所述禽流感病毒包括H5亚型禽流感病毒。
在另一优选例中,所述禽流感病毒包括H5N8病毒。
在另一优选例中,所述抗体包括针对H5亚型禽流感病毒血凝素的抗体。
在另一优选例中,所述抗体包括针对H5亚型禽流感病毒的抗体。
本发明第十一方面提供了一种制备本发明第一方面所述的重组蛋白的方法,包括步骤:
(i)在适宜条件下培养本发明第六方面所述的宿主细胞,从而表达本发明第一方面所述的重组蛋白;
(ii)纯化所述抗原肽。
在另一优选例中,所述方法步骤(i)中将转化的酵母单菌落分别接种到BMGY培养基中,培养后离心去除上清,用BMMY培养基重悬菌体,28-30℃(优选为29.5℃),诱导培养36-48小时(优选为48小时)。
本发明第十二方面提供了一种产生针对禽流感病毒的免疫反应的方法,包括步骤:给需要的对象施用本发明第一方面所述的重组蛋白、本发明第二方面所述的疫苗多肽、本发明第三方面所述的mRNA或DNA疫苗或本发明第七方面所述的病毒株或本发明第八方面所述的药物组合物或本发明第九方面所述的疫苗组合物。
在另一优选例中,所述的对象包括人或非人哺乳动物。
在另一优选例中,所述的非人哺乳动物包括非人灵长动物(如猴)。
在另一优选例中,所述方法在所述对象中诱导产生针对H5亚型禽流感病毒的中和抗体。
本发明第十三方面提供了一种治疗方法,给需要的对象施用本发明第一方面所述的重组蛋白、本发明第二方面所述的疫苗多肽、本发明第三方面所述mRNA或DNA疫苗、本发明第四方面所述的多核苷酸或者本发明第五方面所述的表达载体或者本发明第六方面所述的宿主细胞或本发明第七方面所述的病毒株或本发明第八方面所述的药物组合物或本发明第九方面所述的疫苗组合物。
在另一优选例中,所述治疗方法包括基因治疗方法。
在另一优选例中,所示治疗方法包括体外使用电穿孔技术转染的人类DC细胞移植,淋巴mRNA疫苗注射。
应理解,在本发明范围内中,本发明的上述各技术特征和在下文(如实施例)中具体描述的各技术特征之间都可以互相组合,从而构成新的或优选的技术方案。限于篇幅,在此不再一一累述。
附图说明
图1为本发明A/common magpie/Hong Kong/5052/2007病毒株血凝素的氨基酸序列。
图2为本发明流感病假病毒制备使用的转移载体、包装载体和表达载体的结构示意图。
图3为本发明构建和表达血凝素的DNA质粒图谱。
图4为本发明血凝素蛋白的空间构象和表位。血凝素蛋白分为头部区域和杆部区域。头部区域有4个表位,分别是AS1、AS2、AS3和AS4。
图5为本发明构建A/common magpie/Hong Kong/5052/2007病毒株血凝素头部和杆部互换的重组假病毒和A/Thailand/(KAN-1)/2004病毒株血凝素头部和杆部互换的重组假病毒示意图。
图6为本发明构建A/common magpie/Hong Kong/5052/2007病毒株血凝素头部表位互换的重组假病毒和A/Thailand/(KAN-1)/2004病毒株血凝素头部表位互换的重组假病毒示意图。
图7为本发明比较A/common magpie/Hong Kong/5052/2007病毒株和A/Thailand/(KAN-1)/2004病毒株血凝素头部不同表位内的氨基酸的比较。
图8为本发明流感血凝素头部氨基酸保守型分析。
具体实施方式
本发明人通过广泛而深入的研究,意外地发现,包含来自第一H5亚型流感病毒毒株(比如A/common magpie/Hong Kong/5052/2007)的血凝素骨架,来自第二H5亚型流感病毒毒株(比如A/chicken/Netherland/14015526/2014)的AS1表位突变型(比如159位和/或160位的氨基酸发生突变)的重组蛋白可有效诱导出广谱的中和抗体,从而有效防止禽流感病毒(尤其是H5亚型的10个亚类大部分的代表毒株)的感染。在此基础上,本发明人完成了本发明。
术语
如本文所用,术语“AxxB”表示第xx位的氨基酸A突变为氨基酸B,例如“D159S”表示第159位的氨基酸D突变为S,以此类推。
术语“H3numbering”表示氨基酸编号使用H3numbering方法。
禽流感病毒
H5亚型高致病性禽流感是由正粘病毒科流感病毒属A型流感病毒引起的一类人兽共患传染病。血凝素(Hemagglutinin,HA)因可以诱导出具有中和活性的抗体,并且这些抗体能够预防病毒感染、阻止病毒入侵和清除体内的流感病毒,是A型流感广谱性疫苗主要的靶蛋白。
在本发明中,将H5N1亚型禽流感病毒株A/common magpie/Hong Kong/5052/2007的血凝素HA作为流感疫苗的骨架(HA序列如图1所示,SEQ ID NO.:2所示),其诱导的中和抗体识别的表位集中,表位内关键氨基酸位于血凝素受体结合区域外缘的158、159和160位点或附近(H3numbering)。流感病毒血凝素158、159和160位点及附近位于受体结合位点的外缘,氨基酸的保守性差,属于血凝素的高突变区。
A/common magpie/Hong Kong/5052/2007病毒株的血凝素AS1表位包含39个氨基酸,如表1所示(H3 numbering)。
表1.A/common magpie/Hong Kong/5052/2007病毒株AS1表位氨基酸及编号
并且,在本发明中,以A/common magpie/Hong Kong/5052/2007的血凝素HA作为骨架蛋白,将其AS1表位用A/chicken/Netherland/14015526/2014病毒株的AS1表位进行替换(AS1表位氨基酸序列如表2所示),并将AS1表位159位置的天冬氨酸(Aspartic acid,Asp,D)和160位置的丙氨酸(Alanine,Ala,A)分别突变为丝氨酸(Serine,Ser,S)和苏氨酸(Threonine,Thr,T),构建重组蛋白免疫原(命名为NLAS1HK5052,氨基酸序列如SEQ ID NO.:1所示)。NLAS1HK5052在受体结合位点外缘的高变区158位天冬酰胺(Asparagine,Asn,N)引入了N-糖链,可以诱导出广谱性的中和抗体。
N-连接型糖蛋白糖基化位点为由3个氨基酸组成的序列子:Asn-X-Ser/Thr(N-X-S/T),其中X为脯氨酸以外的任何氨基酸,包括甘氨酸、丙氨酸、缬氨酸、亮氨酸、异亮氨酸、苯丙胺酸、酪氨酸、色氨酸、丝氨酸、苏氨酸、半胱氨酸、蛋氨酸、天冬酰胺、谷氨酰胺、天冬氨酸、谷氨酸、赖氨酸、精氨酸和组氨酸。N-糖链则是指与蛋白质分子中天冬酰胺残基的酰胺氮相连的聚糖。
表2.A/chicken/Netherland/14015526/2014病毒株的AS1表位氨基酸及编号
(请注意,加粗斜体字表示A/common magpie/Hong Kong/5052/2007血凝素 AS1表位与A/chicken/Netherland/14015526/2014血凝素AS1表位中氨基酸不同的位点)
本发明制备的H5N8突变疫苗株可以中和H5亚型10个亚类大部分的代表毒株(以1997年至2014年间流行的病毒为例,如表3所示)。
表3.H5亚型10个亚类的代表毒株
重组蛋白
本发明提供了一种血凝素重组蛋白NLAS1HK5052,所述重组蛋白含有来自第一H5亚型流感病毒毒株的血凝素骨架,来自第二H5亚型流感病毒毒株的 AS1表位,所述AS1表位为AS1表位突变型,所述AS1表位突变型在野生型的AS1表位的对应于来自第二H5亚型流感病毒毒株的血凝素序列(氨基酸序列号为EPI547678,氨基酸序列如SEQ ID NO.:3所示)中的98位,129-138位,153-161位,183位,186-194位和221-228位氨基酸(H3numbering)的选自下组的氨基酸发生突变:
第159位的天冬氨酸(Aspartic acid,Asp,D);和/或
第160位的丙氨酸(Alanine,Ala,A);
并且,本发明所述第一H5亚型流感病毒毒株包括A/common magpie/Hong Kong/5052/2007(H5N1),来自所述第一H5亚型流感病毒毒株的血凝素骨架序列的序列号为ACJ26242(氨基酸序列如SEQ ID NO.:2所示);
并且,本发明所述第二H5亚型流感病毒毒株包括A/chicken/Netherland/14015526/2014(H5N8)。
A/common magpie/Hong Kong/5052/2007血凝素HA序列:
A/chicken/Netherland/14015526/2014血凝素HA序列:
在本发明中,通过159位和160位氨基酸突变,在所述重组蛋白158位,159位和160位的氨基酸形成“Asn-Ser-Thr(N-S-T)”序列,并且在所述重组蛋白的158位的天冬酰胺(Asparagine,Asn,N)位点形成N-糖链,且所述N-糖链位于受体结合位点外缘的高变区。
在本发明中,通过159和160位置氨基酸的突变,或仅160位置氨基酸的突变形成的N-连接型糖蛋白糖基化位点Asn-X-Ser/Thr(N-X-S/T,其中X为脯氨酸以外的任何氨基酸,包括甘氨酸、丙氨酸、缬氨酸、亮氨酸、异亮氨酸、苯丙胺酸、酪氨酸、色氨酸、丝氨酸、苏氨酸、半胱氨酸、蛋氨酸、天冬酰胺、谷氨酰胺、天冬氨酸、谷氨酸、赖氨酸、精氨酸和组氨酸)均可在第158位的天冬酰胺引入N-糖链,形成N-连接型糖蛋白,且所述N-糖链位于受体结合位点外缘的高变区。
应理解,本发明A/common magpie/Hong Kong/5052/2007血凝素HA序列(SEQ ID NO.:2)、A/chicken/Netherland/14015526/2014血凝素HA序列(SEQ ID NO.:3)和重组蛋白NLAS1HK5052(SEQ ID NO.:1或4)中的氨基酸编号均基于 统一的H3numbering方法作出,便于准确的识别AS1表位氨基酸位点和突变的氨基酸位点,也可避免常规的序列对比技术造成的氨基酸编号错位产生的序列同源性差异。
重组蛋白NLAS1HK5052的氨基酸序列如SEQ ID NO.1或4所示:
Mekivllfaivslvksdhicigyhannsteqvdtimeknvtvthaqdilekthngklcdlngvkplilkdcsvagwllgnpmcdefinvpewsyivekanpandlcypgnfndyeelkhllsrinhfekiqiipkdswsnhetslgvsaacpyqgnssffrnvvwlikknxtyptikksynntnqedllvlwgihhpnnaeeqtnlyqnpttyisigtstlnqrlvpkiatrsqvngqrgridffwtilkpndainfesngnfiapeyaykivkkgdstimkseveygncntrcqtpmgainssmpfhnihpltigecpkyvksnklvlatglrnspqrerrrkrglfgaiagfieggwqgmvdgwygyhhsneqgsgyaadkestqkaidgvtnkvnsiidkmntqfeavgrefnnlerrienlnkkmedgfldvwtynaellvlmenertldfhdsnvknlydkvrlqlrdnakelgngcfefyhkcdnecmesvrngtydypqyseearlkreeisgvklesigtyqilsiystvasslvlaimvaglsswmcsngslqcrici(氨基酸x可以是G、A、V、L、I、F、Y、W、S、T、C、M、N、Q、D、E、K、R、H)(SEQ ID NO.:1)
Mekivllfaivslvksdhicigyhannsteqvdtimeknvtvthaqdilekthngklcdlngvkplilkdcsvagwllgnpmcdefinvpewsyivekanpandlcypgnfndyeelkhllsrinhfekiqiipkdswsnhetslgvsaacpyqgnssffrnvvwlikknxsyptikksynntnqedllvlwgihhpnnaeeqtnlyqnpttyisigtstlnqrlvpkiatrsqvngqrgridffwtilkpndainfesngnfiapeyaykivkkgdstimkseveygncntrcqtpmgainssmpfhnihpltigecpkyvksnklvlatglrnspqrerrrkrglfgaiagfieggwqgmvdgwygyhhsneqgsgyaadkestqkaidgvtnkvnsiidkmntqfeavgrefnnlerrienlnkkmedgfldvwtynaellvlmenertldfhdsnvknlydkvrlqlrdnakelgngcfefyhkcdnecmesvrngtydypqyseearlkreeisgvklesigtyqilsiystvasslvlaimvaglsswmcsngslqcrici(氨基酸x可以是G、A、V、L、I、F、Y、W、S、T、C、M、N、Q、D、E、K、R、H)(SEQ ID NO.:4)
本发明的重组蛋白NLAS1HK5052(SEQ ID NO.:1或4)是合成蛋白或重组蛋白,即可以是化学合成的产物,或使用重组技术从原核或真核宿主(例如,细菌、酵母、植物)中产生。本发明的重组蛋白还可包括或不包括起始的甲硫氨酸残基。
本发明还包括所述重组蛋白的片段、衍生物和类似物。如本文所用,术语“片段”、“衍生物”和“类似物”是指基本上保持所述重组蛋白相同的生物学功能或活性的蛋白。
本发明的重组蛋白片段、衍生物或类似物可以是
(i)有一个或多个保守或非保守性氨基酸残基(优选保守性氨基酸残基)被取代的重组蛋白,而这样的取代的氨基酸残基可以是也可以不是由遗传密码编码的,或(ii)在一个或多个氨基酸残基中具有取代基团的重组蛋白,或(iii)成熟重组蛋白与另一个化合物(比如延长突变蛋白半衰期的化合物,例如聚乙二醇)融合所形成的重组蛋白,或(iv)附加的氨基酸序列融合到此重组蛋白序列而形成的重组蛋白(如前导序列或分泌序列或用来纯化此重组蛋白的序列或蛋白原序列,或与抗原IgG片段的形成的融合蛋白)。根据本文的教导,这些片段、衍生物和类似物属于本领域熟练技术人员公知的范围。本发明中,保守性替换的氨基酸最好根据表4进行氨基酸替换而产生。
表4
本发明的活性重组蛋白具有基本相同的激发免疫反应的免疫原性,且诱导产生的中和抗体具有中和H5亚型10个亚类大部分代表毒株的活性。
优选地,所述重组蛋白为NLAS1HK5052,如SEQ ID NO.:1或4所示。
应理解,本发明重组蛋白与SEQ ID NO.:1或4所示的序列相比,具有较高的同源性(相同性),优选地,所述的重组蛋白与SEQ ID NO.:1或4所示序列的同源性至少为80%,较佳地至少为85%-90%,更佳地至少为95%,最佳地至少为98%,最佳地,≥99%。
此外,还可以对本发明的重组蛋白进行修饰。修饰(通常不改变一级结构)形式包括:体内或体外的重组蛋白的化学衍生形式如乙酰化或羧基化。修饰还包括糖基化,如那些在重组蛋白的合成和加工中或进一步加工步骤中进行糖基化修饰而产生的重组蛋白。这种修饰可以通过将重组蛋白暴露于进行糖基化的酶(如哺乳动物的糖基化酶或去糖基化酶)而完成。修饰形式还包括具有磷酸化氨基酸残基(如磷酸酪氨酸,磷酸丝氨酸,磷酸苏氨酸)的序列。还包括被修饰从而提高了其抗蛋白水解性能或优化了溶解性能的重组蛋白。
术语“编码重组蛋白的多核苷酸”可以是包括编码本发明重组蛋白的多核苷酸,也可以是还包括附加编码和/或非编码序列的多核苷酸;核苷酸包括核糖核酸(RNA,Ribonucleic Acid),和脱氧核糖核酸(DNA,Deoxyribonucleic Acid)。
本发明还涉及上述多核苷酸的变异体,其编码与本发明有相同的氨基酸序列的多肽或重组蛋白的片段、类似物和衍生物。这些核苷酸变异体包括取代变异体、缺失变异体和插入变异体。如本领域所知的,等位变异体是一个多核苷酸的替换形 式,它可能是一个或多个核苷酸的取代、缺失或插入,但不会从实质上改变其编码的重组蛋白的功能。
本发明还涉及与上述的序列杂交且两个序列之间具有至少50%,较佳地至少70%,更佳地至少80%相同性的多核苷酸。本发明特别涉及在严格条件(或严紧条件)下与本发明所述多核苷酸可杂交的多核苷酸。在本发明中,“严格条件”是指:(1)在较低离子强度和较高温度下的杂交和洗脱,如0.2×SSC,0.1%SDS,60℃;或(2)杂交时加有变性剂,如50%(v/v)甲酰胺,0.1%小牛血清/0.1%Ficoll,42℃等;或(3)仅在两条序列之间的相同性至少在90%以上,更好是95%以上时才发生杂交。
本发明的重组蛋白和多核苷酸优选以分离的形式提供,更佳地,被纯化至均质。
本发明多核苷酸全长序列通常可以通过PCR扩增法、重组法或人工合成的方法获得。对于PCR扩增法,可根据本发明所公开的有关核苷酸序列,尤其是开放阅读框序列来设计引物,并用市售的cDNA库或按本领域技术人员已知的常规方法所制备的cDNA库作为模板,扩增而得有关序列。当序列较长时,常常需要进行两次或多次PCR扩增,然后再将各次扩增出的片段按正确次序拼接在一起。
一旦获得了有关的序列,就可以用重组法来大批量地获得有关序列。这通常是将其克隆入载体,再转入细胞,然后通过常规方法从增殖后的宿主细胞中分离得到有关序列。
此外,还可用人工合成的方法来合成有关序列,尤其是片段长度较短时。通常,通过先合成多个小片段,然后再进行连接可获得序列很长的片段。
目前,已经可以完全通过化学合成来得到编码本发明的蛋白(或其片段,或其衍生物)的DNA序列。然后可将该DNA序列引入本领域中已知的各种现有的DNA分子(或如载体)和细胞中。此外,还可通过化学合成将突变引入本发明的蛋白序列中。
应用PCR技术扩增DNA/RNA的方法被优选用于获得本发明的多核苷酸。特别是很难从文库中得到全长的cDNA时,可优选使用RACE法(RACE-cDNA末端快速扩增法),用于PCR的引物可根据本文所公开的本发明的序列信息适当地选择,并可用常规方法合成。可用常规方法如通过凝胶电泳分离和纯化扩增的DNA/RNA片段。
疫苗多肽
在本发明中,“本发明表位肽”、“本发明疫苗多肽”、“本发明多肽”可互换使用,指符合本发明第二方面中所述的疫苗多肽。
在本发明中,疫苗多肽还包括其他形式,例如药学上可接受的盐、偶联物、或融合蛋白。
在本发明中,疫苗多肽包括对SEQ ID NO.:1或4所示的序列进行一个或多个(如1-5个,优选地1-3个)氨基酸添加、一个或多个(如1-5个,优选地1-3个)氨基酸的取代和/或1-3个氨基酸缺失所形成的衍生多肽,所述衍生多肽与衍生前的原始多肽具有基本相同的功能。
优选地,疫苗多肽包括对SEQ ID NO.:1或4所示的序列经过1-3个氨基酸添加(优选添加在N端或C端)、和/或1-2个氨基酸的取代(优选保守性氨基酸替换)并仍具有与衍生前的原始多肽具有基本相同的功能。
优选地,所述的保守性氨基酸替换根据表5进行氨基酸替换。
表5
如本文所用,“分离的”是指物质从其原始环境中分离出来(如果是天然的物质,原始环境即是天然环境)。如活体细胞内的天然状态下的多肽是没有分离纯化的,但同样的多肽如从天然状态中同存在的其他物质中分开,则为分离纯化的。
如本文所用,“分离的肽”是指本发明多肽基本上不含天然与其相关的其它蛋白、脂类、糖类或其它物质。本领域的技术人员能用标准的蛋白质纯化技术纯化本发明多肽。基本上纯化的多肽(融合蛋白)在非还原聚丙烯酰胺凝胶上能产生单一的主带。
本发明的多肽可以是重组多肽、或合成多肽,优选合成多肽。
在本发明中,当疫苗多肽的序列较短(如≤70aa,更佳地≤60aa时),可用化学方法直接合成相关肽序列。
当疫苗多肽的序列较长或以融合蛋白形式提供疫苗多肽时,也可以用重组法来大批量地获得相关肽序列。这通常是将编码所述抗原多肽或其融合蛋白的编码序列克隆入载体,再转入细胞,然后通过常规方法从增殖后的宿主细胞中分离得到相关的抗原肽或融合蛋白。
mRNA疫苗、DNA疫苗或VLPs疫苗
本发明还提供了用于预防H5亚型禽流感病毒的mRNA疫苗、DNA疫苗或VLPs疫苗。
mRNA疫苗是一种体外制备的具有翻译活性的RNA,其主要结构包括5'UTR和3'UTR以及含有表达本发明的重组蛋白NLAS1HK5052(SEQ ID NO.:1或4)的开放读码框。相比于DNA疫苗,它不需要进入细胞核无整合到基因组上的风险。典型地,mRNA疫苗的方法包括:根据NLAS1HK5052(SEQ ID NO.:1或4)的氨基酸序列,通过PCR方法或人工合成方法构建模板并体外转录得到mRNA初产物,进一步加帽、加尾等获得结构完整的mRNA,通过递送系统进入体内。
DNA疫苗是一种含有NLAS1HK5052(SEQ ID NO.:1或4)蛋白开放读码框的重组真核表达载体,外源NLAS1HK5052(SEQ ID NO.:1或4)基因可在活体细胞内进行转录翻译表达,诱导机体特异性的体液和细胞免疫应答。DNA序列编码的仅是单一的一段蛋白基因,基本没有毒性逆转的可能,是可注射的DNA分子。典型地,DNA疫苗的方法包括:根据重组蛋白NLAS1HK5052(SEQ ID NO.:1或4)的氨基酸序列,通过PCR方法或人工合成方法,构建模版序列,并将序列与目标载体相连,形成能被宿主细胞摄取并在体内转录和翻译表达相应NLAS1HK5052重组蛋白(SEQ ID NO.:1或4)的DNA疫苗。
VLPs(virus-like particles)为不含有病毒核酸的病毒样颗粒,在形态结构上与天然的病毒颗粒相似,但不具有感染性,具有很强的免疫原性和生物活性。具有安全、高效的特点。典型地,VLPs疫苗的方法包括:含有编码重组蛋白NLAS1HK5052(SEQ ID NO.:1或4)的基因表达载体质粒、含有编码A/chicken/Netherland/14015526/2014神经酰胺(NA)的基因表达载体、转移载体质粒和包装载体质粒,共转染细胞制得。
应理解,一个氨基酸可能有多种碱基可能,重组蛋白NLAS1HK5052(SEQ ID NO.:1或4)对应的核苷酸序列可能有很多种,但mRNA疫苗、DNA疫苗和含有重组蛋白NLAS1HK5052(SEQ ID NO.:1或4)编码序列的表达载体,最后在体内翻译表达出的蛋白氨基酸序列与NLAS1HK5052(SEQ ID NO.:1或4)的氨基酸序列一致,或者同源性至少为80%,较佳地至少为85%-90%,更佳地至少为95%,最佳地至少为98%,最佳地,≥99%。且相应的翻译蛋白AS1表位内有N-糖链的引入。
灭活疫苗或减毒疫苗
本发明还提供了用于预防H5亚型禽流感病毒的灭活疫苗。
灭活疫苗是指通过对病毒或细菌进行培养,然后使用物理(如加热)或化学试剂(如β-丙内酯)将其灭活,使其丧失感染性或毒性,但仍保持免疫原性。灭活疫苗可以由整个病毒或细菌组成,也可由它们的裂解片段组成为裂解疫苗,并进一步纯化,直至疫苗仅仅包含所需的抗原成分。减毒疫苗则是指病原体经过各种处理后,病原微生物毒性减弱,但仍保留其免疫原性。
典型的,灭活疫苗和减毒疫苗的方法包括根据H5亚型禽流感病毒的核苷酸序列,利用反向遗传技术,通过质粒共转染细胞,获得禽流感病毒,并进一步通过细胞或者鸡胚进行病毒扩增后进行灭活或处理,从而使病毒的感染性(或毒性)丧失或减弱。应理解,在本发明的一个优选例中,利用反向遗传技术获得的流感病毒的血凝素蛋白为重组蛋白,氨基酸序列与NLAS1HK5052(SEQ ID NO.:1或4)的氨基酸序列一致,或者同源性至少为80%,较佳地至少为85%-90%,更佳地至少为95%,最佳地至少为98%,最佳地,≥99%。 且相应的翻译蛋白AS1表位内有N-糖链的引入。
载体和宿主细胞
本发明还提供了一种包含本发明的重组蛋白编码序列的载体,以及含所述载体的宿主细胞。
在本发明的一个优选例中,所述载体具有表达所述重组蛋白基因的表达盒,所述表达盒从5’-3’依次具有下述元件:启动子,重组蛋白基因,和终止子。
本领域的普通技术人员可以使用的常规方法获得所述重组蛋白的上述优化基因序列,例如全人工合成或PCR法合成。一种优选的合成法为不对称PCR法。用于PCR的引物可根据本文所公开的本发明的序列信息适当地选择,并可用常规方法合成。可用常规方法如通过凝胶电泳分离和纯化扩增的DNA/RNA片段。
本发明的多核苷酸序列可以通过常规的重组DNA技术,表达或生产目的蛋白(重组蛋白),包括步骤:
(1)用编码本发明蛋白的多核苷酸(或变异体),或用含有该多核苷酸的重组表达载体转化或转导合适的宿主细胞,较佳地为酵母。
(2)在合适的培养基中培养宿主细胞;
(3)从培养基或细胞中分离、纯化蛋白质。
本领域的技术人员熟知的方法能用于构建含本发明蛋白的编码DNA序列和合适的转录/翻译控制信号的表达载体,优选市售的载体如pPinkαHC或pMT/BiP/V5-HisA。这些方法包括体外重组DNA技术、DNA合成技术、体内重组技术等。所述的DNA序列可有效连接到表达载体中的适当启动子上,以指导mRNA合成。表达载体还包括翻译起始用的核糖体结合位点和转录终止子。此外,表达载体优选包含一个或多个选择性标记基因,以提供用于选择转化的宿主细胞的表型性状。
包含上述DNA序列以及适当启动子或者控制序列的载体,可以用于转化适当的宿主细胞,表达目的蛋白。能够表达本发明重组蛋白的宿主细胞可以是原核细胞,如大肠杆菌;或是低等真核细胞,如酵母细胞(毕赤酵母、酿酒酵母);或是高等真核细胞,如昆虫细胞;优选为酵母细胞。用重组DNA转化宿主细胞可用本领域技术人员熟知的常规技术进行。工程细胞可以是快速利用甲醇型(Mut+)或慢速利用甲醇型(Muts)。
工程细胞的培养和目的蛋白发酵生产
在获得工程细胞后,便可在适合的条件下培养工程细胞,表达本发明的基因序列所编码的蛋白。根据宿主细胞的不同,培养中所用的培养基可选自各种常规培养基,在适于宿主细胞生长的条件下进行培养。当宿主细胞生长到适当的细胞密度后,用合适的方法(如温度转换或化学诱导)诱导选择的启动子,将细胞再培养一段时间。
在本发明中,可采用常规的发酵条件。代表性的条件包括(但并不限于):
(a)就温度而言,本发明的重组蛋白的发酵及诱导温度保持在28-30℃;
(b)就诱导期的pH值而言,诱导期pH控制在3-9;
(c)就溶氧(DO)而言,DO控制在20-90%,溶氧的维持可以用氧气/空气混合气体的通入来解决;
(d)就补料而言,补料种类宜包括甘油、甲醇、葡萄糖等碳源,可单独补料或混合补料。
工程细胞表达目的蛋白可以采用层析技术进行纯化。层析技术包括阳离子交换层析、阴离子交换层析、凝胶过滤层析、疏水层析、亲和层析等技术。常用的层析方法包括:
1.阴离子交换层析
阴离子交换层析介质包括(但不限于):Q-Sepharose、DEAE-Sepharose。如果发酵样品的盐浓度较高,影响与离子交换介质的结合,则在进行离子交换层析前需降低盐浓度。样品可以用稀释、超滤、透析、凝胶过滤层析等手段进行平衡缓冲液的更换,直至与对应的离子交换柱平衡液系统相似,然后上样,进行盐浓度或pH的梯度洗脱。
2.疏水层析
疏水层析介质包括(但不限于):Phenyl-Sepharose、Butyl-Sepharose、Octyle-Sepharose。样品通过添加NaCl、(NH4)2SO4等方式提高盐浓度,然后上样,通过降低盐浓度方法洗脱。通过疏水层析除去疏水性有较大差异的杂蛋白。
3.凝胶过滤层析
疏水层析介质包括(但不限于):Sephacryl、Superdex、Sephadex类。通过凝胶过滤层析更换缓冲体系,或进一步精纯。
4.亲和层析
亲和层析介质包括(但不限于):HiTrapTMHeparin HP Columns。
制备方法
本发明的重组蛋白(多肽)可以是重组多肽或合成多肽。本发明的多肽可以是化学合成的,或重组的。相应地,本发明多肽可用常规方法人工合成,也可用重组方法生产。
一种优选的方法是使用液相合成技术或固相合成技术,如Boc固相法、Fmoc固相法或是两种方法联合使用。固相合成可快速获得样品,可根据目的肽的序列特征选用适当的树脂载体及合成系统。例如,Fmoc系统中优选的固相载体如连接有肽中C端氨基酸的Wang树脂,Wang树脂结构为聚苯乙烯,与氨基酸间的手臂是4-烷氧基苄醇;用25%六氢吡啶/二甲基甲酰胺室温处理20分钟,以除去Fmoc保护基团,并按照给定的氨基酸序列由C端逐个向N端延伸。合成完成后,用含4%对甲基苯酚的三氟乙酸将合成的胰岛素原相关肽从树脂上切割下来并除去保护基,可过滤除树脂后乙醚沉淀分离得到粗肽。将所得产物的溶液冻干后,用凝胶过滤和反相高压液相层析法纯化所需的肽。当使用Boc系统进行固相合成时,优选树脂为连接有肽中C端氨基酸的PAM树脂,PAM树脂结构为聚苯乙烯,与氨基酸间的手臂是4-羟甲基苯乙酰胺;在Boc合成系统中,在去保护、中和、偶联的循环中,用TFA/二氯甲烷(DCM)除去保护基团Boc并用二异丙基乙胺(DIEA/二氯甲烷中和。肽链缩合完成后,用含对甲苯酚(5-10%)的氟化氢(HF),在0℃下处理1小时,将肽链从树脂上切下,同时除去保护基团。以50-80%乙酸(含少量巯基乙醇)抽提肽,溶液冻干后进一 步用分子筛Sephadex G10或Tsk-40f分离纯化,然后再经高压液相纯化得到所需的肽。可以使用肽化学领域内已知的各种偶联剂和偶联方法偶联各氨基酸残基,例如可使用二环己基碳二亚胺(DCC),羟基苯骈三氮唑(HOBt)或1,1,3,3-四脲六氟磷酸酯(HBTU)进行直接偶联。对于合成得到的短肽,其纯度与结构可用反相高效液相和质谱分析进行确证。
在一实施方式中,本发明的重组蛋白,按其序列,采用固相合成的方法制备,行高效液相色谱纯化,获得高纯度目的肽冻干粉,-20℃贮存。
另一种方法是用重组技术产生本发明多肽。通过常规的重组DNA技术,可利用本发明的多核苷酸来表达或生产本发明的抗原肽。一般来说有以下步骤:
(1).用本发明的重组蛋白的多核苷酸(或变异体),或用含有该多核苷酸的重组表达载体转化或转导合适的宿主细胞;
(2).在合适的培养基中培养的宿主细胞;
(3).从培养基或细胞中分离、纯化蛋白质。
重组多肽可在细胞内、或在细胞膜上表达、或分泌到细胞外。如果需要,可利用其物理的、化学的和其它特性通过各种分离方法分离和纯化重组的蛋白。这些方法是本领域技术人员所熟知的。这些方法的例子包括但并不限于:常规的复性处理、用蛋白沉淀剂处理(盐析方法)、离心、渗透破菌、超处理、超离心、分子筛层析(凝胶过滤)、吸附层析、离子交换层析、高效液相层析(HPLC)和其它各种液相层析技术及这些方法的结合。
由于本发明多肽较短,因此可以考虑将多个多肽串联在一起,重组表达后获得多聚体形式的表达产物,然后通过酶切等方法形成所需的小肽。
制备疫苗组合物
本发明还提供了一种制备疫苗组合物的方法,具体地,包括步骤:
将本发明制备的重组蛋白与药学上可接受的疫苗佐剂混合,从而形成疫苗组合物。
在另一优选例中,所述的佐剂为铝佐剂、GLA佐剂,较佳的为铝佐剂。
组合物和施用方法
本发明还提供了一种组合物,所述组合物含有:(i)用本发明方法制备的重组蛋白或疫苗多肽,以及(ii)药学上或免疫学上可接受的赋形剂或佐剂。本发明中,术语“含有”表示各种成分可一起应用于或存在于本发明的组合物中。因此,术语“主要由...组成”和“由...组成”包含在术语“含有”中。
本发明的组合物包括药物组合物和疫苗组合物。本发明的组合物可以是单价的,也可以是多价的。
本发明的药物组合物或疫苗组合物可制备成各种常规剂型,其中包括(但并不限于):注射剂、粒剂、片剂、丸剂、栓剂、胶囊、悬浮液、喷雾剂等。
(i)药物组合物
本发明的药物组合物包括有效量的用本发明方法制备的重组蛋白或疫苗多肽,所述重组蛋白或疫苗多肽可以是单价的,也可以是多价的。
本文所用的术语“有效量”指治疗剂治疗、缓解或预防目标疾病或状况的量, 或是表现出可检测的治疗或预防效果的量。该效果可通过例如抗原水平来检测。治疗效果也包括生理性症状的减少。对于某一对象的精确有效量取决于该对象的体型和健康状况、病症的性质和程度、以及选择给予的治疗剂和/或治疗剂的组合。因此,预先指定准确的有效量是没用的。然而,对于某给定的状况而言,可以用常规实验来确定该有效量。
为了本发明的目的,有效的剂量为给予个体约0.2μg/千克至2μg/千克。
药物组合物还可含有药学上可接受的载体。术语“药学上可接受的载体”指用于治疗剂(例如重组蛋白或其它治疗剂)给药的载体。该术语指这样一些药剂载体:它们本身不诱导产生对接受该组合物的个体有害的抗体,且给药后没有过分的毒性。合适的载体可以是大的、代谢缓慢的大分子,如蛋白质、多糖、聚乳酸(polylactic acid)、聚乙醇酸等。这些载体是本领域普通技术人员所熟知的。在Remington’s Pharmaceutical Sciences(Mack Pub.Co.,N.J.1991)中可找到关于药学上可接受的载体或赋形剂的充分讨论。
组合物中药学上可接受的载体可包括液体,如水、盐水、甘油和乙醇。另外,这些载体中还可能存在辅助性的物质,如润湿剂或乳化剂、pH缓冲物质等。通常,可将组合物制成可注射剂,例如液体溶液或悬液;还可制成在注射前适合配入溶液或悬液、液体赋形剂的的固体形式。脂质体也包括在药学上可接受的载体的定义中。
(ii)疫苗组合物
本发明的疫苗组合物可以是预防性的(即预防感染),也可以是治疗性的。所述的疫苗组合物包含免疫性抗原(包括本发明蛋白或自组装的病毒样颗粒),并且通常与“药学上可接受的载体”组合,这些载体包括本身不诱导产生对接受该组合物的个体有害的抗体的任何载体。合适的载体通常是大的、代谢缓慢的大分子,如蛋白质、多糖、聚乳酸、聚乙醇酸、氨基酸聚合物、氨基酸共聚物、脂质凝集物(如油滴或脂质体)等。这些载体是本领域普通技术人员所熟知的。另外,这些载体可起免疫刺激剂(“佐剂”)作用。另外,抗原也可以和细菌类毒素(如白喉、破伤风、霍乱、幽门螺杆菌等病原体的类毒素)偶联。
增强免疫组合物效果的优选佐剂包括但不限于:(1)铝盐(alum),如氢氧化铝、磷酸铝、硫酸铝等;(2)水包油型乳剂配方,例如,(a)MF59(参见WO90/14837),(b)SAF,和(c)RibiTM佐剂系统(RAS)(Ribi Immunochem,Hamilton,MT),(3)皂素佐剂;(4)Freund完全佐剂(CFA)和Freund不完全佐剂(IFA);(5)细胞因子,如白介素(如IL-1、IL-2、IL-4、IL-5、IL-6、IL-7、IL-12等)、干扰素(如γ干扰素)、巨噬细胞集落刺激因子(M-CFS)、肿瘤坏死因子(TNF)等;(6)细菌ADP-核糖基化毒素(如霍乱毒素CT,百日咳毒素PT或大肠杆菌热不稳定毒素LT)的脱毒变异体,参见例如WO93/13302和WO92/19265;以及(7)作为免疫刺激剂来增强组合物效果的其它物质。
包括免疫原性组合物在内的疫苗组合物(例如,可包括抗原、药学上可接受的载体以及佐剂),通常含有稀释剂,如水,盐水,甘油,乙醇等。另外,辅助性物质,如润湿剂或乳化剂、pH缓冲物质等可存在于这类运载体中。
更具体地,包括免疫原性组合物在内的疫苗,包含免疫学有效量的免疫原性多肽,以及上述其它所需的组分。“免疫学有效量”指以单剂或连续剂一部分给予个体的量对治疗或预防是有效的。该用量可根据所治疗个体的健康状况和 生理状况、所治疗个体的类别(如人)、个体免疫系统合成抗体的能力、所需的保护程度、疫苗的配制、治疗医师对医疗状况的评估、及其它的相关因素而定。预计该用量将在相对较宽的范围内,可通过常规实验来确定。
通常,可将疫苗组合物或免疫原性组合物制成可注射剂,例如液体溶液或悬液;还可制成在注射前适合配入溶液或悬液、液体赋形剂的固体形式。该制剂还可乳化或包封在脂质体中,以增强佐剂效果。
(iii)给药途径和剂量
所述组合物可以直接给予对象。对象可以是人或非人哺乳动物,较佳地为人。当用作疫苗时,可用已知的方法将本发明的病毒样颗粒直接施用于个体。通常采用与常规疫苗相同的施用途径和/或模拟病原体感染路径施用这些疫苗。
给予本发明药物组合物或疫苗组合物的途径包括(但并不限于):肌内、皮下、皮内、肺内、静脉内、经鼻、阴道内、经口服或其它肠胃外给药途径。如果需要,可以组合给药途径,或根据疾病情况进行调节。疫苗组合物可以单剂量或多剂量给予,且可以包括给予加强剂量以引发和/或维持免疫力。
应以“有效量”给予病毒样颗粒疫苗,即病毒样颗粒的量在所选用的给药路径中足以引发免疫应答,能有效促使保护宿主抵抗新型冠状病毒感染。
在各疫苗剂份中所选用的病毒样颗粒的量,是按可引发免疫保护性应答而无明显的副作用的量而定。通常,在感染宿主细胞后,各剂的疫苗足以含有约1μg-1000μg,较佳地为1μg-100μg,更佳地10μg-50μg蛋白质或VLP。可用包括观察对象中的抗体滴定度和其它反应的标准研究方法来确定具体疫苗的最佳用量。可通过监控疫苗提供的免疫力水平来确定是否需要增强剂量。在评估了血清中的抗体滴定度后,可能需要选用增强剂量免疫接种。施用佐剂和/或免疫刺激剂就可提高对本发明的蛋白质的免疫应答。优选方法是从肠胃外(皮下或肌内)途径通过注射给予免疫原性组合物。
本发明的主要优点在于:
(1)本发明首次发现包含来自第一H5亚型流感病毒毒株(比如A/common magpie/Hong Kong/5052/2007)的血凝素骨架,来自第二H5亚型流感病毒毒株(比如A/chicken/Netherland/14015526/2014)的AS1表位突变型(比如159位和/或160位的氨基酸发生突变,H3numbering方法)的重组蛋白可有效诱导出广谱的中和抗体,从而有效防止禽流感病毒(尤其是H5亚型的10个亚类大部分的代表毒株)的感染。
(2)本发明首次选择了H5N1亚型禽流感病毒株A/common magpie/Hong Kong/5052/2007的血凝素为骨架蛋白(仅识别单个表位:AS1),将A/chicken/Netherland/14015526/2014病毒株AS1表位转移至A/common magpie/Hong Kong/5052/2007血凝素蛋白上,替换原有的AS1表位,并将AS1表位159位置的天冬氨酸(Aspartic acid,Asp,D)和160位置的丙氨酸(Alanine,Ala,A)分别突变为丝氨酸(Serine,Ser,S)和苏氨酸(Threonine,Thr,T),使得在受体结合位点外缘的高变区形成N-连接型糖蛋白糖基化位点,引入N-糖链,使保守表位暴露出来,诱导出广谱的中和抗体。
(3)本发明通过仅对160位氨基酸进行突变,160位丙氨酸(Alanine,Ala,A)突变为丝氨酸(Serine,Ser,S)或者突变为苏氨酸(Threonine,Thr,T),在所 述重组蛋白的158位、159位和160位氨基酸位置形成“Asn-Asp-Ser/Thr(N-D-S/T)”序列,并且在所述重组蛋白的第158位的天冬酰胺(Asparagine,Asn,N)位点形成N-糖链,且所述N-糖链位于受体结合位点外缘的高变区。
(4)本发明首次开发了一种H5亚型禽流感广谱性疫苗的制备方法。本发明制备的H5N8突变疫苗株可以中和H5亚型10个亚类大部分的代表毒株(尤其是1997年至2014年间流行的代表毒株)。
下面结合具体实施例,进一步阐述本发明。应理解,这些实施例仅用于说明本发明而不用于限制本发明的范围。下列实施例中未注明具体条件的实验方法,通常按照常规条件,例如Sambrook等人,分子克隆实验指南(New York:Cold Spring Harbor Laboratory Press,1989);或按照制造厂商所建议的条件。除非另外说明,否则百分比和份数按重量计算。
以下实施例中所用的实验材料和试剂如无特别说明均可从市售渠道获得。
A/common magpie/Hong Kong/5052/2007血凝素序列号为ACJ26242的序列,A/chicken/Netherland/14015526/2014的AS1位点氨基酸序列(或包含AS1位点的氨基酸序列)来源自序列号为EPI547678的序列,本发明方法中的重组蛋白通过人工合成方式获得表达的核苷酸序列。本发明使用的H5亚型10个亚类的代表毒株的假病毒以及HA重组假病毒均获自中国科学院上海巴斯德研究所。
1.材料
1.1.细胞模型
HEK293FT细胞是转染腺病毒E1A基因并同时表达SV40大T抗原的人肾上皮细胞(Invitrogen,1600Faraday Avenue,Carlsbad,CA 92008USA),用于假病毒和重组流感病毒制备和蛋白表达。
MDCK细胞:犬肾细胞(American Type Culture Collection,ATCC),用于假病毒中和实验。
实验中所用细胞支原体检测均为阴性,细胞培养条件:37℃,5%CO2
1.2.动物模型
6-8周雌性BALB/c小鼠(上海灵畅生物科技有限公司,SPF级)。
1.3.血凝实验
将流感病毒或病毒样颗粒用生理盐水或PBS连续2倍稀释,每个稀释度的病毒稀释度取50μL加入到96孔U型底细胞培养板,每孔加入50μL的0.5%SPF鸡血红细胞并混匀,室温孵育约30分钟后观察红细胞凝集现象,并得到一个凝血单位时的病毒稀释度,即为血凝效价(HA titer)。
1.4.流感病毒假病毒的制备和检测
1.4.1.流感假病毒和对照假病毒的制备(磷酸钙介导的质粒DNA转染方法)
在T75细胞培养瓶(Thermo Fisher,货号156499)中铺入9×106个HEK293FT细胞过夜培养,18小时后给细胞置换新的15ml培养液,2小时后加入转染质粒。
包装假病毒的质粒包括基因表达载体质粒pCMV/R-HA和pCMV/R-NA(用于表达流感病毒HA和NA蛋白作为假病毒的囊膜蛋白,或pCMV-VSV-G用于 表达阴性对照的水泡性口炎病毒的G蛋白(VSV-G))、包装载体质粒pCMV/ΔR8.2(用于表达假病毒的壳蛋白)和转移载体质粒pHR’CMV-luc(用于表达假病毒的报告基因蛋白),这四个质粒组装成含有HA和NA蛋白的假病毒或对照VSV-G假病毒。包装载体质粒和转移载体载体质粒由Luigi Naldini教授(University Torino Medical School,Torino,Italy)赠送。质粒结构如图2所示。
流感假病毒的包装体系为:
18.9μg转移载体质粒pHR’CMV-Luc
18.9μg包装载体质粒pCMVΔR8.2
2.7μg血凝素表达载体质粒pCMV/R-HA
0.675μg神经氨酸酶表达载体质粒pCMV/R-NA
67.5μL CaCl2(2.5M)溶液
加入ddH2O至675μL的体积,然后逐滴加入675μL的2×HEPES缓冲液(PH值7.10),加入过程中用移液器轻吹混匀。
VSV-G对照假病毒的体系为:
18.9μg转移载体质粒pHR’CMV-Luc
18.9μg包装载体质粒pCMVΔR8.2
2.7μgVSV-G囊膜质粒pCMV-VSV-G
67.5μL CaCl2(2.5M)溶液
加入ddH2O至675μL的体积,然后逐滴加入675μL的2×HEPES缓冲液(PH值7.10),加入过程中用移液器轻吹混匀。
室温静置约20分钟后,质粒和钙离子形成颗粒均一沉淀物,将含沉淀物的混合液体逐滴均匀地加入HEK293FT细胞中。细胞培养16-18小时后,置换新鲜培养液并加入100μM的丁酸钠作用6~8小时,再次置换15ml新鲜培养液并继续培养20小时左右,收集含有假病毒的上清。在4000rpm离心5分钟,去除可能含有的细胞残渣后用0.45μm的滤器(Millipore Millex,货号SLHV033RB)过滤,将过滤好的假病毒上清-80℃保存备用。
1.4.2.流感假病毒和对照假病毒的定量
实验中以假病毒颗粒转导MDCK细胞后转移载体质粒pHR’CMV-Luc表达出的中相对荧光素酶活性(Relative Luciferase Activity,RLA)作为流感病毒假病毒感染能力的检测标准。方法如下:将MDCK细胞铺入96孔平底细胞培养板,每孔5000个细胞,培养20小时后加入不同体积的待测假病毒上清,37℃,5%CO2培养。65小时后弃去细胞上清,用PBS清洗1次后按照试剂盒(Promega,Luciferase assay system freezer pack,货号E4530)说明书操作:加入100μL细胞裂解液,冻融使细胞充分裂解后加入50μL荧光素酶反应底物,测得的相对荧光素酶活性可以直观表示待测假病毒的感染效价高低。
1.4.3.流感假病毒库的构建
流感假病毒库,用于检测免疫血清的广谱性,具体如表6所示。
表6构建的H5亚型流感假病毒库

VSV-G假病毒用作对照病毒。
1.5流感假病毒中和实验
实验以中和抗体或血清孵育过后的假病毒颗粒转导MDCK细胞后转移载体质粒pHR’CMV-Luc表达出的相对荧光素酶活性(RLA)作为该中和抗体或血清中和对应流感病毒假病毒检测标准。方法如下:将系列稀释的待测抗体或血清样品与适量的对应流感病毒假病毒混合37℃孵育。一小时后将上述混合液加入提前铺入MDCK细胞的96孔细胞培养板,37℃,5%CO2培养。65小时后,弃去细胞上清,用PBS清洗1次后按照试剂盒(Promega,Luciferase assay system freezer pack,货号E4530)说明书操作:加入100μL细胞裂解液,冻融使细胞充分裂解后加入50μL荧光素酶反应底物,测得的相对荧光素酶活性用于计算该中和抗体或血清中和对应流感病毒假病毒的效价,计算公式如下:
血清抑制百分数=(完全培养液中的假病毒的荧光素酶相对数值-含有系列稀释抗体的完全培养液中的假病毒的荧光素酶相对数值)/完全培养液中的假病毒的荧光素酶相对数值×100%。
在本次研究中用于代表的血清中和效价的指标为IC50值,是指假病毒的荧光素酶相对数值下降了50%时的血清稀释倍数,用软件GraphPad Prism对血清稀释倍数和荧光素酶相对数值按Sigma曲线进行拟和,计算IC50值得到。IC50的浓度通过GraphPad Prism软件对系列稀释的抗体或血清样品的中和效价按Sigma曲线的拟和计算得到。
1.6 DNA疫苗的制备
pCMV/R载体质粒的构建:将血凝素全长序列(包括跨膜区和胞内区)进 行哺乳动物密码子优化后,委托公司(南京金斯瑞生物科技有限公司)进行全基因序列合成并插入pCMV/R载体(构建的血凝素DNA质粒图谱如图3所示),大肠杆菌(JM109)转化和克隆扩增后,进行质粒提取(QIAGEN,货号12183)并鉴定(包括:质粒浓度的检测、OD260/280的比例的测定、DNA琼脂糖凝胶电泳和质粒测序),质粒信息准确无误后将质粒分装并保存在-80℃备用。
1.7病毒样颗粒疫苗的制备
1.7.1病毒样颗粒(Virus-Like Particle,VLP)的包装(磷酸钙介导的质粒DNA转染法)
在T75细胞培养瓶(Thermo Fisher,货号156499)中铺入9×106个HEK293FT细胞,培养18小时后给细胞置换新的15ml培养液,2小时后加入转染质粒。
流感病毒样颗粒的体系为:
18.9μg包装载体质粒pCMVΔR8.2
2.7μg血凝素表达载体质粒pCMV/R-HA
0.675μg神经氨酸酶表达载体质粒pCMV/R-NA
67.5μL CaCl2(2.5M)溶液
加入ddH2O至675μL的体积,然后逐滴加入675μL的2×HEPES缓冲液(PH值7.10),加入过程中用移液器轻吹混匀。
对照病毒样颗粒的体系为
18.9μg包装载体质粒pCMVΔR8.2
2.7μg VSV-G囊膜质粒pCMV/R-VSV-G
67.5μL CaCl2(2.5M)溶液
加入ddH2O至675μL的体积,然后逐滴加入675μL的2×HEPES缓冲液(PH值7.10),加入过程中用移液器轻吹混匀。
混合物室温静置约20分钟后,质粒和钙离子形成颗粒均一沉淀物,将混合沉淀物逐滴均匀地加入到HEK293FT细胞中。细胞培养16-18小时后,置换新鲜培养液并加入100μM的丁酸钠作用6-8小时,再次置换15ml新鲜培养液并继续培养20小时左右,收集含有假病毒的上清。在4000rpm离心5分钟,去除可能含有的细胞残渣后用0.45μm的滤器(Millipore Millex,SLHV033RB)过滤,将过滤好的假病毒上清-80℃保存备用。
1.7.2病毒样颗粒的浓缩和纯化
将收集的含有病毒的细胞上清离心和过滤后,25,000rpm,4℃离心2小时。用PBS充分溶解VLP沉淀。重悬的VLP加到30%和45%(每个2ml)的非连续蔗糖密度梯度上。4℃,110,000xg离心3小时后,可以看到离心管内有上下两条浑浊的液体条带(upper fuzzy band&lower fuzzy band)。Upper fuzzy band在这个梯度离心管的最上层,其主要为表面没有囊膜蛋白的Gag VLP和一些少量的杂蛋白;lower fuzzy band主要为表面带有囊膜刺突蛋白的VLP。小心地取出下面条带用PBS稀释后先用0.45μm的滤膜过滤,再用0.22μm的滤膜过滤。将过滤后的VLP溶液加到20%蔗糖垫上,4℃,110,000xg离心2小时,离心得到的VLP沉淀用无菌的PBS重悬,冰上充分溶解,然后免疫实验动物。
1.7.3病毒样颗粒的定量
病毒样颗粒的定量采用两种方法:血凝实验(仅适用含有血凝素蛋白的病 毒样颗粒)和酶联免疫吸附实验(ELISA)。血凝实验的方法如1.3所述,用于病毒样颗粒表面的囊膜蛋白进行定量。酶联免疫吸附实验用于病毒样颗粒的基质蛋白进行定量,具体步骤按照HIV-1抗原ELISA试剂盒的说明书进行(ZeptoMetrix,货号0801200),具体过程如下:取出适量的HIV-1P24antigen ELISA试剂盒的微孔条,室温平衡并洗涤后,将待测样品和P24蛋白标准品用试剂盒中的稀释液梯度稀释后,取出200μL加入到微孔中,随后每孔加入20μL裂解液,37℃孵育4小时(P24标准品从125pg/ml开始对倍稀释直至7.8125pg/ml并做两个复孔检测。另有两孔不加P24标准品作为阴性对照)。洗涤6次后,每孔加入100μL reconstituted HIV-1P24Detector Ab一抗,37℃孵育一小时。洗涤6次后,加入100μL Streptavidin-Peroxidase working solution二抗,37℃孵育30分钟。洗涤6次后,每孔加入100μL Substrate working solution,室温避光显色30分钟后每孔加入100μL Stop buffer终止反应。最后在酶标仪中取波长450nm,15分钟内读取样品光吸收值(OD Value)。根据标准品绘制的标准曲线计算出待测样品所对应的P24的量。
1.8DDV免疫策略
将6-8周龄的雌性BALB/c小鼠随机分为6只每组,分别在第0天、21天、42天对小鼠进行免疫。第一次和第二次均用表达HA蛋白的DNA质粒免疫,每只小鼠后肢肌肉免疫100μg质粒,第三次用表面膜蛋白HA和NA病毒样颗粒(VLP)免疫,每只小鼠腹腔免疫512个血凝单位,作为DDV免疫组;对照组用空载质粒两次免疫,每只小鼠后肢肌肉免疫100μg质粒,加强免疫用仅含HIV-1gag的VLP免疫,每只小鼠腹腔免疫。
1.9实验动物免疫和血清收集
DDV免疫的实验动物为小鼠。DDV免疫:H5N1亚型禽流感病毒株A/common magpie/Hong Kong/5052/2007的血凝素核苷酸碱基序列插入CMV/R载体,构建质粒,免疫小鼠和雪貂,用A/common magpie/Hong Kong/5052/2007的血凝素和神经氨酸酶作为囊膜蛋白,制备病毒样颗粒加强免疫。
1.10A/common magpie/Hong Kong/5052/2007病毒株广谱性、识别表位和关键氨基酸分析
1.10.1A/common magpie/Hong Kong/5052/2007的血凝素诱导的中和抗体广谱性差
我们选择A/common magpie/Hong Kong/5052/2007血凝素,作为骨架蛋白,首先将A/common magpie/Hong Kong/5052/2007病毒株的血凝素和神经氨酸酶制备免疫原,将6-8周雌性BALB/c小鼠随机分组,采用DDV免疫策略进行免疫。最后一次免疫14天后,采集小鼠免疫血清,用假病毒中和实验检测免疫血清的广谱性。表7结果显示:DDV免疫的血清针对A/common magpie/Hong Kong/5052/2007病毒株有较好的中和活性,但对其他病毒株的中和活性较差,是典型的株特异性免疫原。
表7.A/common magpie/Hong Kong/5052/2007病毒株免疫的广谱性

1.10.2中和抗体识别的关键氨基酸集中,位于血凝素受体结合区域的外缘的氨基酸高变区
为鉴定A/common magpie/Hong Kong/5052/2007的血凝素诱导的中和抗体识别的表位及关键氨基酸位点,我们构建了一系列的突变株。血凝素蛋白空间构象分为远离跨膜区的头部和靠近跨膜区的杆部,头部有包含四个抗体结合区域,分别是AS1、AS2、AS3和AS4(血凝素蛋白的空间构象和头部区域表位如图4所示)。A/common magpie/Hong Kong/5052/2007的血凝素诱导的中和抗体对病毒株A/common magpie/Hong Kong/5052/2007高,对病毒株A/Thailand/(KAN-1)/2004中和活性低,以这两株病毒血凝素不同区域的氨基酸互换的方式构建重组蛋白免疫原,构建头部和杆部互换的HA重组的假病毒(头部杆部互换的重组HA构建示意图如图5所示),不同表位互换的假病毒(图6)。用这种含重组HA的假病毒检测免疫血清的中和活性的变化,推测中和抗体识别的表位和关键性氨基酸的位置。
首先为确定A/common magpie/Hong Kong/5052/2007的血凝素诱导的中和抗体针对的是血凝素头部还是杆部,我们用头部和杆部互换的方式构建了包含重组HA的假病毒。表8结果显示,假病毒结构完整具有血凝活性,表9结果显示互换杆部不会影响免疫血清的中和滴度,互换头部可引起免疫血清的中和滴度发生显著变化,相同头部的HA重组假病毒和野生型假病毒的中和滴度差别不显著,提示A/common magpie/Hong Kong/5052/2007的血凝素诱导的中和抗体针对的是血凝素头部。
表8.构建的头部和杆部重组的HA假病毒
表9.DDV免疫策略诱导的中和抗体针对头部和杆部互换的HA重组假病毒中和活性的比较
血凝素头部包含4个抗原表位(如图7A所示),为了确定A/common magpie/Hong Kong/5052/2007的血凝素诱导的中和抗体针对的血凝素头部的具体表位,我们构建了A/common magpie/Hong Kong/5052/2007和A/Thailand/(KAN-1)/2004病毒株头部表位互换的HA重组假病毒,表10所示重组假病毒结构完整具有血凝活性,可以用于分析免疫血清识别的具体表位。表11结果显示,互换AS2、AS3、AS4和单点突变94位氨基酸,不会影响免疫血清的中和滴度,互换AS1表位可引起免疫血清的中和滴度发生显著变化,相同AS1表位的重组假病毒和野生型假病毒的中和滴度差别不显著,提示A/common magpie/Hong Kong/5052/2007的血凝素诱导的中和抗体针对的是血凝素头部AS1表位。
表10.重组假病毒的名称、血凝滴度、P24的含量及二者的比例
表11.DDV免疫策略诱导的中和抗体针对头部和杆部互换的重组假病毒中和活性的比较

为了确定A/common magpie/Hong Kong/5052/2007的血凝素诱导的中和抗体针对的血凝素AS1表位内的关键氨基酸,本发明比较了A/common magpie/Hong Kong/5052/2007和A/Thailand/(KAN-1)/2004病毒株血凝素AS1表位的氨基酸差异,发现只有5个氨基酸不同(如图7B所示),分别位于血凝素蛋白的受体结合位点190helix上的188和193位氨基酸和受体结合位点外缘loop环上的158、159、160,我们构建这两个位置互换的突变假病毒如表12所示,可以用于分析免疫血清。表13结果显示:互换190helix上的氨基酸,不会影响免疫血清的中和滴度,互换受体结合位点外缘loop环上的158、159、160可引起免疫血清的中和滴度发生显著变化,受体结合位点外缘loop环上的158、159、160位置氨基酸相同的重组假病毒和野生型假病毒的中和滴度差别不显著,提示A/common magpie/Hong Kong/5052/2007的血凝素诱导的中和抗体针对的关键氨基酸位于158、159和160位置或附近,对血凝素蛋白头部的氨基酸保守性分析发现,A/common magpie/Hong Kong/5052/2007的血凝素158、159和160位置或附近的氨基酸属于高变区,保守性差。
表12.突变假病毒的名称、血凝滴度、P24的含量和二者的比例
表13.DDV免疫诱导的中和抗体针对突变假病毒中和活性比较
158、159和160位置位于血凝素蛋白的头部受体结合位点外缘,158、159和160位置及附近是氨基酸高变区(图8)。
1.10.3制备H5N8亚型流感广谱性疫苗
以A/common magpie/Hong Kong/5052/2007的血凝素作为骨架蛋白,将A/chicken/Netherland/14015526/2014病毒株AS1表位转移至A/common magpie/Hong Kong/5052/2007的血凝素上,并将AS1表位的159和160位置的 天冬氨酸(Aspartic acid,Asp,D)和丙氨酸(Alanine,Ala,A)突变为丝氨酸(Serine,Ser,S)和苏氨酸(Threonine,Thr,T),在受体结合位点外缘的高变区引入N-糖链,构建的HA重组免疫原,命名为NLAS1HK5052,蛋白氨基酸序列同SEQ ID NO.:1,其中x为Ser,采用“DDV”免疫方式免疫小鼠,最后一次免疫14天后收集小鼠血清,分析免疫血清的广谱性。
表14结果显示,构建的HA重组免疫原NLAS1HK5052“DDV”免疫诱导的中和抗体广谱性很好,而野生病毒株(A/chicken/Netherland/14015526/2014)“DDV”免疫诱导的中和抗体广谱性较差。
表14.A/chicken/Netherland/14015526/2014及突变疫苗株DDV免疫血清的广谱性分析
在本发明提及的所有文献都在本申请中引用作为参考,就如同每一篇文献被单独引用作为参考那样。此外应理解,在阅读了本发明的上述讲授内容之后,本领域技术人员可以对本发明作各种改动或修改,这些等价形式同样落于本申请所附权利要求书所限定的范围。

Claims (15)

  1. 一种血凝素重组蛋白,其特征在于,所述重组蛋白含有来自第一H5亚型流感病毒毒株的血凝素骨架,来自第二H5亚型流感病毒毒株的AS1表位,所述AS1表位为AS1表位突变型,所述AS1表位突变型在野生型的AS1表位的对应于来自第二H5亚型流感病毒毒株的血凝素序列(氨基酸序列号:EPI547678)中的98位,129-138位,153-161位,183位,186-194位和221-228位氨基酸(H3 numbering)的选自下组的氨基酸发生突变:
    第159位的天冬氨酸(Aspartic acid,Asp,D);和/或
    第160位的丙氨酸(Alanine,Ala,A);并且,所述第一H5亚型流感病毒毒株包括A/common magpie/Hong Kong/5052/2007(H5N1);
    所述第二H5亚型流感病毒毒株包括A/chicken/Netherland/14015526/2014(H5N8)。
  2. 如权利要求1所述的重组蛋白,其特征在于,通过159位和160位氨基酸突变,在所述重组蛋白的158位、159位和160位氨基酸位置形成N-连接型糖蛋白糖基化位点“Asn-Ser-Thr(N-S-T)”序列,并且在所述重组蛋白的第158位的天冬酰胺(Asparagine,Asn,N)位点形成N-糖链,且所述N-糖链位于受体结合位点外缘的高变区。
  3. 如权利要求1所述的重组蛋白,其特征在于,通过159位和160位氨基酸突变,160位丙氨酸(Alanine,Ala,A)突变为苏氨酸(Threonine,Thr,T),159位的天冬氨酸(Aspartic acid,Asp,D)突变为除丝氨酸和脯氨酸以外的氨基酸(不包含天冬氨酸),在所述重组蛋白的158位、159位和160位氨基酸位置形成N-连接型糖蛋白糖基化位点“Asn-X-Thr(N-X-T)”序列,其中X氨基酸选自下组:甘氨酸、丙氨酸、缬氨酸、亮氨酸、异亮氨酸、苯丙胺酸、酪氨酸、色氨酸、苏氨酸、半胱氨酸、蛋氨酸、天冬酰胺、谷氨酰胺、谷氨酸、赖氨酸、精氨酸、组氨酸、或其组合,并且在所述重组蛋白的第158位的天冬酰胺(Asparagine,Asn,N)位点形成N-糖链,且所述N-糖链位于受体结合位点外缘的高变区。
  4. 如权利要求1所述的重组蛋白,其特征在于,通过159位和160位氨基酸突变,160位丙氨酸(Alanine,Ala,A)突变为丝氨酸(Serine,Ser,S),159位的天冬氨酸(Aspartic acid,Asp,D)突变为除丝氨酸和脯氨酸以外的氨基酸(不包含天冬氨酸),在所述重组蛋白的158位、159位和160位氨基酸位置形成N-连接型糖蛋白糖基化位点“Asn-X-Ser(N-X-S)”序列,其中X氨基酸选自下组:甘氨酸、丙氨酸、缬氨酸、亮氨酸、异亮氨酸、苯丙胺酸、酪氨酸、色氨酸、丝氨酸、苏氨酸、半胱氨酸、蛋氨酸、天冬酰胺、谷氨酰胺、谷氨酸、赖氨酸、精氨酸、组氨酸、或其组合,并且在所述重组蛋白的第158位的天冬酰胺(Asparagine,Asn,N)位点形成N-糖链,且所述N-糖链位于受体结合位点外缘的高变区。
  5. 如权利要求1所述的重组蛋白,其特征在于,通过仅对160位氨基酸进行突变,160位丙氨酸(Alanine,Ala,A)突变为丝氨酸(Serine,Ser,S)或者突变为苏氨酸(Threonine,Thr,T),在所述重组蛋白的158位、159位和160位氨基酸位置形成N-连接型糖蛋白糖基化位点“Asn-Asp-Ser/Thr(N-D-S/T)”序列,并且在所述重组蛋白的第158位的天冬酰胺(Asparagine,Asn,N)位点形成N-糖 链,且所述N-糖链位于受体结合位点外缘的高变区。
  6. 如权利要求1所述的重组蛋白,其特征在于,突变后的氨基酸在158,159,160位点形成N-连接型糖蛋白糖基化位点:Asn-X-Ser/Thr(N-X-S/T),其中X为脯氨酸以外的任何氨基酸,包括甘氨酸、丙氨酸、缬氨酸、亮氨酸、异亮氨酸、苯丙胺酸、酪氨酸、色氨酸、丝氨酸、苏氨酸、半胱氨酸、蛋氨酸、天冬酰胺、谷氨酰胺、天冬氨酸、谷氨酸、赖氨酸、精氨酸和组氨酸。
  7. 一种疫苗多肽,其特征在于,所述疫苗多肽包括权利要求1所述的重组蛋白。
  8. 一种DNA或mRNA疫苗,其特征在于,所述的疫苗含有用于表达权利要求1所述的重组蛋白的编码mRNA、以及DNA表达载体。
  9. 一种分离的多核苷酸,其特征在于,所述的多核苷酸编码权利要求1所述的重组蛋白或权利要求7所述的疫苗多肽。
  10. 一种表达载体,其特征在于,所述表达载体含有权利要求9所述的多核苷酸。
  11. 一种宿主细胞,其特征在于,所述的宿主细胞含有权利要求10所述的表达载体,或者在基因组中整合有权利要求9所述的多核苷酸。
  12. 一种H5亚型流感病毒株,其特征在于,所述病毒株的基因组中包含外源性的重组蛋白基因序列,其中,所述重组蛋白基因序列编码权利要求1所述的重组蛋白。
  13. 一种药物组合物,其特征在于,所述的组合物含有权利要求1所述的重组蛋白、权利要求7所述的疫苗多肽或权利要求8所述的mRNA或DNA疫苗或权利要求9所述的多核苷酸或者权利要求10所述的表达载体或者权利要求11所述的宿主细胞或权利要求12所述的病毒株,以及药学上可接受的载体和/或辅料。
  14. 一种疫苗组合物,其特征在于,所述的组合物含有权利要求1所述的重组蛋白、权利要求7所述的疫苗多肽或权利要求8所述的mRNA或DNA疫苗或权利要求9所述的多核苷酸或者权利要求10所述的表达载体或者权利要求11所述的宿主细胞或权利要求12所述的病毒株,以及免疫学上可接受的载体和/或辅料。
  15. 如权利要求1所述的重组蛋白或权利要求7所述的疫苗多肽或权利要求8所述的mRNA或DNA疫苗或权利要求12所述的病毒株或权利要求13所述的药物组合物或权利要求14所述的疫苗组合物的用途,其特征在于,(a)用于制备针对禽流感病毒血凝素的抗体;和/或(b)用于制备预防和/或治疗禽流感病毒感染或其相关疾病的药物。
PCT/CN2023/089267 2022-04-28 2023-04-19 H5n8禽流感广谱性疫苗的开发及其应用 WO2023207717A1 (zh)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN117164705A (zh) * 2023-08-31 2023-12-05 华南农业大学 一种靶向h5亚型禽流感病毒血凝素蛋白的纳米抗体

Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2020093984A1 (en) * 2018-11-06 2020-05-14 Boehringer Ingelheim Vetmedica Gmbh Immunogenic composition against avian influenza virus h5 subtype
CN113150083A (zh) * 2021-04-29 2021-07-23 山西高等创新研究院 重组禽流感亚单位疫苗及其制备方法
CN113603754A (zh) * 2021-08-23 2021-11-05 福建省农业科学院畜牧兽医研究所 一种水禽h5n8亚型流感病毒ha重组蛋白及其制备方法与应用
CN113913395A (zh) * 2021-10-19 2022-01-11 中国农业科学院哈尔滨兽医研究所(中国动物卫生与流行病学中心哈尔滨分中心) 人工重组的h5n8流感病毒及其制备方法和应用
CN113913394A (zh) * 2021-10-19 2022-01-11 中国农业科学院哈尔滨兽医研究所(中国动物卫生与流行病学中心哈尔滨分中心) 人工重组的h5n6流感病毒及其制备方法和应用

Family Cites Families (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2010500034A (ja) * 2006-08-09 2010-01-07 メッドイミューン バクシーンズ,インコーポレイティド インフルエンザ赤血球凝集素変異体およびノイラミニダーゼ変異体
CN104288759A (zh) * 2013-07-16 2015-01-21 普莱柯生物工程股份有限公司 一种禽流感疫苗组合物及其制备方法和应用

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2020093984A1 (en) * 2018-11-06 2020-05-14 Boehringer Ingelheim Vetmedica Gmbh Immunogenic composition against avian influenza virus h5 subtype
CN113150083A (zh) * 2021-04-29 2021-07-23 山西高等创新研究院 重组禽流感亚单位疫苗及其制备方法
CN113603754A (zh) * 2021-08-23 2021-11-05 福建省农业科学院畜牧兽医研究所 一种水禽h5n8亚型流感病毒ha重组蛋白及其制备方法与应用
CN113913395A (zh) * 2021-10-19 2022-01-11 中国农业科学院哈尔滨兽医研究所(中国动物卫生与流行病学中心哈尔滨分中心) 人工重组的h5n8流感病毒及其制备方法和应用
CN113913394A (zh) * 2021-10-19 2022-01-11 中国农业科学院哈尔滨兽医研究所(中国动物卫生与流行病学中心哈尔滨分中心) 人工重组的h5n6流感病毒及其制备方法和应用

Non-Patent Citations (2)

* Cited by examiner, † Cited by third party
Title
CUENO MARNI E., SHIOTSU HAYATO, NAKANO KARIN, SUGIYAMA EMIKO, KIKUTA MARI, USUI RIKUYA, OYA RIKU, IMAI KENICHI: "Structural significance of residues 158–160 in the H3N2 hemagglutnin globular head: A computational study with implications in viral evolution and infection", JOURNAL OF MOLECULAR GRAPHICS AND MODELLING, ELSEVIER SCIENCE, NEW YORK, NY, US, vol. 89, 1 June 2019 (2019-06-01), US , pages 33 - 40, XP093102782, ISSN: 1093-3263, DOI: 10.1016/j.jmgm.2019.02.007 *
SEALY JOSHUA E., HOWARD WENDY A., MOLESTI ELEONORA, IQBAL MUNIR, TEMPERTON NIGEL J., BANKS JILL, SLOMKA MAREK J., BARCLAY WENDY S.: "Amino acid substitutions in the H5N1 avian influenza haemagglutinin alter pH of fusion and receptor binding to promote a highly pathogenic phenotype in chickens", JOURNAL OF GENERAL VIROLOGY, SOCIETY FOR GENERAL MICROBIOLOGY, vol. 102, no. 11, 2 November 2021 (2021-11-02), XP093102785, ISSN: 0022-1317, DOI: 10.1099/jgv.0.001672 *

Cited By (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN117164705A (zh) * 2023-08-31 2023-12-05 华南农业大学 一种靶向h5亚型禽流感病毒血凝素蛋白的纳米抗体
CN117164705B (zh) * 2023-08-31 2024-06-04 华南农业大学 一种靶向h5亚型禽流感病毒血凝素蛋白的纳米抗体

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