CN105770884B - B-type avian metapneumovirus subunit vaccine - Google Patents
B-type avian metapneumovirus subunit vaccine Download PDFInfo
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Abstract
The invention provides a B-type avian metapneumovirus subunit vaccine, which comprises an antigen and a vaccine adjuvant, wherein the antigen is inactivated B-type avian metapneumovirus F protein, and the amino acid sequence of the B-type avian metapneumovirus F protein is SEQ ID NO. 1. The invention relates to a vaccine which is prepared by inoculating pichia pastoris X33-F of genetic engineering for expressing B type avian metapneumovirus F protein into a culture medium, efficiently expressing the B type avian metapneumovirus F protein under the action of methanol, extracting and purifying, adding formaldehyde solution for inactivation, adding adjuvant, mixing and emulsifying. The vaccine prepared by the invention can improve the antibody level after immunization, improve the uniformity of the antibody after immunization, ensure the immune effect of the vaccine, and has the advantages of high efficiency and good safety.
Description
Technical Field
The invention belongs to the technical field of biological veterinary drugs, and particularly relates to a B-type avian metapneumovirus subunit vaccine.
Background
The avian metapneumovirus belongs to the genus of paramyxovirus pneumovirus, and the genome is nonsegmented single-stranded negative-strand RNA which can cause the turkey to have respiratory diseases and is called turkey rhinotracheitis; after infecting chickens, viral air sacculitis, rhinotracheitis and swollen head syndrome are caused, and egg laying is reduced. At the end of the 70's 20 th century, diseases caused by avian metapneumovirus were first reported in south africa and subsequently occurred in north america, south america, the middle east and the far east. The virus was first isolated in 1989 in the united states. When the virus is isolated, Bordetella, Pasteurella, Pseudomonas, bird's disease bacillus rhinotracheitis, Alcaligenes faecalis and the like can be isolated. The avian metapneumovirus can inhibit the movement of cilia of the trachea, dust in the trachea is difficult to discharge outwards, and a large amount of bacteria in the dust are easy to cause secondary infection to invade the respiratory tract. The pathogenic avian metapneumovirus can be divided into three types: the A type infected turkey, the B type infected broiler chicken and the C type exist only in the United states, and the A type and the B type have cross protection effect and do not have cross protection effect with the C type. With the continuous expansion of the breeding scale of poultry industry in China, secondary infection caused by the infection of the avian metapneumovirus is increasingly serious, the harm to the poultry industry is very serious, and the only effective method is to prevent the morbidity of chicken flocks by vaccinating. At present, the research on the avian metapneumovirus vaccine at home and abroad is mostly focused on the development of inactivated vaccine.
The entire pathogen contains many antigens, but not all antigens stimulate a protective response by the host. Some of these antigens can also cause allergies, immunosuppression and other side effects, which are drawbacks of using intact pathogens for vaccines. In addition, the production and preparation of the inactivated vaccine applied in China at present are complicated in antigen process, and the attenuated vaccine also has the disease condition of vaccination. The subunit vaccine can solve the problem, and particularly, the subunit vaccine has the advantages of high antigen stability, high purity, strong specificity, high sensitivity, no generation of other irrelevant antibodies, convenient and accurate immune effect detection method, and easy production. It is produced without animal body or embryo body and has no tissue residue. Moreover, the inactivation is not needed, but the safety is high.
Disclosure of Invention
The invention aims to provide a B-type avian metapneumovirus subunit vaccine which has the advantages of high efficiency, good safety, high antibody uniformity and high protection rate, thereby making up the defects of the prior art.
The B-type avian metapneumovirus subunit vaccine comprises an antigen and a vaccine adjuvant, wherein the used antigen is inactivated B-type avian metapneumovirus F protein,
an avian metapneumovirus type B F protein comprising:
1) protein with an amino acid sequence of SEQ ID NO. 1,
2) protein which is obtained by substituting, deleting and adding one or more amino acids on the protein in the step 1) and has the function of the protein in the step 1);
the nucleotide sequence of the gene for coding the F protein is SEQ ID NO. 2;
wherein, the Pichia pastoris X33-F (Pichia pastoris X33-F) for producing the B-type avian metapneumovirus fusion protein is preserved in the China center for type culture Collection of Wuhan university in 2016, 3 and 9 days, and the preservation number is CCTCC NO: M2016097.
Wherein the B-type avian metapneumovirus fusion protein is inactivated by formaldehyde solution;
the content of the B type avian metapneumovirus F protein in the vaccine is not less than 50 mu g/0.3 ml.
The invention relates to a vaccine which is prepared by inoculating pichia pastoris X33-F of genetic engineering for expressing B type avian metapneumovirus F protein into a culture medium, efficiently expressing the B type avian metapneumovirus F protein under the action of methanol, extracting and purifying, adding formaldehyde solution for inactivation, adding adjuvant, mixing and emulsifying. The vaccine prepared by the invention can improve the antibody level after immunization, improve the uniformity of the antibody after immunization, ensure the immune effect of the vaccine, and has the advantages of high efficiency and good safety.
Drawings
FIG. 1: the F gene PCR amplification identification map of the invention example 1;
FIG. 2: the nucleotide sequence alignment chart of the F gene of the invention;
FIG. 3: the amino acid sequence alignment chart of the F protein of the invention;
FIG. 4: the enzyme digestion identification chart of the high-efficiency expression vector in the embodiment of the invention;
FIG. 5: the PCR identification chart of the recombinant strain X33-F in the embodiment of the invention;
FIG. 6: the recombinant bacteria fermentation induction expression product SDS-PAGE electrophoresis verification picture of the embodiment of the invention.
Detailed Description
The invention is described in detail below with reference to the figures and specific embodiments.
Example 1: amplification and sequence analysis of the F protein
Symptoms of swollen head syndrome appear in a plurality of chicken farms in Shandong province in 2010, existing avian pneumovirus vaccines are injected before diseased chicken flocks, and variation of infected viruses is presumed; therefore, the avian pneumovirus is screened from the diseased individuals. Finally, a strain of avian pneumovirus SHS/A3 is screened out.
In order to verify the antigenicity of the screened virus, 5 virus strains of different sources including the screened virus strain SHS/A3 are used as antigens to prepare vaccines, after the SPF chicken are immunized, virus liquid of the SHS/A3 strain is used for virus challenge experiments, and the results show that the vaccine is compared with other avian pneumovirus vaccines; the vaccine prepared by the vaccine has better immune effect (p is less than 0.05); thus determining that it has undergone genetic variation.
1. Amplification of the F Gene of type B avian metapneumovirus SHS/A3 Strain (APV)
Primers were designed and synthesized based on the F gene sequence published in NCBI, and the sequence information of the primers was as follows:
primer1:5′-GGGATGTACCTCAAACTGCTACTAAT-3′;
primer2:5′-TCAACTGATGTAGCCCATGTTGC-3′。
2. cloning and sequencing of PCR amplified F gene
Extracting nucleic acid of SHS/A3 strain as template, performing PCR amplification of target fragment with primer1 and primer2, and sequencing (FIG. 1 is PCR amplification identification chart of type B avian metapneumovirus F protein gene) to obtain nucleotide sequence of SEQ ID NO. 2; the coded amino acid sequence is SEQ ID NO. 1. The nucleotide sequence comparison analysis is carried out with the F gene of the B-type avian metapneumovirus published in NCBI, and the homology is 95.1-99.2 percent (FIG. 2 is the nucleotide sequence comparison diagram of the F gene of the SHS/A3 strain); the deduced amino acid sequence homology is 95.0% -97.4% (FIG. 3 is the amino acid sequence alignment chart of the F protein of the SHS/A3 strain). The results showed that the isolated SHS/A3 strain is a novel avian metapneumovirus type B and contains a novel F gene.
3. Design and synthesis of type B avian metapneumovirus (APV) F gene
According to the sequence determination result of the F gene of the SHS/A3 strain, a pair of primers is designed and synthesized, and the sequence information of the primers is as follows:
primer3:5′-gggggtaccATGTACTTGAAGTTGCAATTG-3′;
primer4:5′-gcggccgcTCAACTGATGTAACCCATGT-3′。
using F gene whose synthetic nucleotide sequence is SEQ ID NO. 2 as template, using primer3 and primer4 to make PCR amplification, recovering target fragment product and connecting pMD18-T vector, transforming and screening positive clone pMD 18-T-F.
Example 2: recombinant expression of the F protein
1. Preparation method of recombinant B-type avian metapneumovirus F protein
The method comprises the following steps: a. constructing an expression vector; b. constructing an expression strain; c. and (3) inducing, extracting and purifying the recombinant F protein.
a. Constructing an expression vector:
after carrying out 1.2% agarose gel electrophoresis on the positive cloning plasmid pMD18-T-F and the expression vector pPICZ alpha vector by using KpnI and NotI double digestion products respectively, recovering by using a DNA gel recovery kit to obtain about 1.6kb and 3.3kb fragments respectively, and directionally connecting at 16 ℃ to construct the pPICZ alpha-F expression vector (FIG. 4 is a digestion identification diagram of the efficient expression vector in the embodiment of the invention); after the sequencing verifies that the sequence and the reading frame are correct, the plasmid is linearized and then is electrically transformed into pichia pastoris competent cells.
b. Constructing an expression strain:
after electrotransformation, F gene is recombined into a pichia pastoris genome to construct a pichia pastoris expression strain X33-F (which is preserved in China Center for Type Culture Collection (CCTCC) M2016097 in 2016, 3, 6 and the preservation number is shown in figure 5);
c. induction and extraction purification of recombinant F protein:
inducing expression, selecting single colony containing X33-F, inoculating to BMGY liquid culture medium, shaking culturing at 30 deg.C overnight, centrifuging to collect thallus, suspending with appropriate amount of BMMY, adding final concentration 0.5% methanol, and inducing at 30 deg.C for 96 hr. Centrifuging at 9000rpm for 5min at 4 deg.C, collecting supernatant, precipitating with 30% ammonium sulfate, centrifuging at 12000rpm for 5min to collect protein precipitate, and re-dissolving protein with PBS. Adding protein electrophoresis loading buffer, boiling for 8 min, and performing SDS-PAGE identification with 12% separating gel. (in FIG. 6, 1, 2 and 3 represent precipitates of the F protein expression product, and M represents a molecular weight standard protein.)
Example 3: preparation of subunit vaccines
Preparation of subunit vaccine
1. Preparation of bacterial liquid for preparing vaccine X33-F strain is inoculated in YPD liquid culture medium containing bleomycin, and shaking culture is carried out for 16-18 hours at 30 ℃. And then streaking and inoculating the solid YPD culture medium with bleomycin, selecting 2-3 typical colonies, mixing the typical colonies in a small amount of YPD liquid culture medium, placing the mixture in a shaking table at 30 ℃ for shaking culture for 18 hours, quantitatively subpackaging, and performing pure inspection to obtain the first-grade seeds. Inoculating the first-stage seeds in BMGY liquid medium, performing shake culture at 30 deg.C for 16-18 hr, performing microscopic examination, and storing at 2-8 deg.C
2. Preparing the protein for preparing the vaccine by adding BMGY incomplete liquid culture medium according to 60 percent (V/V) of the volume of a fermentation tank, simultaneously adding an antifoaming agent according to 0.1 percent (V/V) of the culture medium, introducing high-temperature steam for sterilization for 30 minutes, adding YNB and biotin when the temperature of the culture medium is reduced to 32 ℃, inoculating a second-stage seed solution for producing B-type avian metapneumovirus F protein, and setting the parameters of the fermentation tank as 800r/min of stirring speed and 30 ℃ respectively, and maintaining the DO value (dissolved oxygen amount) at 20 percent. Adding methanol into the bacterial liquid after 24 hours of culture, carrying out induced expression culture at the methanol adding speed of 2ml/h/L, and carrying out induced expression for 120 hours according to the fermentation control parameters and the process; centrifuging the fermentation culture bacteria liquid for 30 minutes at 10000r/min by a tube centrifuge, adding ammonium sulfate into the obtained supernatant to precipitate protein, centrifuging the obtained product for 30 minutes at 12000r/min to obtain precipitate, and adding a proper amount of normal saline to dissolve the protein precipitate.
3. Inactivating, namely putting the protein solution into an inactivating bottle, adding 10% formaldehyde solution in a metering manner, and shaking along with the addition to fully mix the protein solution, wherein the final concentration of the formaldehyde solution is 0.1%. Adding formaldehyde solution and pouring into another inactivation bottle to avoid viruses adhered near the bottle mouth from contacting the inactivator. And inactivating the cells at 37 ℃ for 16 hours, taking out the cells, and storing the cells at 2-8 ℃.
4. Inspection of semi-finished product
(1) And (4) performing sterile inspection according to the appendix of the current Chinese veterinary pharmacopoeia.
(2) Protein content determination protein content was determined by the Bradford method.
(3) Inactivation test A small amount of the inactivated protein solution was inoculated into YPD solid medium, and cultured at 30 ℃ for 72 hours. Observing the growth of the sterile colonies, and judging the inactivation and inspection to be qualified.
5. Preparation of subunit vaccine finished product
And (3) preparing the vaccine by using the semi-finished protein antigen which is qualified after inspection (the liquid components in the following preparation are calculated according to the volume ratio).
(1) The preparation of the oil phase comprises the steps of putting 95 parts of white oil for livestock and 1 part of aluminum stearate in an oil phase preparation tank, heating to 80 ℃, adding span-805 parts until the temperature reaches 115 ℃, keeping for 30min, and cooling for later use.
(2) Aqueous phase preparation avian metapneumovirus type B F protein was diluted to 150 μ g/0.1ml using physiological saline. And (3) adding 5 parts of sterilized Tween-80 into the liquid preparation tank, simultaneously adding 95 parts of the protein liquid for preparing the seedlings, and stirring for 20-30 min to completely dissolve the Tween-80.
(3) Emulsifying to obtain 2 parts of oil phase, placing in a high-speed shearing machine, starting a motor to rotate slowly and stirring, simultaneously slowly adding 1 part of water phase, and emulsifying for 5 minutes at 10000 r/min. After emulsification, 10ml of the mixture is taken out and centrifuged at 3000r/min for 15 minutes, and the water separated out from the bottom of the tube is not more than 0.5 ml.
Second, subunit vaccine finished product inspection
(1) Traits
The apparent vaccine should be milk white emulsion, free of impurities and qualified in external packaging.
The dosage form is water-in-oil type. A clean pipette is taken to suck a small amount of vaccine and drip the vaccine into cold water, and the vaccine should not spread except the 1 st drop.
The stable suction vaccine 10ml is added into a centrifuge tube and centrifuged for 15 minutes at 3000r/min, and the water separated out from the tube bottom is not more than 0.5ml correspondingly.
The viscosity is carried out according to the appendix of the current Chinese veterinary pharmacopoeia, and the viscosity is in accordance with the regulations.
(2) The loading inspection is carried out according to the appendix of the current Chinese animal pharmacopoeia and is in accordance with the regulations.
(3) The sterility test is carried out according to the appendix of the current Chinese veterinary pharmacopoeia and is in accordance with the regulations.
(4) The safety test was carried out by injecting 10 SPF chickens 7 days old subcutaneously 1.0ml of the subunit vaccine per neck, simultaneously feeding 5 control chickens under the same conditions, continuously observing for 14 days, and recording the feeding, drinking and clinical conditions of the test chickens. Any local and systemic adverse reactions caused by the vaccine should not occur.
(5) Efficacy test 10 SPF chickens of 21 days old were injected subcutaneously with 0.3ml of subunit vaccine per neck, and another 10 SPF chickens of the same day old were used as a control for immunization. At 28 days after immunization, 0.1ml of SHS/A3 strain virus solution is added in eyes to counteract virus, and the virus content is 106.5TCID500.1 ml. After challenge, the observation was continued for 7 days, and nasal swabs were collected and virus was isolated on day 5 after challenge. The result shows that the B type avian metapneumovirus F protein subunit vaccine immunized chicken flock can resist the attack of virus, no clinical symptoms appear, and the virus separation is negative. The control group showed clinical symptoms and 9/10 virus was positive for isolation. The F protein subunit vaccine prepared by the invention has good immune effect (p is less than 0.05), and can protect immune chickens against attack of B type avian metapneumovirus.
(6) Similar product contrast test the subunit vaccine and some imported similar product are used for immunizing SPF chicken according to the method to carry out efficacy contrast test. When the antibody is measured by using the avian pneumovirus ELISA kit, from the aspect of antibody value, control chickens are negative, subunit vaccine immunized chickens are not less than 2000, similar products immunized chickens 6/10 are not less than 2000, and subunit vaccine is obviously higher than imported similar products. According to the method, the SHS/A3 strain is used for virus challenge, and from the result of virus challenge protection, the subunit vaccine prepared by the invention has 90% protection after virus challenge, while the protection rate of similar products is 60%. The results show that the subunit vaccine is superior to the similar product (see table 1), and the incidence rate is far lower than that of the commercial vaccine (p < 0.05).
Table 1: efficacy comparison test with like products
Claims (5)
1. A subunit vaccine of type B avian metapneumovirus is characterized in that the subunit vaccine comprises an antigen and a vaccine adjuvant, wherein the antigen is inactivated type B avian metapneumovirus F protein; the amino acid sequence of the B-type avian metapneumovirus F protein is SEQ ID NO. 1.
2. The vaccine of claim 1, wherein the edited gene of the type B avian metapneumovirus F protein has the nucleotide sequence of SEQ ID NO. 2.
3. The vaccine of claim 1 or 2, wherein the avian metapneumovirus type B F protein is expressed using pichia pastoris expression strain X33-F with accession number CCTCC M2016097.
4. The vaccine of claim 1, wherein said type B avian metapneumovirus F protein has been inactivated by formalin.
5. The vaccine of claim 1, wherein said avian metapneumovirus type B F protein is present in an amount of no less than 50 μ g/0.3 ml.
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Citations (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN103739679A (en) * | 2014-01-15 | 2014-04-23 | 北京市农林科学院 | Avian metapneumovirus (aMPV) F protein polypeptide and application thereof |
CN105296440A (en) * | 2015-09-08 | 2016-02-03 | 北京市农林科学院 | Chicken C type avian metapneumovirus strain aMPV/C-JCZ and application thereof |
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CN103739679A (en) * | 2014-01-15 | 2014-04-23 | 北京市农林科学院 | Avian metapneumovirus (aMPV) F protein polypeptide and application thereof |
CN105296440A (en) * | 2015-09-08 | 2016-02-03 | 北京市农林科学院 | Chicken C type avian metapneumovirus strain aMPV/C-JCZ and application thereof |
Non-Patent Citations (4)
Title |
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1株B亚型禽偏肺病毒的分离与鉴定;薛聪等;《中国兽医学报》;20140131;第34卷(第1期);39-44 * |
Avian metapneumovirus strain aMPV/B/IT/GuineaFowl/1818/12 fusion protein (F) gene, complete cds;KC542808;《Genbank》;20140606;1 * |
禽偏肺病毒分子生物学及基因工程疫苗研究进展;胡海霞等;《中国家禽》;20120620;第34卷(第12期);1-5 * |
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