The Sequence Listing is submitted as an ASCII formatted text filed via EFS-Web, with a file name of “Sequence Listing.TXT”, a creation date of Oct. 16, 2017, and a size of 4,310 bytes. The sequence listing filed via EFS-Web is part of the specification and is incorporated in its entirety by reference herein.
The present invention relates to biotechnical field, and more particularly to a human type 55 replication defective adenovirus vector, method for preparing the same and uses thereof.
Adenovirus (Ad) is a double-stranded DNA virus with a genome length of about 35-40 kb. It is known that human adenovirus is classified into 7 species (A-G) including more than 60 serotypes. Adenovirus type 3, 4, 7 and 14, belonging to species B, can cause acute respiratory diseases and even fatal pneumonia. In recent years, the emergence of type 55 adenovirus (hereinafter referred to as Ad55) which is a recombinant virus of type 11 and 14 adenoviruses, has led to a series of outbreaks of community-acquired pneumonia. Death cases were sporadically reported in these epidemics. Clinically, supportive treatment is the only strategy for Ad55 infection. There are still no anti-viral drugs nor prophylactic vaccines. Therefore, development of anti-Ad55 vaccines and drugs is essential for the control of Ad55 infection in general populations, especially among military recruits, young students and the like.
At present, the only adenovirus vaccine is used in US troops. This vaccine is enteric-coated capsules comprised of wild type Ad4 and Ad7 which are passaged and propagated on diploid human fetal kidney fibroblasts, and then frozen, dehydrated, and coated with cellulose lactose. The utilization of this vaccine effectively decreased the outbreaks of adenovirus epidemic in US troops. However, the used adenovirus vaccine is still of significant drawbacks. This vaccine is mainly used to prevent Ad4 and Ad7 infection, and has no exact preventive effects on Ad14 and Ad55 which are highly pathogenic. On the other hand, this vaccine is comprised of wild-type adenovirus, which may bring safety concerns because residual live viruses discharged from the intestinal tract can easily pollute the water and thus resulting in the spread of the viruses. This vaccine, therefore, cannot be applied to general population. Replication defective adenovirus vaccine with high safety and protective capacity against Ad55 is urgently needed.
Previous studies have shown that E1 gene is essential for the replication of adenovirus, whereas E3 gene antagonizes host immune responses. Adenovirus with E1 and E3 genes deleted lose the ability to replicate in immune-competent individuals and exhibit an attenuated phenotype, whereas the major surface antigens such as Hexon and Fibre are not affected. Therefore, the use of replication defective adenovirus as a vaccine can effectively enhance its safety and expand its applicable range. Replication defective adenovirus can be propagated in complementary cell lines, such as 293 and PerC6 cells, which steadily express the E1 gene of Ad5. However, for many adenoviruses, especially those from species B, deletion of E1 and E3 genes renders them difficult to propagate in these cell lines, mainly because Ad5 E1B 55K cannot interact with E4 Orf6 from species B adenovirus, and thereby cannot effectively inhibit host mRNA transportation out of the nucleus and enhance the expression of viral late proteins.
Replication defective Ad55 can also be widely used as gene vector in gene therapy, as well as vaccines and other fields. Adenovirus vector has a number of advantages such as good safety, effectiveness of gene transduction and convenience of large-scale production. Due to these advantages, adenovirus vector has been used in hundreds of clinical trials around the world, ranking among the most widely used vectors (24.8%). Most studies use Ad5 or Ad2 as vector. However, the pre-existing anti-Ad immune response elicited by previous adenovirus infection limits the use of traditional adenovirus vector. Studies have shown that pre-existing Ad2 and Ad5 neutralizing antibodies are of high seropositive rate in developing countries and regions such as Africa, South America and China. In some populations the seropositive rate is even more than 90%. These neutralizing antibodies inhibit the entry of adenovirus vectors into body cells, making it difficult to perform immunological or therapeutic functions. To overcome the pre-existing anti-Ad immune response, researchers have developed a series of techniques, including: 1) using immunosuppressive agents to inhibit the anti-Ad immune response such as cyclosporine, cyclophosphamide, FK506, etc.; 2) modifying or reconstructing surface proteins of adenovirus vector in order to bypass pre-existing neutralizing antibodies; 3) infecting PBMC by adenovirus in vitro, then performing autologous transfusion (an AVIP techniques which we have previously developed), and so on. However, these techniques either have severe side effects (such as immunosuppressive agents) or can only be used for once because of the immune response triggered against a new vector after the application.
The technical problem to be solved by the present invention is to provide a human type 55 replication defective adenovirus vector in order to overcome the above-mentioned problems of the prior art.
The above technical problems will be resolved by the following technical solutions:
A human type 55 replication defective adenovirus vector is prepared by the following method: knocking out E1 and E3 genes of Ad55 and then substituting the open reading frame (Orf) 6 or Orf 2, 3, 4, 6, and 6/7 of E4 gene in Ad55 genome with corresponding reading frames of Ad5 genome.
Preferably, the human type 55 replication defective adenovirus vector also integrates exogenous gene expression cassette in the E1 gene region.
A method for preparing a human type 55 replication defective adenovirus vector comprises the following steps:
S1. Amplifying homologous recombination arms of the Ad55 E1 gene region by PCR and ligating the arms backward into a vector with kanamycin resistance (KanaR) gene, linearizing the vector, obtaining a genomic plasmid pAd55ΔE1ΔE3-Kana through homologous recombination of the linearized vector with pAd55ΔE3, which is linearized by partial digestion;
S2. Amplifying homologous recombination arms of the Ad55 E1 gene region by PCR, ligating the arms forward into a vector with KanaR gene, linearizing the vector, obtaining a genomic plasmid pAd55ΔE1ΔE3 through homologous recombination of the linearized vector with the linearized pAd55ΔE1ΔE3-Kana;
S3. Amplifying the Ad5 E4 Orf2-6 and Ad55 E4 genes by PCR, substituting a corresponding region of the Ad55 E4 gene with Ad5 E4 Orf2-6 to obtain p55E4(5E4), linearizing the p55E4(5E4), obtaining a genomic plasmid pAd55ΔE1ΔE3(5E4) through homologous recombination of the linearized p55E4(5E4) with the linearized pAd55ΔE1ΔE3;
S4. Amplifying Ad5 E4 Orf6 by PCR, substituting the corresponding region of the Ad55 E4 gene mentioned in S3 with the amplified Ad5 E4 Orf6 to obtain p55E4(5Orf6), linearizing the p55E4(5Orf6), obtaining a genomic plasmid pAd55ΔE1ΔE3(5Orf6) through homologous recombination of the linearized p55E4(5Orf6) with the linearized pAd55ΔE1ΔE3.
Preferably, a specific process of step S1 comprises of:
Amplifying homologous recombination arms L-delE1 and R-delE1 of the E1 gene by PCR using the Ad55 genome as a template, ligating the arms into a pVax vector after digestion to obtain pVax-delE1(L+R), linearizing the pVax-delE1(L+R), obtaining the genomic plasmid pAd55ΔE1ΔE3-Kana with the E1 and E3 genes knocked out and a unique restriction site PmeI introduced through homologous recombination of the linearized pVax-delE1(L+R) with pAd55ΔE3 linearized by partial digestion and ampicillin and kanamycin dual-resistance screening.
Most preferably, in an embodiment of the present invention, a specific process of step S1 comprises of:
Amplifying upstream and downstream recombination arms L-delE1 and R-delE1 of the E1 gene by PCR using Ad55 genome as the template, digesting the L-delE1 with SpeI and EcoRI, ligating the digested L-delE1 into the pVax vector digested with the same endonucleases to obtain pVax-L-delE1; digesting the R-delE1 with EcoRI and XbaI, ligating the digested R-delE1 into pVax-L-delE1 digested with the same endonucleases to obtain the shuttle plasmid pVax-delE1(L+R) with the E1 gene knocked out;
Linearizing pVax-delE1(L+R) with EcoRI and linearizing pAd55ΔE3 by partial digestion with PacI, obtaining the genomic plasmid pAd55ΔE1ΔE3-Kana through homologous recombination of the two linearized fragments and dual-resistance screening.
Preferably, a specific process of step S2 comprises of:
Amplifying homologous recombination aims L-delK(E1) and R-delK(E1) of the E1 gene by PCR using the Ad55 genome as a template, ligating the arms into a pVax vector after digestion to obtain pVax-delK(E1), linearizing the pVax-delK(E1), obtaining the genomic plasmid pAd55ΔE1ΔE3 with the E1, E3 and KanaR genes knocked out and a unique restriction site PmeI introduced through homologous recombination of the linearized pVax-delK(E1) with the linearized pAd55ΔE1ΔE3-Knana.
Most preferably, in an embodiment of the present invention, a specific process of step S2 comprises of:
Amplifying upstream and downstream recombination arms L-delK and R-delK of the E1 gene by PCR using the Ad55 genome as the template, digesting the L-delK with SpeI and EcoRI, ligateing the digested L-delK into the pVax vector digested with the same endonucleases to obtain pVax-L-delK(E1); digesting the R-delK with EcoRI and XbaI, ligating the digested R-delK into pVax-L-delK(E1) digested with the same endonucleases to obtain the shuttle plasmid pVax-delK (E1) with the kanaR gene knocked out;
Linearizing pVax-delK(E1) by digestion with SpeI and EcoRI and linearizing pAd55ΔE3-Kana with PmeI, obtaining the genomic plasmid pAd55ΔE1ΔE3 with the kanaR gene knocked out and unique restriction site PmeI introduced in the original E1 gene region through homologous recombination of the two linearized fragments.
Preferably, a specific process of step S3 comprises of:
Amplifying Ad5 E4 Orf2-6 and Ad55 E4 by PCR using Ad5 genome and Ad55 genome as templates respectively, ligating the Ad55 E4 into a T vector to obtain p55E4, further removing Ad55 E4 Orf2-6 by PCR using p55E4 as a template, then ligating the PCR product with the Ad5 E4 Orf2-6 to obtain p55E4(5E4), linearizing the p55E4(5E4), and obtaining pAd55ΔE1ΔE3(5E4) through homologous recombination of the linearized p55E4(5E4) with the linearized pAd55ΔE1ΔE3.
Most preferably, in an embodiment of the present invention, a specific process of step S3 comprises of:
Amplifying Ad5 E4 Orf2-6 gene and Ad55 E4 gene by PCR using Ad5 genome and Ad55 genome as templates respectively, ligating each into the T vectors to obtain p5Orf2-6 and p55E4 respectively; removing E4 Orf2-6 of Ad55 by PCR using p55E4 as the template and introducing the restriction site SapI, digesting the two vectors with SapI and then ligating each other to obtain p55E4(5E4);
Digesting p55E4(5E4) with PmeI and MluI and digesting pAd55ΔE1ΔE3 with PsiI, obtaining the genomic plasmid pAd55ΔE1ΔE3(5E4) of which Ad55 E4 Orf2-6 is substituted with Ad5 E4 Orf2-6 through homologous recombination.
Preferably, a specific process of step S4 comprises of:
Amplifying Ad5 E4 Orf6 by PCR using Ad5 genome as a template, removing Ad55 E4 Orf6 from p55E4 by PCR, ligating the two PCR products to obtain p55E4(5Orf6), linearizing the p55E4(5Orf6), obtaining pAd55ΔE1ΔE3(5Orf6) through homologous recombination of the linearized p55E4(5Orf6) with the linearized pAd55ΔE1ΔE3.
Most preferably, in an embodiment of the present invention, a specific process of step S4 comprises of:
Amplifying Ad5 E4 Orf6 using p5Orf2-6 and p55E4 as templates and introducing a restriction site SapI by PCR, removing Ad55 E4 Orf6 from p55E4, digesting the two PCR products with SapI and then ligating each other to obtain p55E4(5Orf6);
Digesting p55E4(5Orf6) with PmeI and MluI and digesting pAd55ΔE1ΔE3 with PsiI, obtaining the genomic plasmid pAd55ΔE1ΔE3(5Orf6) of which Ad55 E4 Orf6 is substituted with Ad5 E4 Orf6 through homologous recombination.
A method for preparing a human type 55 replication defective adenovirus vector also comprises the following steps:
S5 Amplifying homologous recombination ail is SE1L and SE1R of the E1 gene by PCR using the Ad55 genome as a template, digesting the aims and ligating the digested products into a pVax vector to obtain pSE1LR; amplifying an exogenous gene expression cassette CMV-EGFP-BGH by PCR using pGA1-EGFP as a template, digesting the pSE1LR and CMV-EGFP-BGH, ligating the two digested products to obtain pGK551-EGFP, linearizing the pGK551-EGFP, obtaining pAd55ΔE1ΔE3(5E4)-EGFP and pAd55ΔE1ΔE3(5Orf6)-EGFP through homologous recombination of the linearized pGK551-EGFP with the linearized pAd55ΔE1ΔE3 (5 E4) and pAd55ΔE1ΔE3(5Orf6) (mentioned in S3 step and S4 step) respectively, then transfecting the pAd55ΔE1ΔE3(5E4)-EGFP and pAd55ΔE1ΔE3(5Orf6)-EGFP into 293 cells after linearization, and obtaining human type 55 replication defective adenovirus vectors by centrifugal purification afterwards.
Preferably, a specific process of step S5 comprises of:
S5(1). Using the pVax, Ad55 genome and pGA1-EGFP as PCR templates respectively to obtain a Vax backbone, upstream and downstream homologous recombination arms SE1L and SE1R of the E1 gene region, the exogenous gene expression cassette CMV-EGFP-BGH; digesting the Vax backbone, SE1L and SE1R, then ligating each to obtain pSE1LR; digesting the CMV-EGFP-BGH and pSE1LR, then ligating each to obtain the shuttle plasmid pGK551-EGFP;
S5(2). Obtaining pAd55ΔE1ΔE3(5E4)-EGFP and pAd55ΔE1ΔE3(5Orf6)-EGFP through homologous recombination of the linearized pGK551-EGFP with the linearized pAd55ΔE1ΔE3(5E4) and pAd55ΔE1ΔE3(5Orf6) respectively;
S5(3). Linearizing pAd55ΔE1ΔE3 (5E4), pAd55ΔE1ΔE3(5Orf6), pAd55ΔE1ΔE3(5E4)-EGFP and pAd55ΔE1ΔE3(5Orf6)-EGFP with AsiSI, transfecting 293 cells with the linearized plasmids, obtaining purified human type 55 replication defective adenovirus vectors Ad55ΔE1ΔE3(5E4), Ad55ΔE1ΔE3(5Orf6), Ad55ΔE1ΔE3 (5E4)-EGFP and Ad55ΔE1ΔE3(5Orf6)-EGFP after amplification and density gradient centrifugation.
Most preferably, in an embodiment, a specific process of step S5 comprises of:
S5(1). Using the pVax and Ad55 genome as PCR templates respectively to obtain the Vax backbone, upstream and downstream homologous recombination aims SE1L and SE1R of the E1 gene region, digesting the Vax backbone with SpeI and SE1L with XbaI followed by phosphorylation, ligating the two fragments to obtain pSE1L; digesting pSE1L and SE1R with SpeI and EcoRV and ligating each to obtain pSE1R; using pGA1-EGFP as a template to obtain CMV-EGFP-BGH by PCR, digesting CMV-EGFP-BGH and pSE1LR with SpeI and EcoRV and ligating each to obtain the desired shuttle plasmid pGK551-EGFP with exogenous gene expression cassette;
S5(2). Digesting pGK551-EGFP with BstZ17I and SgrAI, and pAd55ΔE1ΔE3(5E4) and pAd55ΔE1ΔE3(5Orf6) with PmeI, obtaining pAd55ΔE1ΔE3(5E4)-EGFP and pAd55ΔE1ΔE3(5Orf6)-EGFP through homologous recombination of the digested pGK551-EGFP with the digested pAd55ΔE1ΔE3 (5E4) and pAd55ΔE1ΔE3(5Orf6) respectively;
S5(3). Linearizing pAd55ΔE1ΔE3 (5E4), pAd55ΔE1ΔE3(5Orf6), pAd55ΔE1ΔE3(5E4)-EGFP and pAd55ΔE1ΔE3(5Orf6)-EGFP with AsiSI, transfecting 293 cells for rescue and amplification of the linearized plasmids, obtaining purified human type 55 replication defective adenovirus vectors Ad55ΔE1ΔE3 (5E4), Ad55ΔE1ΔE3 (5Orf6), Ad55ΔE1ΔE3(5E4)-EGFP and Ad55ΔE1ΔE3(5Orf6)-EGFP by density gradient centrifugation.
Use of the human type 55 replication defective adenovirus vector for preparing vaccines.
Use of the human type 55 replication defective adenovirus vector for preparing neutralizing antibodies.
Use of the human type 55 replication defective adenovirus vector in biological reporter-tracer systems.
Use of the human type 55 replication defective adenovirus vector for preparing vaccines against human Ad55.
Uses of the human type 55 replication defective adenovirus vector for preparing drugs against human Ad55.
Beneficial effects: (1) the vectors of the present invention can be produced in helper cell lines such as 293 and PerC6 in large scale, can be purified by density gradient centrifugation, and have an attenuated phenotype for the lack of replication capacity in normal human cells; (2) the recombinant vectors can also express exogenous genes in target cells efficiently; (3) the recombinant vectors of the present invention can be used as vaccines or gene therapy vectors, and can also be used in research and development of drugs and neutralizing antibodies, as well as in reporter-tracer systems, etc.
The present invention discloses a method for preparing a human type 55 replication defective adenovirus vector. The preparation method and construction idea of the adenovirus vector of the invention can be applied to developing vaccines against adenovirus and other pathogenic viruses, screening anti-adenovirus drugs and neutralizing antibodies, and developing biological reporter-tracer systems.
The term “human type 55 adenovirus” in the present invention refers to type 55 adenovirus known to one skilled in the art, and the Ad55 genome used in the embodiments is also derived from these known human type 55 adenoviruses. The human type 55 replication defective adenovirus vector of the present invention is not limited to the particular clinical isolates employed in the embodiments.
The term “exogenous sequence” of the present invention refers to any DNA sequence not derived from Ad55. One skilled in the art should recognize that the exogenous sequence may be an exogenous gene expression cassette, or a shRNA or miRNA expression cassette.
In the following embodiments, the exogenous gene expression cassette may comprise a eukaryotic promoter, an exogenous gene coding sequence and a transcription terminator, as understood by one skilled in the art. The exogenous gene coding sequence may be, but is not limited to, a coding sequence of green fluorescent protein, other viral antigens, or shRNA etc.
In order to provide a clearer understanding of the technical solution of the present invention, the following embodiments are given in detail with reference to drawings. It is to be understood that the embodiments are merely illustration of the invention and are not intended to limit the scope of the invention. Experimental methods not specified in the following embodiments are generally carried out according to conventional conditions, such as those described in Molecular Cloning: Laboratory Manual (Sambrook, et al, 1989, New York, Cold Spring Harbor Laboratory Press), or suggested by the manufacturers. Chemical agents used in the embodiments are commercially available.
Unless otherwise defined, all technical and scientific terms used in the present invention have the same meaning as commonly understood by one skilled in the art. The terminology used in the specification of the present invention is for the purpose of describing particular embodiments only and is not intended to limit the invention.
1. Construction of Shuttle Plasmid pVax-delE1(L+R) with the E1 Gene Knocked Out
The Ad55 genome was used as the PCR template to amplify and obtain the recombinant arms L-delE1 and R-delE1.
L-delE1 primer sequence:
PCR program: 95° C., 30 s; 62° C., 30 s; 72° C., 20 s; 25 circles.
R-arm primer sequence:
PCR program: 95° C., 30 s; 60° C., 30 s; 72° C., 80 s; 25 circles.
The L-delE1 was digested with SpeI and EcoRI and then ligated to pVax vector (Invitrogen) which was digested with the same endonucleases to obtain pVax-L-delE1; R-delE1 was digested with EcoRI and XbaI and then ligated to the pVax-L-delE1 digested with the same endonucleases to obtain shuttle plasmid pVax-delE1(L+R) with the E1 gene knocked out. Detection of R-delE1 in pVAX-delE1(L+R) by PCR assay were shown in
2. Construction of Plasmid pAd55ΔE1ΔE3-Kana
The pVax-delE1(L+R) was linearized by EcoRI and the pAd55ΔE3 was linearized by PacI, then the two linearized plasmids were co-transformed into BJ5183 competent cells (Stratagene); after screening with ampicillin and kanamycin, the plasmids were extracted, and further transformed into XL-Blue competent cells (Peking Baihui Biotechnology Co., Ltd.); the plasmids were extracted to obtain plasmid pAd55ΔE1ΔE3-Kana. Restriction maps were constructed using multiple groups of restriction endonuclease. Two PmeI restriction sites were introduced in original E1 gene region of adenovirus genome of the achieved plasmid pAd55ΔE1ΔE3-Kana in order to facilitate subsequent cloning. See a schematic of plasmid construction in
1. Construction of shuttle plasmid pVax-delK(L+R) with KanaR-gene knocked out.
The Ad55 genome was used as the PCR template to amplify and obtain recombinant aims L-delK and R-delK.
L-delK primer sequence:
PCR program: 95° C., 30 s; 61° C., 30 s; 72° C., 20 s; 25 circles.
R-delK primer sequence:
PCR program: 95° C., 30 s; 60° C., 30 s; 72° C., 80 s; 25 circles.
The L-delK was digested with SpeI and EcoRI and then ligated to pVax vectors (Invitrogen) digested with the same endonucleases to obtain pVax-L-delK; R-delK was digested with EcoRI and XbaI and then ligated to the pVax-L-delE3 digested with the same endonucleases to obtain shuttle plasmid pVax-delK(L+R) of which the KanaR gene was knocked out. Detection of R-delK in pVAX-delK(E1) by PCR assay were shown in
2. Construction of Plasmid pAd55ΔE1ΔE3
The pVax-delK(L+R) was linearized with SpeI and XbaI, and the pAd55ΔE1ΔE3-Kana was linearized with PmeI, the two linearized plasmids were then co-transformed into BJ5183 competent cells (Stratagene), then the plasmids were extracted and transformed into XL-Blue competent cells (Peking Baihui Biotechnology Co., Ltd.), then the plasmids were extracted and indentified by restriction analysis. The genomic plasmid pAd55ΔE1ΔE3 was obtained, wherein the KanaR gene was removed and unique restriction site PmeI was introduced in the E1 region. See a schematic of plasmid construction in
1. Construction of Shuttle Plasmid with Ad55E4 Gene Modified
1) The Ad55 genome was used as the PCR template to amplify and obtain Ad55E4 gene, and the primers used were as follows:
PCR program: 95° C., 30 s; 61° C., 30 s; 72° C., 4 min; 25 circles.
The PCR products were phosphorylated, and were ligated to blunt-ended T vectors (TaKaRa) to obtain p55E4.
2) The p55E4 plasmid was used as the PCR template to amplify and obtain linearized p55E4 with SapI restriction site introduced at the ends and Ad55 E4 Orf6 gene removed.
PCR program: 95° C., 30 s; 63° C., 30 s; 72° C., 5 min; 25 circles.
Ad5 E4 Orf6 gene with SapI site at the ends was obtained by PCR using Ad5 genome as template.
PCR program: 95° C., 30 s; 61.5° C., 30 s; 72° C., 45 s; 25 circles.
The linearized p55E4 and Ad5 E4Orf6 were digested with SapI and then ligated with each other to obtain p55E4 (5Orf6).
3) Similarly, the p55E4 plasmid was used as the PCR template to amplify and obtain linearized p55E4 with SapI restriction site and Ad55 E4Orf(2-6) gene knocked out. The primers used were as follows:
PCR program: 95° C., 30 s; 61.5° C., 30 s; 72° C., 4 min; 25 circles.
Ad5 E4Orf(2-6) with SapI site at the ends was obtained by PCR using Ad5 genome as template.
PCR program: 95° C., 30 s; 61° C., 30 s; 72° C., 2 min; 25 circles.
The linearized p55E4 and Ad5 E4Orf(2-6) fragments were digested with SapI and then ligated with each other to obtain p55E4(5E4).
2. Construction of pAd55ΔE1ΔE3(5Orf6) and pAd55ΔE1ΔE3(5E4).
The p5E4(5Orf6) and p55E4(5E4) were linearized with MluI and PmeI, and the pAd55ΔE1ΔE3 was linearized with PsiI, then the linearized fragments were co-transformed into BJ5183 competent cells to obtain genomic plasmids pAd55ΔE1ΔE3(5Orf6) and pAd55ΔE1ΔE3 (5E4) with E1 and E3 genes knocked out and E4 gene modified through recombination. See a schematic of plasmid construction in
1. Construction of Shuttle Plasmid pGK551-EGFP with Exogenous Gene Expression Cassette.
1) Ad55 genome was used as the PCR template to amplify and obtain homologous recombination aims SE1L and SE1R.
SE1L primer sequences:
PCR program: 95° C., 30 s; 61° C., 30 s; 72° C., 30 s; 25 circles.
SE1R primer sequences:
PCR program: 95° C., 30 s; 60° C., 30 s; 72° C., 1 min 30 s; 25 circles.
2) Construction of shuttle plasmids pSE1LR.
pSE3LR and SE1L were digested with KpnI and EcoRV, and then ligated with each other to obtain pSE1L; the pSE1L and SE1R were digested with SpeI and MluI, and then ligated with each other to obtain pSE1LR.
3) Construction of shuttle plasmids pGK551-EGFP and the like with exogenous gene expression cassette.
CMV-EGFP-BGH expression cassette was obtained using pGA1-EGFP as template and the following primer by PCR.
PCR program: 95° C., 30 s; 66° C., 30 s; 72° C., 1 min 45 s; 25 circles.
pSE1LR was digested with SpeI and EcoRV, and CMV-EGFP-BGH was digested with SpeI, then they were ligated with each other to obtain target shuttle plasmid pGK551-EGFP. Detection of EGFP in pGK551-EGFP by PCR assay were shown in
2. Construction of Genomic Plasmid pAd55ΔE1ΔE3(5Orf6)-EGFP and the Like.
pG551-EGFP was digested with BstZ17I and SgrAI and recovered by ethanol precipitation; and the pAd55ΔE1ΔE3(5Orf6) and pAd55ΔE1ΔE3(5E4) were linearized with PmeI and then recovered by ethanol precipitation; then the linearized fragments were co-transformed into BJ5183 to obtain plasmids pAd55ΔE1ΔE3(5Orf6)-EGFP and pAd55ΔE1ΔE3(5E4)-EGFP with exogenous gene expression cassette through homologous recombination. See a schematic of detailed construction process in
According to a conventional method, the pAd55ΔE1ΔE3(5Orf6)-EGFP and pAd55ΔE1ΔE3(5E4)-EGFP were linearized with AsiSI and recovered by ethanol precipitation, respectively, and then transfected into 293 cells through cationic liposome. 8 hours after transfection, 2 ml DMEM medium containing 5% fetal bovine serum was added and incubated for 7-10 days, the cell pathogenesis was observed. Subsequently, the cells and culture supernatant were collected, repeatedly freezed and thawed for 3 times in the water bath of 37° C. and liquid nitrogen, and then the cellular debris were removed by centrifugation. The supernatants were added into a 10 cm dish cell cultures. 2-3 days later, the cells and culture supernatant were collected, then the cellular debris were removed by repeated freezing and thawing for 3 times and centrifugation, the supernatants were added into 6-10 15 cm dishes; 2-3 days later, the cells were collected, then the cellular debris were removed by repeated freezing and thawing for 3 times and centrifugation, the supernatants were added into a centrifuge tube of cesium chloride density gradient and centrifuged for 4 hours at 4° C., 35000 rpm; the virus band was separated, desalted and packed; the virus titer was determined by OD260 absorbance under the formula i.e. virus concentration=OD260×dilution factor×36/genome length (kb); the virus solution was stored at −80° C. Purification of the replication defective Ad55 vectors h cesium chloride density gradient centrifugation were shown in
According to a conventional method, the replication capability of replication defective Ad55 vectors in helper cells 293 and non-helper cell A549 was examined by plaque-forming assay. 90% confluent 293 and A549 cells in 6-well plate were infected with Ad55ΔE1ΔE3(5Orf6)-EGFP, Ad55ΔE1ΔE3(5E4)-EGFP or Ad55ΔE3-EGFP at a dose of 1×107Vp per well. 4 hours after infection, the culture medium was removed and the cells were coated with 1% agarose gel (containing 1% agarose, 5% fetal bovine serum, 1×MEM medium). After 10-12 days' incubation in an incubator at 37° C., the virus plaques were observed with fluorescence microscope and the graphs were taken. The results were shown in
Immunogenicity of replication defective Ad55 was evaluated according to the immunization protocol shown in
Balb/c mice at 6-8 weeks of age were divided into 9 groups, each group had 5 mice. On day 0, 8 groups of mice were injected intramuscularly with heat-inactived Ad55ΔE3-EGFP, Ad55ΔE3-EGFP, Ad55ΔE1ΔE3(5Orf6)-EGFP and Ad55ΔE1ΔE3(5E4) at a dose of either 1×108Vp per mice or 1×1010Vp per mice, respectively. One group of mice was immunized with Ad5ΔE1ΔE3 as control. On day 21, blood samples were collected from orbit and the serum was separated. Meanwhile, the mice were boosted with respective vaccines according to the above protocol. On day 35, the mice were sacrificed and the serum samples were collected. At last, the level of anti-Ad55 neutralizing antibodies in the serums was measured.
According to a conventional method, Ad55E3-SEAP and Ad5-SEAP were used as reporter viruses to detect the neutralizing antibodies against Ad55 and Ad5 in mice serum, respectively. 293 cells were seeded onto 96-well plates. The mice serum was serially diluted with medium free of phenol and serum. The Ad55ΔE3-SEAP or Ad5-SEAP were co-incubated with serum dilutions at a dose of 1×107Vp per sample at 37° C. for an hour, and added to the cell culture plate. After incubation for 24 hours, 50 μl of culture supernatants were transferred to 96-well black plate. The Phospha-Light™ system (Applied Biosystem) was used to detect the ralative light units (shown on the fluorescence illuminometer), and the neutralizing antibody titer was calculated based on the relative light units. The immunized mice could generate Ad55 neutralizing antibody after the primary immunization the neutralization antibody titer in mice was shown in
According to the methods described in Examples 4 and 5, the coding sequences for glycoprotein (GP) of Ebola virus (two strains of Zaier subtype, Guinea 2014 and Maynia1976, which were designated as GP (ZG) and GP (ZM) respectively) were codon optimized and cloned into shuttle plasmid pGK551 to obtain pGK551-GP(ZG) and pGK551-GP(ZM). The shuttle plasmids were then linearized with BstZ17I and SgrAI, and recombined with pAd55ΔE1ΔE3(5E4) linearized with PmeI to obtain pAd55-GP(ZG) and pAd55-GP(ZM), respectively. The genomic structure of the replication defective Ad55 vectors harboring GP gene of Ebola virus was illuminated by
The examples described above are merely illustrations of several embodiments of the present invention, and the specific and detailed description are not intended to limit the scope of the invention. It should be noted that within the scope of the present invention, various modifications and variations are possible in light of the above teachings for those skilled in the art. Accordingly, the scope of the present invention should be determined by the appended claims.
Number | Date | Country | Kind |
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2015 1 0179459 | Apr 2015 | CN | national |
This present application is a Continuation Application of PCT application No. PCT/CN2015/095730 filed on Nov. 27, 2015, which claims the benefit of Chinese Patent Application No. 201510179459.7 filed on Apr. 15, 2015, the contents of which are hereby incorporated by reference.
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7468181 | Vogels | Dec 2008 | B2 |
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Zhou et al. An efficient method of directly cloning chimpanzee adenovirus as a vaccine vector. Nov. 2010. Nat Protoc. vol. 5, No. 11, pp. 1775-1785. (Year: 2010). |
Zhang et al. (Genome Sequence of Human Adenovirus Type 55, a Re-Emergent Acute Respiratory Disease Pathogen in China. Nov. 2012. Journal of Virology. vol. 86, No. 22, pp. 12441-12442. (Year: 2012). |
Xingguo Mei, Construction of Adenovirus Carrier, Microcarrier Drug Delivery System, 2009, p. 332. |
Liuxin Dong, Expression of Type-specific E1B55K Gene Enhanced the Propagation of Human Adenovirus Type 41 in 293 Cells, China Doctoral Dissertations Full-text Database, 2011, pp. E059-E011. |
Chengjun Wu, Construction of Ad35 Adenovirus Carrier and the Research of Viral Albumen Immunogenicity, China Doctoral Dissertations Full-text Database, 2011, pp. E059-E094. |
1st Office Action of counterpart Chinese Patent Application No. 201510179459.7 dated Jul. 7, 2017. |
Number | Date | Country | |
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20180179554 A1 | Jun 2018 | US |
Number | Date | Country | |
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Parent | PCT/CN2015/095730 | Nov 2015 | US |
Child | 15784224 | US |