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  • Podsumowanie
  • Streszczenie
  • Wprowadzenie
  • Protokół
  • Wyniki
  • Dyskusje
  • Ujawnienia
  • Podziękowania
  • Materiały
  • Odniesienia
  • Przedruki i uprawnienia

Podsumowanie

In this protocol, AAV2 vector is produced by co-culturing Spodoptera frugiperda (Sf9) insect cells with baculovirus (BV)-AAV2-green fluorescent protein (GFP) or therapeutic gene and BV-AAV2-rep-cap infected Sf9 cells in suspension culture. AAV particles are released from the cells using detergent, clarified, purified by affinity column chromatography, and concentrated by tangential flow filtration.

Streszczenie

Adeno-associated viruses (AAV) are promising vectors for gene therapy applications. Here, the AAV2 vector is produced by co-culture of Spodoptera frugiperda (Sf9) cells with Sf9 cells infected with baculovirus (BV)-AAV2-GFP (or therapeutic gene) and BV-AAV2-rep-cap in serum-free suspension culture. Cells are cultured in a flask in an orbital shaker or Wave bioreactor. To release the AAV particles, producer cells are lysed in buffer containing detergent, which is subsequently clarified by low-speed centrifugation and filtration. AAV particles are purified from the cell lysate using AVB Sepharose column chromatography, which binds AAV particles. Bound particles are washed with PBS to remove contaminants and eluted from the resin using sodium citrate buffer at pH 3.0. The acidic eluate is neutralized with alkaline Tris-HCl buffer (pH 8.0), diluted with phosphate-buffered saline (PBS), and further concentrated with tangential flow filtration (TFF). The protocol describes small-scale pre-clinical vector production compatible with scale-up to large-scale clinical-grade AAV manufacturing for human gene therapy applications.

Wprowadzenie

Adeno-associated viruses (AAV) are non-enveloped human parvoviruses containing a single-stranded DNA of 4.6 kb. AAV vectors have several advantages over other viral vectors for gene therapy applications1,2,3,4. AAVs are naturally replication-incompetent, thereby, require a helper virus and host machinery for replication. AAVs do not cause any disease and have low immunogenicity in the infected host3,5. AAV can infect both quiescent and actively dividing cells and may persist as episome without integrating into the genome of the host cells (AAV rarely integrate into the host genome)1,3. These features have made AAV a desirable tool for gene therapy applications.

To generate an AAV gene transfer vector, the transgene cassette, including the therapeutic gene, is cloned between two internal terminal repeats (ITRs), which are typically derived from the AAV serotype 2. The maximum size from 5' ITR to 3' ITR, including the transgene sequence, is 4.6 kb6. Different capsids may have a different cell or tissue tropism. Therefore, capsids should be chosen based on the tissue or cell type intended to be targeted with the AAV vector7.

Recombinant AAV vectors are commonly produced in mammalian cell lines such as human embryonic kidney cells, HEK293 by transient transfection of the AAV gene transfer vector, AAV rep-cap, and helper virus plasmids2,3. However, there are several limitations for large-scale AAV production by transient transfection of adherent HEK293 cells. First, a large number of cell stacks or roller bottles are needed. Second, high-quality plasmid DNA and transfection reagents are needed, which increases the cost of manufacturing. Finally, when using adherent HEK293 cells, the serum is frequently needed for optimal production, complicating downstream processing1,2,3. An alternative method of AAV manufacturing involves using the insect cell line, Spodoptera frugiperda (Sf9) cells, and an insect virus called recombinant Autographa californica multicapsid nuclear polyhedrosis virus (AcMNPV or baculovirus)8,9,10. Sf9 cells are grown in serum-free suspension culture that is easy to scale up and is compatible with current good manufacturing practice (cGMP) production at a large scale, which does not require plasmid or transfection reagents. Moreover, the cost of the AAV production using the Sf9-baculovirus system is lower than the cost of using transient transfection of plasmids into HEK293 cells11.

The original rAAV production system using baculovirus-Sf9 cells used three baculoviruses: one baculovirus containing gene transfer cassette, the second baculovirus containing rep gene, and the third baculovirus containing serotype-specific capsid gene12,13. However, the baculovirus containing rep construct was genetically unstable upon multiple rounds of passages, which prevented amplification of the baculovirus for the large-scale AAV production. To resolve this issue, a novel rAAV vector system was developed, which contained two baculoviruses (TwoBac): one baculovirus containing the AAV gene transfer cassette and another baculovirus containing the AAV rep-cap genes together which are genetically more stable than the original system and more convenient to produce rAAV because of using TwoBac instead of three14,15. The OneBac system uses the AAV gene transfer cassette and the rep-cap genes in a single baculovirus which is more convenient to produce the rAAV because of using one baculovirus instead of using TwoBac or ThreeBac2,16,17. In our study, the TwoBac system was used for optimization.

The baculovirus system for AAV production also has limitations: baculovirus particles are unstable for long-term storage in serum-free medium11, and if the baculovirus titer is low, a large volume of baculovirus supernatant is needed, which may become toxic to the growth of Sf9 cells during AAV production (personal observation). The use of titer-less infected-cell preservation and scale-up (TIPS) cells, or baculovirus-infected insect cells (BIIC), provides a good option for AAV production in which baculovirus-infected Sf9 cells are prepared, cryopreserved, and subsequently used for infection of fresh Sf9 cells. Another advantage is the increased stability of baculovirus (BV) in Sf9 cells after cryopreservation10,11.

Two types of TIPS cells are generated to enable AAV production: the first one by infection of Sf9 cells with the BV-AAV2-GFP or therapeutic gene, and the second one by infection of Sf9 cell with BV-AAV2-rep-cap. TIPS cells are cryopreserved in small and ready-to-use aliquots. AAV vectors are produced in serum-free suspension culture in a flask placed in an orbital shaker or Wave bioreactor by co-culturing TIPS cells that produce baculoviruses and fresh Sf9 cells. Sf9 cells are infected by baculoviruses that carry the AAV2-GFP vector and the rep-cap sequences to generate AAV. Four to five days later, when AAV yields are the highest, the producer cells are lysed with detergent to release the AAV particles. The cell lysate is subsequently clarified by low-speed centrifugation and filtration. AAV particles are purified from the lysate by AVB Sepharose column chromatography. Finally, AAV vectors are concentrated using TFF. The protocol describes the production of AAV at a small scale, useful for research and pre-clinical studies. However, the methods are scalable and compatible with manufacturing clinical-grade AAV vectors for gene therapy applications.

Protokół

See Figure 1 for an illustration summarizing the protocol.

1. Generation of baculovirus-infected TIPS cells

  1. Thaw one vial of Sf9 cells and immediately seed them in 50 mL of insect cell culture medium. Grow Sf9 cells in an orbital shaker incubator at 125 rpm and 28 °C in round bottom flasks with a loosely attached cap for exchange of air8,9. Propagate the cells in a 1 L flask containing 200 mL of medium to obtain enough cells for TIPS cells production.
  2. Add 50 mL of Sf9 cells at 2 x 106 cells/mL in two flasks: infect one flask of Sf9 cells with 0.5 mL of baculovirus (BV)-AAV2-GFP (or therapeutic gene) and the other flask of cells with 0.5 mL of BV-AAV2-rep-cap.
    NOTE: AAV vector plasmids were generously provided by Dr. Robert M. Kotin (NIH). Baculovirus production from bacmid DNA (Bac-to-Bac System) has been described previously8,9. The baculovirus stability during the passage is a critical problem for the scale-up production of rAAV. It is better to use a lower passage number of baculovirus (up to passage number 4). Determine the optimal volume of the baculovirus supernatant empirically by checking the baculovirus infection efficiency using flow cytometry (Figure 2) during TIPS cell production.
  3. Monitor the baculovirus infection 3-4 days post-infection by staining baculovirus gp64 in infected Sf9 cells as follows.
    1. Stain 2 x 105 Sf9 cells (both uninfected and baculovirus-infected cells) with 0.5 µg of mouse anti-baculovirus gp64 antibody (1:200) containing a fluorescent dye in 100 µL of blocking buffer for 30 min at ambient temperature.
    2. Wash the cells with 1 mL of PBS to remove the antibody and resuspend the stained cells in 300 µL of PBS containing 0.5% bovine serum albumin.
    3. Analyze the baculovirus gp64 expression on cells using flow cytometry (Figure 2).
      NOTE: Determine the gating strategy for flow cytometry acquisition and analysis empirically. A total of 10,000 single live cells is acquired. Baculovirus gp64 expression on Sf9 cell surfaces indicates baculovirus infection. After 3-4 days, most of the Sf9 cells become infected with the baculovirus, as evidenced by baculovirus gp64 expression (Figure 2).
  4. When the cells are 80%-90% viable with an increase in the diameter (Figure 3), harvest the cells and cryopreserve 1 x 107 cells in 1 mL of insect culture medium supplemented with 10% fetal bovine serum and 10% dimethyl sulfoxide in a slow-freezing container at -80 °C. The next day, transfer the tube containing TIPS cells to a liquid nitrogen freezer for long-term storage.
    ​NOTE: Perform cell culture in a biosafety cabinet following the standard aseptic laboratory technique at Biosafety Level 2 (BSL-2).

2. Production of AAV vector

  1. Day 1: Co-culture Sf9 cells with the baculovirus-infected TIPS cells
    1. Culture and grow naive Sf9 cells at 1 x 106 cells/mL at 28 °C in several 2 L flasks containing 400 mL of insect cell culture medium in a shaker incubator that is needed for AAV production. After 3-4 days, the cell density is increased up to 5 x 106-6 x 106 cells/mL.
      NOTE: CO2 and humidity are not important factors for the growth of Sf9 cells.
    2. Seed the Sf9 cells either in shake flasks or in a bioreactor as follows.
      1. AAV production in flasks in an orbital shaker incubator: Use a pipette or a peristaltic pump to seed 400 mL of Sf9 culture at 2 x 106 cells/mL into a 2 L flask aseptically. Set up the orbital shaker at 125 rpm and 28 °C.
        ​NOTE Use a peristaltic pump or standard pipette depending on the scale of the AAV production.
      2. AAV production in a bioreactor: Use a peristaltic pump to seed 1 L of Sf9 culture at 2 x 106 cells/mL into a 10 L bioreactor bag aseptically. Load the bag onto the Bioreactor unit for culturing at 28 °C. Add 40% oxygen to the bioreactor bag at 0.1 psi. Set up the bioreactor unit at a 20° angle and shake the bag at 25 rpm.
    3. Thaw one vial of each BV-AAV2-GFP (or therapeutic gene) and BV-AAV2-rep-cap TIPS cells. Dilute the cells with 20 mL of insect culture medium and perform a viability count of the cells using trypan blue. Inoculate both TIPS cells at a ratio of 1:10,000 relative to the naive Sf9 cells cultured in a shaker flask or bioreactor.
      ​NOTE: The survival of the TIPS cells is reduced due to cryopreservation, and the recovery rate is approximately 50% when cell viability is determined with the trypan blue staining. Perform a pilot experiment to empirically determine the ratio of TIPS cells and naïve Sf9 cells before large-scale rAAV production.
  2. Day 2: Culture monitoring
    1. Harvest 1 mL of Sf9 culture aseptically. Stain with the Trypan blue dye to analyze the cell count, viability, and morphology.
  3. Day 3: Culture monitoring and feeding
    1. Harvest 1 mL of Sf9 culture and analyze the cell count, viability, and morphology. Check the status of baculovirus infection after staining the Sf9 cells as mentioned in step 1.3.
      NOTE: Increase in cell diameter and cytopathic effect are indications of baculovirus infection. The increase in diameter precedes a decrease in cell viability, and these parameters are used to determine the cell harvest time during AAV production. Determine the optimal time point empirically.
    2. Feed the Sf9 culture with fresh insect culture medium at a ratio of 1:5 aseptically.
  4. Day 4: Culture monitoring
    1. Harvest 1 mL of Sf9 culture and analyze the cell count, viability, and morphology. Disconnect oxygen supply from the bioreactor bag.
  5. Day 5: Culture monitoring and harvest
    1. Harvest 1 mL of Sf9 culture and analyze the cell count, viability, and morphology. Harvest the culture medium and cells when Sf9 cell viability has decreased to around 50% (Figure 4).
    2. Spin the cell suspension at 2100 x g for 15 min at 4 °C. Collect the supernatant and the cell pellet, and store them at -80 °C.

3. Lysis of cells and release of AAV

  1. Thaw the AAV producer cell pellet. Add 100 mL of cell lysis buffer (20 mM Tris-HCl pH 8.0, 150 mM sodium chloride, 0.5 % Triton-X-100) to the cell pellet, mix vigorously, and incubate for 30 min at ambient temperature to release the AAV particles.
  2. Centrifuge at 2100 × g for 30 min at 4 °C and transfer the cell lysate to a new container. Mix the cell lysate and cell culture supernatant after thawing.
  3. Add 20 U/mL nuclease and 10 mM MgCl2 to the cell lysate to digest the DNA and RNA. Incubate for 2-4 h at 37 °C.
  4. Filter the lysate through a 0.8 µm and 0.2 µmpolyethersulfone dual filtration system using a pump.
  5. Store the clarified cell lysate at 4 °C overnight or purify the AAV immediately.

4. Purification of AAV vector using affinity column chromatography system

  1. Prepare the chromatography instrument by sequentially washing the sample and buffer lines with sterile water, 1 N sodium hydroxide, water, and phosphate-buffered saline (PBS, pH 7.4) at a flow rate of 50 mL/min.
  2. Mount the AVB Sepharose column (10.0 mL) into the chromatography system, and run 100 mL of PBS at a flow rate of 5 mL/min.
    NOTE: Use a lower or higher volume of AVB Sepharose column depending on the scale of AAV production and set up the flow rate as suggested by the column or resin manufacturer (see Table of Materials).
  3. To collect the fractions of column pass-through solution, wash buffer, and elution buffer containing AAV particles, insert tubes into the fraction collector slots of the chromatography instrument.
  4. Equilibrate the column with PBS at a flow rate of 5.0 mL/min.
  5. Load the filtered cell lysate containing AAV particles onto the column using the chromatography machine equipped with a sample pump. Run the sample at a flow rate of 3.0 mL per min.
  6. Run PBS through the AVB Sepharose column at a flow rate of 3.0 mL/min until the ultraviolet (UV) absorbance curve (280 nm) returns to the baseline and becomes stable.
  7. Elute the AAV particles from the column with 50 mM sodium citrate (pH 3.0) buffer at a flow rate of 3.0 mL/min (Figure 5).
    NOTE: While the AAV particles dissociate from the resin and pass through the UV detector, an elution peak of protein can be seen on the chromatogram.
  8. Immediately dilute the AAV supernatant with a one-fifth volume of 500 mM Tris-HCl (pH 8.0) to increase the pH of the AAV containing supernatant to approximately pH 5.5 to prevent pH-mediated degradation with acidic elution buffer. Further, dilute the AAV supernatant 10-fold with PBS to fully neutralize the pH.
    NOTE: The pH value is approximately 5.5 after neutralizing the rAAV solution. After neutralizing AAV, dilute the rAAV solution 10-fold with PBS (pH 7.4) so that AAV is in a physiologic buffer.
  9. Store 1 mL of each column run-through samples, wash buffer, and 100 µL of the eluted AAV supernatant to evaluate the presence of AAV by infection of the target cells.
  10. Clean the AVB Sepharose column with 100 mL of 100 mM citric acid (pH 2.1) and 100 mL of PBS (pH7.4) at a flow rate of 5.0 mL/min. Rinse the column with 20% ethanol at a flow rate of 5.0 mL/min and store at 4 °C.
  11. Clean the pipelines of the chromatography instrument with the column offline position as described in section 4.1. Finally, rinse the chromatography system with 200 mL of 20% Ethanol at a flow rate of 50.0 mL/min and store in 20% ethanol.

5. Concentration and diafiltration of AAV vector using tangential flow filtration (TFF)

  1. Set up the TFF system equipped with a polysulfone membrane cartridge (100 kDa Molecular Weight Cut Off) to concentrate the AAV.
  2. Equilibrate TFF module with 200 mL of PBS for 10 min.
  3. Load the AAV sample by controlling the pump's flow until the sample is reduced to the desired volume while maintaining a trans-membrane pressure at 2-3 psi.
  4. Diafiltrate the retentate with 100 mL of PBS, as used in this study, or empirically define alternate buffer that supports long-term stability of AAV.
  5. After concentrating the AAV sample to the desired volume, collect the AAV sample, filter it through a 0.2 µm polyethersulfonefilter, aliquot, and then store it at -80 °C.

6. Infection of AAV samples into the target cells to evaluate the presence of AAV in the purification steps

  1. Inoculate 7 x 104 HT1080 cells/well in a 24-well plate in 500 µL of Dulbecco's Modified Eagle's Medium (DMEM) supplemented with 1% L-glutamine, 1% sodium pyruvate, and 10% fetal bovine serum (FBS) the day before infection. Culture the cells in an incubator at 37 °C and 5% CO2.
  2. Count the cells before infection. Add the diluted unpurified AAV bulk sample before the column run, column run-through samples, wash buffer, and eluted purified AAV sample.
    NOTE: Count the Trypan blue-stained cells with a hemocytometer. Determine the dilution factor and volume (µL) of the AAV samples empirically. The higher the AAV titers, the more dilution is needed. Ensure that the baculovirus particles of the unpurified bulk sample before the column run, column run-through samples, wash buffer are heat-inactivated at 50 °C for 50 min before infecting the target cells to determine infectious titers of AAV.
  3. Two days after infection, analyze the protein expression (e.g., GFP or therapeutic gene) in the cells using a flow cytometer.
  4. Calculate infectious titers of AAV using the number of cells at the time of infection, dilution factor, and percentage of GFP+ cells with the formula: (Total number of cells x Percentages GFP+ cells x Dilution Factor) / Volume of AAV in milliliters.
    NOTE: For example, the number of cells is 1 x 105, the percentage of GFP+ cells is 3.4%, the dilution factor is 100, and the volume of AAV added is 2 µL. The titer of AAV is 1.7 x 108 infectious unit (IU)/mL. The total amount of purified AAV particles in 25 mL of the eluted fraction is 4.3 x 109 infectious units (IU)/mL (Figure 6). The total number of initial unpurified AAV particles is 1.09 x 1010 IU/mL, and purified AAV particles are 4.3 x 109 IU/mL. Therefore, the percentage of recovery is 39.4%. The percentage of GFP+ cells should be between 1%-30%, which corresponds to a linear range when used to calculate the infectious titer of AAV. If more concentrated AAV vector particles are infected into the target cells; there is a possibility that multiple copies of the AAV particles may infect a single cell that will show as a single copy of the vector. Therefore, dilute the AAV vector supernatant to obtain 1%-30% vector infection in the target cells. If the AAV vector does not have a reporter gene, stain the transgene or the therapeutic gene expressed by the AAV vector with an antibody containing a fluorescent dye that can be detected and quantitated using a flow cytometer. Not all AAV serotypes can efficiently infect HT1080 cells. Therefore, to perform the infectivity assay for other AAV serotypes, use different cell lines. Titer the AAV2-GFP particles before purification and after purification on HT1080 cells and measure the GFP expression by flow cytometry. Calculate the recovery (%) by the ratio of the number of purified AAV particles and the number of AAV particles prior to purification multiplied by 100.

Wyniki

Here, the representative results of process development for the production and purification of AAV vectors using the Sf9 insect cell system are shown. The method includes co-culture of Sf9 cells with baculovirus-infected TIPS cells, feeding the cells with growth medium, harvesting and lysis of the producer cells to release the AAV particles, clarification of the cell lysate with nuclease treatment, centrifugation and filtration, purification of AAV using AVB Sepharose affinity chromatography, and concentration with TFF (...

Dyskusje

The parameters used in this protocol for the process development of production, purification, and concentration of AAV vectors can be applied to both small and large-scale manufacturing of AAV vectors for gene therapy applications. The entire upstream and downstream process can be performed in a closed system compatible with the current Good Manufacturing Practices (cGMP). The major advantages of the Sf9-baculovirus system are scalability for large-scale GMP-grade AAV production at an affordable cost. The system does not...

Ujawnienia

The authors declare no conflicts of interest.

Podziękowania

We would like to thank Dr. Robert M. Kotin (National Heart, Blood and Lung Institute, NIH) for generously providing us the AAV plasmids and Danielle Steele and Rebecca Ernst (Cincinnati Children's Hospital) for their technical assistance. This work is supported by the Start-Up fund from Cincinnati Children's Research Foundation to M.N.

Materiały

NameCompanyCatalog NumberComments
1 N Sodium HydroxideSigma-Aldrich1.09137For Akta Avant cleaning
2 L flasksThermoFisher Scientific431281Flask for suspension culture
50 ml Conical tubeThermoFisher Scientific14-959-49AFor collection of supernatants
24-well plateThermoFisher Scientific07-200-80Adherent cell culture plate
250 mL flasksThermoFisher Scientific238071Flask for suspension culture
Akta Avant 150 with Unicorn SoftwareCytiva28976337Chromatography system
AVB Sepharose High PerformanceCytiva28411210Chromatography medium
Baculovirus-AAV-2 GFPIn-housenon-catalogAAV transfer vector
Baculovirus-AAV-2 rep-capIn-housenon-catalogAAV packaging vector
NucleaseSigma-AldrichE1014Enzyme to degrade DNA and RNA
Blocking bufferSanta Cruz Biotechnologies516214Blocking to prevent non-specific antibody binding to cells
Cell lysis bufferIn-houseNon-catalog item20 mM Tris-HCl (pH 8.0), 150 mM NaCl, 0.5 % Titron X-100
Cellbag, 2 L and 10 LCytiva28937662Bioreactor bag
Cleaning bufferIn-houseNon-catalog item100 mM citric acid (pH 2.1) 
CryovialThomas Scientific1222C24For cryopreservation
DMEMSigma-AldrichD6429Growth media for cell lines
Elution bufferIn-houseNon-catalog item50 mM sodium citrate buffer (pH 3.0)
EthanolSigma-AldrichE7073For disinfection and storage of the chromatography
Filtration unit Pall Corporation12941Membrane filter
HT1080 cell lineATCCCCL-121Fibroblast cell line
HyClone™ SFX-Insect culture mediaCytivaSH30278.02Serum-free insect cell growth medium
Peristaltic PumpPall CorporationNon-catalog itemTFF pump
MaxQ 8000 orbital shaker incubator ThermoFisher ScientificNon-catalog itemShaker for suspension culture
MicroscopeNikonNon-catalog itemCell monitoring and counting 
Mouse anti-baculovirus gp64 PE antibodySanta Cruz Biotechnologies65498 PEMonitoring baculovirus infection in Sf9 cells
Oxygen tankPraxairNon-catalog item40 % Oxygen supply is needed for Sf9 cell growth
PBSThermoFisher Scientific20012027Wash buffer
Silver Staining kitThermoFisher ScientificLC6100Staining AAV capsid proteins
Sf9 cellsThermoFisher Scientific11496-015Insect cells
Steile waterIn-houseNon-catalog itemFor Akta Avant cleaning
Table top centrifugeThermoFisher Scientific75253839/433607For clarification of Baculovirus supernatant
Tangential Flow Filtration (TFF) cartridgePall CorporationOA100C12TFF cartridge to concentrate the AAV
Tris-HCl, pH 8.0ThermoFisher15568025Alkaline buffer to neutralize the eluted AAV
WAVE Bioreactor System 20/50Cytiva28-9378-00Bioreactor

Odniesienia

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  3. Nathwani, A. C., et al. Adenovirus-associated virus vector-mediated gene transfer in hemophilia B. The New England Journal of Medicine. 365 (25), 2357-2365 (2011).
  4. Wang, D., Tai, P. W. L., Gao, G. Adeno-associated virus vector as a platform for gene therapy delivery. Nature Reviews Drug Discovery. 18 (5), 358-378 (2019).
  5. Mingozzi, F., High, K. A. Immune responses to AAV vectors: overcoming barriers to successful gene therapy. Blood. 122 (1), 23-36 (2013).
  6. Grieger, J. C., Samulski, R. J. Packaging capacity of adeno-associated virus serotypes: impact of larger genomes on infectivity and postentry steps. Journal of Virology. 79 (15), 9933-9944 (2005).
  7. Rabinowitz, J. E., et al. Cross-dressing the virion: the transcapsidation of adeno-associated virus serotypes functionally defines subgroups. Journal of Virology. 78 (9), 4421-4432 (2004).
  8. Nasimuzzaman, M., Lynn, D., vander Loo, J. C. M., Malik, P. Purification of baculovirus vectors using heparin affinity chromatography. Molecular Therapy - Methods & Clinical Development. 3, 16071 (2016).
  9. Nasimuzzaman, M., vander Loo, J. C. M., Malik, P. Production and Purification of Baculovirus for Gene Therapy Application. Journal of Visualized Experiments: JoVE. (134), e57019 (2018).
  10. Sandro, Q., Relizani, K., Benchaouir, R. AAV Production Using Baculovirus Expression Vector System. Methods in Molecular Biology. 1937, 91-99 (2019).
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  14. Chen, H. Intron splicing-mediated expression of AAV Rep and Cap genes and production of AAV vectors in insect cells. Molecular Therapy. 16 (5), 924-930 (2008).
  15. Smith, R. H., Yang, L., Kotin, R. M. Chromatography-based purification of adeno-associated virus. Methods in Molecular Biology. 434, 37-54 (2008).
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  17. Wu, Y., et al. Popularizing recombinant baculovirus-derived OneBac system for laboratory production of all recombinant adeno-associated virus vector serotypes. Current Gene Therapy. 21 (2), 167-176 (2021).
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