Abstract
The supercoiled circular (SC) topology form of plasmid DNA has been regarded to be advantageous over open circular or linearized analogue in transfection and expression efficiency, and therefore are largely demanded in the biopharmaceutical manufacturing. However, production of high-purity SC plasmid DNA would result in high manufacturing cost. The effect of SC proportion in plasmid DNA on the quality of packaged lentiviral vectors has never been reported. In this study, we established an efficient system for production of high-titer lentiviral vectors using suspension HEK293SF cells in serum-free media, and the lentiviral titer was not associated with the proportion of SC plasmid DNA. Plasmids DNA with different proportion of SC, open-circular, and linearized forms were prepared using the thermal denaturation method, and were transfected to adherent HEK293T or suspension HEK293SF cells for packaging of lentiviral vectors. The titer of lentiviral vectors from HEK293T cells, but not from HEK293SF cells, was significantly impaired when the proportion of SC plasmid DNA decreased from 60–80% to 30–40%. Further decrease of SC plasmid proportion to 3% led to a dramatic reduction of lentiviral titer no matter the packaging cell line was. However, lentiviral vectors from HEK293SF cells still showed a high titer even when the proportion of SC plasmid DNA was 3%. This study demonstrated that extremely high proportion of SC plasmid DNA was not required for packaging of high-titer lentiviral vector in HEK293SF cells, at least under our manufacturing process.
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Acknowledgements
This work was supported by the Beijing Municipal Science & Technology Commission (Nos. Z171100001017098, Z181100006218036, Z181100002218040, Z191100001119097), the Scientific Research Foundation for Capital Medicine Development (No. 2018-2-4084), the Peking University Clinical Scientist Program (No. BMU2019LCKXJ003), the Clinical Medicine Plus X-Young Scholars Project of Peking University (No. PKU2020LCXQ015), Peking University People’s Hospital Research and Development Funds (No. RDX2019-14), the Zhongguancun Science Park Management Committee (No. 201805028-1), and the Fundamental Research Funds for the Central Universities in China.
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Lu, XA., He, T., Han, Z. et al. Production of lentiviral vectors in suspension cells using low proportion of supercoiled circular plasmid DNA. Cytotechnology 72, 897–905 (2020). https://doi.org/10.1007/s10616-020-00433-4
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DOI: https://doi.org/10.1007/s10616-020-00433-4