BACKGROUND: Although lentiviral transduction methods are widely used, their broader application is dependent upon the optimization of lentiviral transduction efficiency for a broad range of cell types. In the present study, we focus on the evaluation of two chemical classes with respect to their ability to increase lentiviral transduction without cytotoxicity. METHODS: We compared the activity of adjuvants that are already used for lentivirus delivery with that of novel adjuvants selected on the basis of their chemical and physical characteristics. RESULTS: The novel poloxamer synperonic F108 demonstrated superior characteristics for enhancing lentiviral transduction over the best-in-class polybrene-assisted transduction. The results revealed that poloxamer synperonic F108 exhibited the dual benefits of low toxicity and a high efficiency of lentiviral gene delivery into a range of different primary cell cultures. In the presence of poloxamer synperonic F108, cells showed an increased propidium dye influx indicating a re-organization of membrane microstructures accompanying lentivirus uptake. The administration of a mixture of poloxamer synperonic F108 with polybrene further enhanced lentiviral transduction rates. CONCLUSIONS: The results obtained in the present study indicate that a contribution to efficiency is made by each adjuvant, with polybrene acting as a charge protector and poloxamer synperonic F108 as a membrane modulator. Therefore, poloxamer synperonic F108, either alone or in combination, can lead to the optimization of large-scale lentiviral transduction approaches.
BACKGROUND: Although lentiviral transduction methods are widely used, their broader application is dependent upon the optimization of lentiviral transduction efficiency for a broad range of cell types. In the present study, we focus on the evaluation of two chemical classes with respect to their ability to increase lentiviral transduction without cytotoxicity. METHODS: We compared the activity of adjuvants that are already used for lentivirus delivery with that of novel adjuvants selected on the basis of their chemical and physical characteristics. RESULTS: The novel poloxamer synperonic F108 demonstrated superior characteristics for enhancing lentiviral transduction over the best-in-class polybrene-assisted transduction. The results revealed that poloxamer synperonic F108 exhibited the dual benefits of low toxicity and a high efficiency of lentiviral gene delivery into a range of different primary cell cultures. In the presence of poloxamer synperonic F108, cells showed an increased propidium dye influx indicating a re-organization of membrane microstructures accompanying lentivirus uptake. The administration of a mixture of poloxamer synperonic F108 with polybrene further enhanced lentiviral transduction rates. CONCLUSIONS: The results obtained in the present study indicate that a contribution to efficiency is made by each adjuvant, with polybrene acting as a charge protector and poloxamer synperonic F108 as a membrane modulator. Therefore, poloxamer synperonic F108, either alone or in combination, can lead to the optimization of large-scale lentiviral transduction approaches.
Authors: Yogindra Vedvyas; Enda Shevlin; Marjan Zaman; Irene M Min; Alejandro Amor-Coarasa; Spencer Park; Susan Park; Keon-Woo Kwon; Turner Smith; Yonghua Luo; Dohyun Kim; Young Kim; Benedict Law; Richard Ting; John Babich; Moonsoo M Jin Journal: JCI Insight Date: 2016-11-17
Authors: Nataša Anastasov; Ines Höfig; Vanja Radulović; Simon Ströbel; Michael Salomon; Jan Lichtenberg; Ina Rothenaigner; Kamyar Hadian; Jens M Kelm; Christian Thirion; Michael J Atkinson Journal: BMC Cancer Date: 2015-06-10 Impact factor: 4.430
Authors: Lewis L Brayshaw; Carlos Martinez-Fleites; Takis Athanasopoulos; Thomas Southgate; Laurent Jespers; Christopher Herring Journal: RSC Med Chem Date: 2020-12-24