BACKGROUND: Recombinant adeno-associated virus (rAAV) are the most promising vectors for gene therapy. However, large-scale rAAV production remains a challenge for the translation of rAAV-based therapeutic strategies to the clinic. The baculovirus expression vector system (BEVS) has been engineered to produce high rAAV titers in serum-free suspension cultures of insect cells. METHODS: The typical approach of rAAV production in BEVS has been based on a synchronous infection with three baculoviruses at high multiplicity of infection (MOI) [>3 plaque forming units (pfu)/cell]. An alternative approach is to co-infect at low MOI (0.1 pfu/cell). Both strategies (high and low MOI) were compared at a cell density of 1.0 x 10(6) cells/ml in shake-flask experiments. To increase the rAAV titer, a low MOI combined with an initial cell density at infection of 5.0 x 10(6) cells/ml, in fed-batch mode, was evaluated. Subsequently, the production strategy was validated in 3-l bioreactor runs. RESULTS: An increase of 210% in the rAAV titer (4.7 x 10(11) enhanced transduction units/l) was observed when using low MOI, an effect primarily caused by the increase in cell density. The fed-batch approach resulted in a seven-fold increase of rAAV yield. Controlled operations in bioreactor contributed to further increase the rAAV yield (2.8 x 10(14) vector genomes/l) by 25% in comparison to the shake flask results. CONCLUSIONS: This high yield production process using low MOIs and a feeding strategy successfully addresses several limitations of current rAAV production in insect cells and contributes to position the BEVS system as one of the most efficient for large-scale manufacturing of rAAV vectors.
BACKGROUND: Recombinant adeno-associated virus (rAAV) are the most promising vectors for gene therapy. However, large-scale rAAV production remains a challenge for the translation of rAAV-based therapeutic strategies to the clinic. The baculovirus expression vector system (BEVS) has been engineered to produce high rAAV titers in serum-free suspension cultures of insect cells. METHODS: The typical approach of rAAV production in BEVS has been based on a synchronous infection with three baculoviruses at high multiplicity of infection (MOI) [>3 plaque forming units (pfu)/cell]. An alternative approach is to co-infect at low MOI (0.1 pfu/cell). Both strategies (high and low MOI) were compared at a cell density of 1.0 x 10(6) cells/ml in shake-flask experiments. To increase the rAAV titer, a low MOI combined with an initial cell density at infection of 5.0 x 10(6) cells/ml, in fed-batch mode, was evaluated. Subsequently, the production strategy was validated in 3-l bioreactor runs. RESULTS: An increase of 210% in the rAAV titer (4.7 x 10(11) enhanced transduction units/l) was observed when using low MOI, an effect primarily caused by the increase in cell density. The fed-batch approach resulted in a seven-fold increase of rAAV yield. Controlled operations in bioreactor contributed to further increase the rAAV yield (2.8 x 10(14) vector genomes/l) by 25% in comparison to the shake flask results. CONCLUSIONS: This high yield production process using low MOIs and a feeding strategy successfully addresses several limitations of current rAAV production in insect cells and contributes to position the BEVS system as one of the most efficient for large-scale manufacturing of rAAV vectors.
Authors: Stanislav Sokolenko; Steve George; Andreas Wagner; Anup Tuladhar; Jonas M S Andrich; Marc G Aucoin Journal: Biotechnol Adv Date: 2012-01-28 Impact factor: 14.227
Authors: Renuka Rao; Melad Farraha; Grant J Logan; Sindhu Igoor; Cindy Y Kok; James J H Chong; Ian E Alexander; Eddy Kizana Journal: Viruses Date: 2022-07-26 Impact factor: 5.818