TY - JOUR
T1 - Efficient FLPe recombinase enables scalable production of helper-dependent adenoviral vectors with negligible helper-virus contamination
AU - Umaña, Pablo
AU - Gerdes, Christian A.
AU - Stone, Daniel
AU - Davis, Julian R E
AU - Ward, Daniel
AU - Castro, Maria G.
AU - Lowenstein, Pedro R.
PY - 2001
Y1 - 2001
N2 - Helper-dependent (HD), high-capacity adenoviruses are one of the most efficient and safe gene therapy vectors, capable of mediating long-term expression1-12. Currently, the most widely used system for HD vector production avoids significant contamination with helper virus by using producer cells stably expressing a nuclear-targeted Cre recombinase and an engineered first-generation helper virus with parallel loxP sites flanking its packaging signal1,3-12. The system requires a final, density-based separation of HD and residual helper viruses by ultracentrifugation to reduce contaminating helper virus to low levels. This separation step hinders large-scale production of clinical-grade HD virus13. By using a very efficient recombinase, in vitro-evolved FLPe (ref. 14), to excise the helper virus packaging signal in the producer cells, we have developed a scalable HD vector production method. FLP has previously been shown to mediate maximum levels of excision close to 100% compared to 80% for Cre (ref. 15). Utilizing a common HD plasmid backbone1,7,8,10-12, the FLPe-based system reproducibly yielded HD virus with the same low levels of helper virus contamination before any density-based separation by ultracentrifugation. This should allow large-scale production of HD vectors using column chromatography-based virus purification13.
AB - Helper-dependent (HD), high-capacity adenoviruses are one of the most efficient and safe gene therapy vectors, capable of mediating long-term expression1-12. Currently, the most widely used system for HD vector production avoids significant contamination with helper virus by using producer cells stably expressing a nuclear-targeted Cre recombinase and an engineered first-generation helper virus with parallel loxP sites flanking its packaging signal1,3-12. The system requires a final, density-based separation of HD and residual helper viruses by ultracentrifugation to reduce contaminating helper virus to low levels. This separation step hinders large-scale production of clinical-grade HD virus13. By using a very efficient recombinase, in vitro-evolved FLPe (ref. 14), to excise the helper virus packaging signal in the producer cells, we have developed a scalable HD vector production method. FLP has previously been shown to mediate maximum levels of excision close to 100% compared to 80% for Cre (ref. 15). Utilizing a common HD plasmid backbone1,7,8,10-12, the FLPe-based system reproducibly yielded HD virus with the same low levels of helper virus contamination before any density-based separation by ultracentrifugation. This should allow large-scale production of HD vectors using column chromatography-based virus purification13.
U2 - 10.1038/89349
DO - 10.1038/89349
M3 - Article
SN - 1546-1696
VL - 19
SP - 582
EP - 585
JO - Nature biotechnology
JF - Nature biotechnology
IS - 6
ER -