Knockout of the NEU2 gene in Vero cells resulted in an approximately 18-fold increase in Rotarix rotavirus replication compared to wild-type cells, offering a means to improve vaccine manufacturing.
Does silencing specific host genes enhance rotavirus replication in vaccine cell lines?
Silencing specific host genes, such as NEU2, in Vero cell lines significantly enhances rotavirus replication, offering a method to improve the manufacturing efficiency of rotavirus vaccines.
Estimación del efecto: ~18-fold increase
Tasa de eventos absoluta: 18% vs 1%
Rotavirus is a major cause of severe gastroenteritis among very young children. In developing countries, rotavirus is the major cause of mortality in children under five years old, causing up to 20% of all childhood deaths in countries with high diarrheal disease burden, with more than 90% of these deaths occurring in Africa and Asia. Rotavirus vaccination mimics the first infection without causing illness, thus inducing strong and broad heterotypic immunity against prospective rotavirus infections. Two live vaccines are available, Rotarix and RotaTeq, but vaccination efforts are hampered by high production costs. Here, we present a dataset containing a genome-wide RNA interference (RNAi) screen that identified silencing events that enhanced rotavirus replication. Evaluated against several rotavirus vaccine strains, hits were validated in a Vero vaccine cell line as well as CRISPR/Cas9 generated cells permanently and stably lacking the genes that affect RV replication. Knockout cells were dramatically more permissive to RV replication and permitted an increase in rotavirus replication. These data show a means to improve manufacturing of rotavirus vaccine.
Wu et al. (Wed,) conducted a other in Rotavirus vaccine production. NEU2 gene knockout vs. Wild-type Vero cells was evaluated on Rotavirus replication (viral transcript fold-increase) (~18-fold increase). Knockout of the NEU2 gene in Vero cells resulted in an approximately 18-fold increase in Rotarix rotavirus replication compared to wild-type cells, offering a means to improve vaccine manufacturing.