We established a method for production of recombinant adeno-associated virus type 5 (rAAV5) in insect cells by use of baculovirus expression vectors. One baculovirus harbors a transgene between the inverted terminal repeat sequences of type 5, and the second expresses Rep78 and Rep52. Interestingly, the replacement of type 5 Rep52 with type 1 Rep52 generated four times more rAAV5 particles. We replaced the N-terminal portion of type 5 VP1 with the equivalent portion of type 2 to generate infectious AAV5 particles. The rAAV5 with the modified VP1 required ␣2-3 sialic acid for transduction, as revealed by a competition experiment with an analog of ␣2-3 sialic acid. rAAV5-GFP/Neo with a 4.4-kb vector genome produced in HEK293 cells or Sf9 cells transduced COS cells with similar efficiencies. Surprisingly, Sf9-produced humanized Renilla green fluorescent protein (hGFP) vector with a 2.4-kb vector genome induced stronger GFP expression than the 293-produced one. Transduction of murine skeletal muscles with Sf9-generated rAAV5 with a 3.4-kb vector genome carrying a human secreted alkaline phosphatase (SEAP) expression cassette induced levels of SEAP more than 30 times higher than those for 293-produced vector 1 week after injection. Analysis of virion DNA revealed that in addition to a 2.4-or 3.4-kb single-stranded vector genome, Sf9-rAAV5 had more-abundant forms of approximately 4.7 kb, which appeared to correspond to the monomer duplex form of hGFP vector or truncated monomer duplex SEAP vector DNA. These results indicated that rAAV5 can be generated in insect cells, although the difference in incorporated virion DNA may induce different expression patterns of the transgene.
Production of recombinant adeno-associated virus (rAAV) results in substantial quantities of empty capsids or virus-like particles (VLPs), virus protein shells without the vector genome. The contaminating VLPs would interfere with transduction by competing for cell-surface receptors and, when administered in vivo, contribute to antigen load, which may elicit a stronger immune response. Density-gradient ultracentrifugation provides a means to separate VLPs from rAAV particles, but is not feasible for large-scale preparations of vectors. Since the compositions of the VLP and vector differ by the single-stranded DNA genome, we hypothesized that the isoelectric point of the vector may differ from that of the VLP. In an attempt to separate type 1 rAAV particles from VLPs by ion-exchange chromatography, we tested a number of buffer systems and found that trimethylammonium sulfate, or [(CH3)4N]2SO4, effectively separated rAAV1 particles from VLPs. The rAAV1-GFP chromatographically separated from VLPs induced stronger GFP expression in HEK293 cells than rAAV1-GFP contaminated with VLPs. The transduction of mouse muscles with rAAV1-SEAP (secreted form of alkaline phosphatase) isolated from VLPs also showed higher serum SEAP levels than rAAV1-SEAP with VLPs. These results suggest that chromatographic separation of rAAV1 from empty capsids increased the efficacy of rAAV1.
Juvenile hormone epoxide hydrolases (JHEHs) are a family of enzymes that hydrolyze juvenile hormones (JHs). They are important in terms of organ-specific regulation and irreversible degradation. In contrast to three JHEH genes (jheh) in Drosophila melanogaster and five jheh in Tribolium castaneum, only one jheh gene has been reported to date in lepidopteran insects. By searching a genome database of the silkworm, KAIKOBLAST, five JHEH-related genes (jheh-r), in addition to Bmjheh, were found. Developmental changes in mRNA expression were brought about revealing several unique patterns for each of jheh-r as to developmental stages and organ-specificity. Recombinant proteins of JHEH-r were expressed using a baculovirus system to evaluate their enzymatic activities. Three of the five JHEH-r recombinant proteins had JH hydrolytic activities. This is the first report on lepidopteran jheh-related genes and also provides the comprehensive analysis of multiple jheh-related genes in an insect species with respect to their functions in enzyme activities.
Juvenile hormone epoxide hydrolases (JHEHs) degrade juvenile hormones (JHs) and are important for JH titre regulation. Here, we report the cloning and analysis of five jheh-related (jheh-r1-r5) genes in the red flour beetle, Tribolium castaneum, a model species for the coleopteran insects. T. castaneum JHEH-r (TcJHEH-r) proteins show high homology to lepidopteran JHEHs and also to human microsomal epoxide hydrolase. In the phylogenetic tree, Tcjheh-rs were clustered, and interestingly, they were also clustered in the genome. Examination of enzymatic activities using recombinant TcJHEH-r proteins showed that TcJHEH-r3 had strong degradation activity for JH III, whereas TcJHEH-r4 had weak activity. The study has yielded significant information that will facilitate further analysis of JHEHs and epoxide hydrolases.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.