Comparison of the E3 and L3 regions for arming oncolytic adenoviruses to achieve a high level of tumor-specific transgene expression.

Arming oncolytic adenoviral vectors with anticancer transgenes that can be expressed in a tumor-selective manner may enable the engineering of vectors with increased potency, while retaining their safety profile. Armed oncolytic adenoviral vectors were constructed in which transgene expression has been linked via modified splice acceptor sequences that did not necessitate the deletion of any part of the adenoviral genome. Several oncolytic adenoviral vectors were compared in which the transgene was inserted in place of either the E3 or the L3 region. While all vectors had similar viral growth and cytotoxicity characteristics, the highest level of transgene expression was observed from a vector in which the transgene had been inserted downstream of the L3 23K protease gene, the Ad-23K-GM vector. Notably, no transgene expression occurred with this vector in the absence of DNA replication either in vitro or in vivo. In contrast, viruses in which the transgene was inserted into E3 locations exhibited a low level of transgene expression even in the absence of DNA replication. In summary, by utilizing the L3 region for arming oncolytic viruses, higher levels of tumor-specific transgene expression can be obtained without the need to delete any parts of the viral genome.

The N-terminus of the Begomovirus nuclear shuttle protein (BV1) determines virulence or avirulence in Phaseolus vulgaris.

The BV1 gene of the bipartite Begomovirus genome encodes a nuclear shuttle protein (NSP) that is also an avirulence determinant in common bean. The function of the NSP of two common bean-infecting bipartite begomoviruses, Bean dwarf mosaic virus (BDMV) and Bean golden yellow mosaic virus (BGYMV), was investigated using a series of hybrid DNA-B components expressing chimeric BDMV and BGYMV NSP, and genotypes of the two major common bean gene pools: Andean (cv. Topcrop) and Middle American (cvs. Alpine and UI 114). BDMV DNA-A coinoculated with HBDBG4 (BDMV DNA-B expressing the BGYMV NSP) and HBDBG9 (BDMV DNA-B expressing a chimeric NSP with the N-terminal 1 to 42 amino acids from BGYMV) overcame the BDMV resistance of UI 114. This established that the BDMV NSP is an avirulence determinant in UI 114, and mapped the domain involved in this response to the N-terminus, which is a variable surface-exposed region. BDMV DNA-A coinoculated with HBDBG10, expressing a chimeric NSP with amino acids 43 to 92 from BGYMV, was not infectious, revealing an essential virus-specific domain. In the BGYMV background, the BDMV NSP was a virulence factor in the Andean cv. Topcrop, whereas it was an avirulence factor in the Middle American cultivars, particularly in the absence of the BGYMV NSP. The capsid protein (CP) also played a gene pool-specific role in viral infectivity; it was dispensable for infectivity in the Andean cv. Topcrop, but was required for infectivity of BDMV, BGYMV, and certain hybrid viruses in the Middle American cultivars. Redundancy of the CP and NSP, which are nuclear proteins involved directly or indirectly in viral movement, provides a masking effect that may allow the virus to avoid host defense responses.

Intravenous administration of an AAV-2 vector for the expression of factor IX in mice and a dog model of hemophilia B.

Previous experiments have demonstrated the stable expression of factor IX (FIX) protein in mice and canine models of hemophilia B following portal vein gene transfer with a recombinant adeno-associated virus (rAAV) vector encoding FIX. Here, we present the results of studies that further optimized the rAAV vector transgene cassette used to express FIX and explored the use of the less-invasive intravenous (i.v.) route of vector administration for the treatment of hemophilia B. First, a liver-specific promoter was evaluated in conjunction with cis-acting regulatory elements in mice. Constructs that included both the beta-globin intron and the woodchuck hepatitis virus post-transcriptional regulatory element resulted in the highest level of FIX expression in vivo. Using this optimized vector, we demonstrate that i.v. injection was feasible for hepatic gene transfer in mice, achieving 70-80% of portal vein expression levels of FIX. In further studies using the Chapel Hill strain of hemophilia B dogs, we demonstrate for the first time FIX expression and partial correction of the bleeding disorder following i.v. administration of an AAV vector.