The human parvovirus adeno-associated virus (AAV) is unique in its ability to target viral integration to a specific site on chromosome 19 (ch-19). Recombinant AAV (rAAV) vectors retain the ability to integrate but have apparently lost this ability to target. In this report, we characterize the terminal-repeat-mediated integration for wild-type (wt), rAAV, and in vitro systems to gain a better understanding of these differences. Cell lines latent for either wt or rAAV were characterized by a variety of techniques, including PCR, Southern hybridization, and fluorescence in situ hybridization analysis. More than 40 AAV-rAAV integration junctions were cloned, sequenced, and then subjected to comparison and analysis. In both immortalized and normal diploid human cells, wt AAV targeted integration to ch-19. Integrated provirus structures consisted of head-to-tail tandem arrays with the majority of the junction sequences involving the AAV inverted terminal repeats (ITRs). No complete viral ITRs were directly observed. In some examples, the AAV p5 promoter sequence was found to be fused at the virus-cell junction. Data from dot blot analysis of PCR products were consistent with the occurrence of inversions of genomic and/or viral DNA sequences at the wt integration site. Unlike wt provirus junctions, rAAV provirus junctions mapped to a subset of non-ch-19 sequences. Southern analysis supported the integration of proviruses from two independent cell lines at the same locus on ch-2. In addition, provirus terminal repeat sequences existed in both the flip and flop orientations, with microhomology evident at the junctions. In all cases with the exception of the ITRs, the vector integrated intact. rAAV junction sequence data were consistent with the occurrence of genomic rearrangement by deletion and/or rearrangement-translocation at the integration locus. Finally, junctions formed in an in vitro system between several AAV substrates and the ch-19 target site were isolated and characterized. Linear AAV substrates typically utilized the end of the virus DNA substrate as the point of integration, whereas products derived from AAV terminal repeat hairpin structures in the presence or absence of Rep protein resembled AAV-ch-19 junctions generated in vivo. These results describing wt AAV, rAAV, and in vitro integration junctions suggest that the viral integration event itself is mediated by terminal repeat hairpin structures via nonviral cellular recombination pathways, with specificity for ch-19 in vivo requiring additional viral components. These studies should have an important impact on the use of rAAV vectors in human gene therapy.
The use of recombinant viruses for the expression of a wide array of foreign proteins has become commonplace during the last few years. Recently, we have described the construction and characterization of chimeric human immunodeficiency virus type 1 (HIV-1)-poliovirus genomes in which the gag and pol genes of HIV-1 have been substituted for the VP2 and VP3 capsid genes of the P1 capsid precursor region of poliovirus. Transfection of these RNAs into tissue culture cells results in replication of the RNA genome and expression of HIV-1-Pl fusion proteins (
The assembly process of poliovirus occurs via an ordered proteolytic processing of the capsid precursor protein, P1, by the virus-encoded proteinase 3CD. To further delineate this process, we have isolated a recombinant vaccinia virus which expresses, upon infection, the poliovirus P1 capsid precursor polyprotein with an authentic carboxy terminus. Coinfection of HeLa cells with the Pl-expressing vaccinia virus and with a second recombinant vaccinia virus which expresses the poliovirus proteinase 3CD resulted in the correct processing of P1 to yield the three individual capsid proteins VPO, VP3, and VP1. When extracts from coinfected cells were fractionated on sucrose density gradients, the VPO, VP3, and VP1 capsid proteins were immunoprecipitated with type 1 poliovirus antisera from fractions corresponding to a sedimentation consistent for poliovirus 75S procapsids. Examination of these fractions by electron microscopy revealed structures which lacked electron-dense cores and which corresponded in size and shape to those expected for poliovirus empty capsids. We conclude that the expression of the two poliovirus proteins P1 and 3CD in coinfected cells is sufficient for the correct processing of the capsid precursor to VPO, VP3, and VP1 as well as for the assembly of poliovirus empty capsid-like structures.
Poliovirus-based vectors (replicons) have been shown to maintain the in vitro tropism of poliovirus for motor neurons of the CNS. To determine if replicons could be effective for delivery of potentially beneficial proteins to the CNS, we have constructed and characterized a replicon encoding IL-10. IL-10 was rapidly produced in tissue culture cells following in vitro infection with replicons encoding IL-10. Intrathecal inoculation of replicons encoding IL-10 into the non-injured CNS of mice transgenic for the poliovirus receptor resulted in expression of IL-10 within motor neurons at 24-48 h post-inoculation, which subsided by 72-96 h post-inoculation. Single intrathecal or intramuscular injections of replicons were given following spinal cord trauma. Animals receiving replicons encoding IL-10 demonstrated a greater functional recovery in the first 24 h after injury that was maintained throughout the testing period. Compared to animals given replicons encoding gfp, CNS tissue from animals given replicons encoding IL-10 revealed extensive expression of IL-10 from astrocytes around the CNS lesion during the first week following injury. The expression of IL-10 from astrocytes also correlated with more resting microglia as opposed to the rounded activated microglia seen in animals given replicons encoding gfp. Results of these studies establish that replicons can be used to express biologically active molecules in motor neurons of the CNS and these biologically active molecules can have a direct effect on the CNS or induce a cascade of molecules that can influence the cellular composition and activation state of cells within the CNS.
The specificity of poliovirus encapsidation has been studied using a novel chimeric genome in which the gene encoding firefly luciferase has been substituted for the VP2-VP3-VP1 genes of the poliovirus capsid (P1) gene. Transfection of RNA transcribed in vitro from this genome resulted in a VP4-luciferase fusion protein which retained luciferase enzyme activity. Since the detection of enzyme activity was dependent upon replication of the transfected RNA genome, we refer to these genomes as replicons. The replicon encoding luciferase was encapsidated upon transfection of the genomic RNA into cells previously infected with a recombinant vaccinia virus, VV-P1, which encodes the poliovirus type 1 capsid proteins (P1). Infection of cells with each serial passage, followed by analysis of luciferase enzyme activity, revealed that encapsidated replicons could be detected at the first passage with VV-P1. Amplification of the titer of encapsidated replicons occurred upon serial passage with VV-P1, as evidenced by the high expression levels of luciferase enzyme activity following infection. Serial passage of the luciferase replicons with poliovirus type 1, 2, or 3 resulted in the trans encapsidation into the type 1, 2, or 3 capsids, respectively. In contrast, serial passage with bovine enterovirus, Coxsackievirus A21 or B3, or enterovirus 70 did not result in trans encapsidation, even though co-infection of cells with the replicon and different enteroviruses resulted in high-level expression of luciferase. The results of this study highlight the specificity of poliovirus encapsidation and point to the use of encapsidated replicons encoding luciferase as a reagent for dissecting elements of replication and encapsidation.
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