Plasmovirus: replication cycle of a novel nonviral/viral vector for gene transfer.

We recently described a novel nonviral/viral vector for gene transfer, the plasmovirus (Noguiez-Hellin P, Robert-le Meur M, Laune S, et al. C R Acad Sci Paris, Sciences de la Vie. 1996;319:45-50; Noguiez-Hellin P, Robert-le Meur M, Salzmann J-L, et al. Proc Natl Acad Sci USA. 1996;93:4175-4180). Plasmoviruses are plasmids capable of expressing all the viral genes required for generating infectious particles and packaging a defective genome containing a transgene. Transfected as plasmids, plasmoviruses transform the transduced cells into packaging cells that release infectious replication-defective retrovirus vectors (RV) containing a transgene, which are capable of infecting nearby cells. We previously showed that such a vector can efficiently "propagate" the transgene after transfection. Here we examine in greater detail the different steps of plasmovirus replication in vitro in human (143 B TK-) and murine (NIH 3T3 TK-) cells. Molecular-biological analysis revealed plasmovirus-coded protein expression starting from 24 hours post-transfection, followed by the detection of infectious RV 48 hours post-transfection. The gag proteins were correctly processed in the released particles. Electron microscopic analysis revealed typical type C particles. Nonintegrated plasmovirus DNA was not toxic for the cells and could be detected for at least 14 days post-transfection. While the transfected gag gene and the transgene could also be detected throughout this period, we observed that env-coded proteins decreased after 72 hours post-transfection. Nevertheless, the production of RV resulted in the propagation of the transgene in the culture, with stable integration of plasmovirus proviral DNA into the host genome of infected cells. We show that this propagation results in a major improvement in therapeutic efficacy using an HSV1-TK transgene and ganciclovir treatment, when compared to that of plasmovirus constructs that cannot propagate. Altogether, these results demonstrate the functionality of this gene transfer method and suggest that improvements in the vector design enhance its efficacy.

Plasmoviruses: nonviral/viral vectors for gene therapy.

We have generated a chimeric gene transfer vector that combines the simplicity of plasmids with the infectivity and long-term expression of retroviruses. We replaced the env gene of a Moloney murine leukemia virus-derived provirus by a foreign gene, generating a plasmid that upon transfer to tumor cells generates noninfectious retroviral particles carrying the transgene. We added to this plasmid an independent expression cassette comprising a cytomegalovirus promoter, an amphotropic retroviral envelope, and a polyadenylylation signal from simian virus 40. These constructs were designed to minimize the risk of recombination generating replication-competent retroviruses. Their only region of homology is a 157-bp sequence with 53% identity. We show that the sole transfection of this plasmid in various cell lines generates infectious but defective retroviral particles capable of efficiently infecting and expressing the transgene. The formation of infectious particles allows the transgene propagation in vitro. Eight days after transfection in vitro, the proportion of cells expressing the transgene is increased by 10-60 times. There was no evidence of replication-competent retrovirus generation in these experiments. The intratumoral injection of this plasmid, but not of the control vector lacking the env gene, led to foci of transgene-expressing cells, suggesting that the transgene had propagated in situ. Altogether, these "plasmoviruses" combine advantages of viral and non-viral vectors. They should be easy to produce in large quantity as clinical grade materials and should allow efficient and safe in situ targeting of tumor cells.

[Generation of a trans-complementable defective recombinant provirus and loading a transgene]. / Génération d'un provirus recombinant défectif complémentable en trans et véhiculant un transgène.

This work was aimed at generating a novel system for gene transfer to tumor cell, combining the advantages of non-viral gene transfer methods with those of transfer by recombinant retroviruses. We replaced the env gene of an infectious Moloney murine leukemia provirus with the gene coding for the thymidine kinase of Herpes Simplex Virus 1 (HSV1-TK). The sole transfection of this construction allows the production of viral particles, and the encapsidation of a viral genome carrying transgene. We show that this gene is expressed at a level sufficient for conferring sensitivity to ganciclovir, a nucleoside analog that is metabolised in a toxic compound by HSV1-TK. We also show that the complementation of this recombinant defective provirus with a gene coding for a retroviral envelope, either expressed constitutively by the transduced cell, or by co-transfection, leads to the formation of infectious viral particles capable of transducing HSV1-TK into tumor cells.