Amino-terminal fragment of urokinase inhibits tumor cell invasion in vitro and in vivo: respective contribution of the urokinase plasminogen activator receptor-dependent or -independent pathway.

The urokinase plasminogen activator (uPA) is implicated in both cancer cell invasion and angiogenesis. It can interact with a specific receptor (uPAR) via the epidermal growth factor (EGF)-like domain in the urokinase amino-terminal fragment (ATF) in a species-specific manner. Our previous studies showed that adenovirusmediated delivery of murine ATF (AdmATF) suppressed human tumor growth in mouse models, by inhibiting murine angiogenesis. However, we cannot exclude its putative inhibitory action on human cancer cell invasion through a uPAR-independent pathway. To further investigate the mechanisms of ATF, we constructed another adenovirus, AdhmATF, expressing humanized murine ATF (hmATF). hmATF binds to human uPAR but not to murine uPAR. We compared the antagonist effect of both AdmATF and AdhmATF on human and murine cancer cells. In vitro, the supernatant from AdhmATF-infected cells repressed 79% of membrane-associated uPA activity on human MDA-MB-231 cells, whereas that from AdmATF-infected cells repressed 35% of membrane-associated uPA activity. On murine LLC cells, the supernatant from AdhmATF-infected cells inhibited 29% of cell surface uPA activity, whereas that from AdmATF-infected cells inhibited 74% of cell surface uPA activity. Similar results were obtained in a cell invasion assay. In vivo, intratumoral injection of the adenoviruses into LLC tumors on day 24 postinjection induced lower but significant tumor growth suppression by AdhmATF (tumor volume was 1185 +/- 128 mm3), whereas suppression by AdmATF was greater (407 +/- 147 mm3). In the MDA-MB-231 tumor model, on day 52 postinjection, tumor size was 187 +/- 47 mm3 in the AdhmATF-treated group and 468 +/- 65 mm3 in the AdmATF-treated group. The LLC and MDA-MB- 231 cell lines transfected by mATF or hmATF genes showed growth inhibition In vivo equivalent to the results obtained by adenovirus treatment. These results demonstrate the strong anticancer activity of ATF even when its uPAR-binding affinity has been suppressed, and indicate that ATF exerts an antitumor effect via dual mechanisms: essentially through targeting the uPA-uPAR system via the EGF-like domain and partially through targeting a uPAR-independent interaction via the kringle domain.

Transposition of the thyroid iodide uptake and organification system in nonthyroid tumor cells by adenoviral vector-mediated gene transfers.

Radioactive iodine (131I) is routinely used for the treatment of differentiated thyroid cancers. Attempts have been made to enlarge this therapeutic strategy to nonthyroid tumors by coupling radioactive iodide administration with transfer of the sodium iodide symporter (NIS) gene into target cells, for example with an adenoviral vector (AdNIS). Although efficient iodide uptake was achieved in the tumors treated with AdNIS, no therapeutic effect could be observed with 131I, most probably because the iodide retention time in the target cells was short. To circumvent this problem, we propose to organify the iodide taken up, as it occurs in the thyroid. We constructed a recombinant adenovirus encoding the human thyroperoxidase (TPO) gene under the control of the cytomegalovirus early promoter (AdTPO). Infection of nonthyroid tumor cells with this virus led to production of an enzymatically active protein. A significant increase in iodide organification could be observed in cells coinfected with both AdNIS and AdTPO in the presence of exogenous hydrogen peroxide. However, the levels of iodide organification obtained were too low to significantly increase the iodide retention time in the target cells.

Simultaneous CAR- and alpha V integrin-binding ablation fails to reduce Ad5 liver tropism.

Targeting adenovirus encoding therapeutic genes to specific cell types has become a major goal in gene therapy. Coxsackievirus and adenovirus receptor (CAR) and alpha(V) integrins have been identified as the primary cell surface components that interact with adenovirus type 5 (Ad5)-based vectors during in vitro transduction. Redirecting Ad5-based vectors requires abrogation of the natural interaction between the viral capsid and its cellular receptors and simultaneous introduction of a new binding specificity into the viral capsid. To abrogate native Ad5 tropism, fiber knob mutations Pro409Glu and Lys417Ala were each incorporated into adenoviral vectors, while the RGD motif was deleted from the penton base. In vitro transduction experiments showed that these capsid mutations eliminated Ad5 interactions with CAR and alpha(V) integrins. Moreover, incorporation in the fiber HI loop of a vitronectin-derived ligand (VN4) specific for the uPAR/CD87 receptor provided the Lys417Ala virus with an alternative entry pathway specific for uPAR-expressing cells, indicating a successful in vitro retargeting of the vector. Unexpectedly, however, simultaneous disruption of Ad5 binding to CAR and alpha(V) integrins had no effect on liver gene transfer following systemic administration in mice. This study highlights the need to understand better the molecular determinants involved in adenovirus uptake by the liver to control the fate of adenoviral vectors in vivo.

A novel method using baculovirus-mediated gene transfer for production of recombinant adeno-associated virus vectors.

The baculovirus Autographa californica multiple nucleopolyhedrosis virus causes non-productive infection in mammalian cells. Recombinant baculovirus therefore has the capability to transfer and express heterologous genes in these cells if a mammalian promoter governs the gene of interest. We have investigated the possibility of using baculovirus as a tool to produce recombinant adeno-associated virus (rAAV). AAV has become increasingly popular as a vector for gene therapy and functional genomics efforts, although its use is hampered by the lack of a simple and efficient vector production method. We show here that co-infection of mammalian producer cells with three viruses - a baculovirus containing the reporter gene flanked by AAV ITRs, a baculovirus expressing the AAV rep gene and a helper adenovirus expressing the AAV cap gene - produces infectious rAAV particles. This baculovirus-based chimeric vector method may in future improve large-scale rAAV vector preparations and circumvent present-day problems associated with rAAV production.