Experimental treatment of ovarian cancers by adenovirus vectors combining receptor targeting and selective expression of tumor necrosis factor.

Ovarian cancer is the fourth most common cancer among women and existing treatment is not routinely curative. One new strategy for cancer therapy is the selective delivery of TNFalpha to tumors via adenovirus vectors. We have tested the combination of two modifications to adenovirus vectors designed to limit delivery to tumors, capsid modification and expression control. To target alpha(v)beta(3/5) integrin receptors that are highly expressed in tumor and sparsely expressed in the epithelial layer of peritoneum, we modified the capsid fiber and penton base to remove native receptor binding and incorporated an RGD-4C motif in the fiber knob (Ad.PB*F*RGD). This vector exhibits effective gene transfer in all of the alpha(v)beta(3/5)-positive ovarian cancer cells tested in vitro and in vivo. Importantly, the Ad.PB*F*RGD vector is able to transduce ovarian tumor nodules and avoid infecting the normal mesothelial cells that line the intraperitoneal space following intraperitoneal administration. To further increase selectivity, different promoters were incorporated into the capsid-modified vector to confer the expression of the hTNFalpha therapeutic gene. We analyzed both constitutive (CMV or RSV) and potentially tumor selective promoters (MUC-1, E2F or hTERT) in terms of efficacy, selectivity and safety. TNF-expressing Ad.PB*F*RGD vectors containing the MUC-1 promoter showed anti-tumor activity in two ovarian cancer xenograft models (Caov3 and Igr-ov1) with little evidence of toxicity or systemic TNF. The data indicate that combination of capsid modification and transcriptional regulation of expression is a promising strategy for development of a new ovarian cancer treatment.

Binding of adenoviral fiber knob to the coxsackievirus-adenovirus receptor is crucial for transduction of fetal muscle.

Adenoviral (Ad) infection involves attachment mediated by the Ad fiber protein binding to the coxsackievirus-adenovirus receptor (CAR) of a target cell and internalization facilitated by the interaction of the Ad penton base protein with alpha(v) integrins. To understand the relative importance of the Ad binding and internalization steps for the transduction of fetal skeletal muscle, we used a panel of genetically modified vectors that specifically ablate the fiber-CAR interaction (AdL.F*), the penton base-alpha(v) integrin interaction (AdL.PB*), or both (AdL.PB*F*) to transduce embryonic day 16 (E-16) mouse muscle in vivo and primary E-16 muscle cells in vitro. Quantification of transgene expression and vector genome copies revealed a striking absence of E-16 muscle transduction by AdL.F* and AdL.PB*F*. In contrast, fetal muscle transduction with AdL.PB* was not significantly different than with the unmodified vector. Similar results were observed with in vitro Ad infection studies in primary E-16 muscle cells. From these data we conclude that the fiber-CAR interaction is important for the transduction of fetal muscle by Ad vectors. The high dependence on fiber-CAR binding will impact the development of strategies for Ad vector retargeting to achieve muscle-specific transduction in utero.

Advances towards targetable adenovirus vectors for gene therapy.

Adenovirus-based vectors can efficiently transfer therapeutic genes into cells through an entry process that is initiated be binding to specific receptors on the cell surface. The receptors for the most commonly used Ad vectors include both the Coxsackie and adenovirus receptor (CAR) and omega-integrins. Therapeutic applications of AD vectors could be expanded if the specificity of gene transfer could be modulated to enhance expression of a therapeutic gene in transfer tissues and avoid non-target tissues. Ad vectors have been successfully retargeted to novel receptors using several approaches. The merits and challenges of specific approaches are discussed. In vivo evaluation of these retargeted Ad vectors has given promising results but has also highlighted additional challenges for achieving efficient targeted gene delivery. Additional modifications beyond those affecting interaction with the native receptors, CAR and integrins may be required both to avoid the clearance mechanisms that effectively remove circulating vector following systemic administration and to avoid gene transfer in non-target tissues such as the liver. Developing Ad vector that address these issues and can be targeted to novel receptors would enable gene delivery at the site of disease in applications that are currently not feasible.

Ablating CAR and integrin binding in adenovirus vectors reduces nontarget organ transduction and permits sustained bloodstream persistence following intraperitoneal administration.

To create tumor-targeted Ad vectors, ablation of native CAR and integrin receptor binding is crucial to enhance the specificity of tumor transduction. Toward this aim, we have previously created base vectors in which binding to CAR (single-ablated) or to both CAR and integrins (double-ablated) has been ablated. In this study, the biodistribution of the conventional (CAR and integrin binding intact), single-ablated, and double-ablated vectors was evaluated following intraperitoneal administration. The mesothelial lining of the peritoneal organs was the principle site of CAR-dependent gene transfer by the conventional vector. Surprisingly, the single-ablated vector strongly transduced the liver parenchyma rather than the mesothelium, while the double-ablated vector did not significantly transduce the parenchyma or mesothelium. The high level of parenchymal transduction by the single-ablated vector suggested that it efficiently entered the bloodstream from the peritoneal cavity. Consistent with this hypothesis, a large proportion of active particles distributed and persisted in the bloodstream following intraperitoneal administration of either the single- or the double-ablated vector. The above results suggest that the double-ablated vector backbone may not only significantly improve targeting to cancers located in the peritoneal cavity, but may also significantly improve targeting to metastatic tumors located throughout the body by virtue of its enhanced bloodstream persistence.