Modulation of renal glomerular disease using remote delivery of adenoviral-encoded solubletype II TGF-beta receptor fusion molecule.

BACKGROUND: Systemic adenoviral (Ad) gene therapy for renal disorders is largely hampered by the unique architecture of the kidney. Consequently, currently available Ad vectors are of only limited therapeutic utility in the context of glomerular and fibroproliferative renal diseases. METHODS: The Ad vectors studied in the context of blocking renal fibrosis were AdTbeta-ExR and AdCATbeta-TR. AdTbeta-ExR encodes a chimeric soluble molecule comprising the entire ectodomain of the human type II TGF-beta receptor, genetically fused to the Fc fragment of the human IgG1 (sTbetaRII), while AdCATbeta-TR encodes only the dominant-negative truncated ectodomain of the human type II TGF-beta receptor. The biologic activity of the type II TGF-beta receptor was evaluated in vitro by its ability to inhibit cellular proliferation and in vivo in a unilateral ureter obstruction fibrosis model. Renal targeting with sTbetaRII was evaluated immunohistochemically after intramuscular (IM) delivery of AdTbeta-ExR. The renal antifibrotic effect of the Ad vectors was evaluated in a lupus murine model with both light and electron microscopy and urinalysis. RESULTS: sTbetaRII was detected in the glomeruli after remote IM injection of AdTbeta-ExR, but not the control AdCATbeta-TR, indicating renal deposition of the heterologous soluble fusion protein after its expression in the muscle and secretion into the circulation. AdTbeta-ExR, but not AdCATbeta-TR, could transiently inhibit mesangial expansion, glomerular hypercellularity, proteinuria and cortical interstitial fibrosis in a murine lupus model. However, the autoimmune renal disease eventually surpassed the antifibrotic effect. CONCLUSIONS: These results indicate the superiority of a soluble type II TGF-beta receptor over a dominant-negative, non-soluble type II TGF-beta receptor in the context of blocking renal fibrosis in murine models.

A model system for the design of armed replicating adenoviruses using p53 as a candidate transgene.

Cancer gene therapy endeavors to overcome the low therapeutic index of currently available therapeutic modalities via the efficient and safe delivery of genetic material into tumor cells. However, despite promising preclinical results, replication-deficient viral vectors have demonstrated a limited efficacy in the clinical setting. To increase vector efficiency, replication-competent viruses have been proposed. Clinical trials have shown the safety of locally injected, conditionally replicative adenoviruses (Ads) but have underscored the need for improved potency. To further increase the therapeutic effect of replicating viral vectors, armed therapeutic viruses (ATVs) have recently been used for high-efficiency transgene expression. However, interference with cellular signaling and viral production by constitutive transgene expression may be counterproductive for ATV replication, thereby hindering the therapeutic outcome. Consequently, studies are equivocal with regard to the potential benefits of ATVs. To address this issue, we hypothesized that induction of replication of an Ad expressing p53 may be a useful strategy in the context of ATV because p53 does not interfere with Ad replication and may even increase its cytolytic effect. We show that in our in vitro ATV model system, E1 transcomplementation of a replication-deficient Ad encoding p53 resulted in dramatic augmentation of cell killing and circumvented resistance to apoptosis. Correlation was found between the degrees of cell killing and apoptosis induction, rather than with viral burst. Furthermore, both Ad5 E1B 55kDa and E4 orf6 genes were required to enhance the cell killing. In conclusion, our p53-ATV model system demonstrates the potential utility of therapeutic transgene expression by a replicating Ad after a rational selection of a candidate transgene.

Adenoviral gene therapy for renal cancer requires retargeting to alternative cellular receptors.

Metastatic renal cell carcinoma (RCC) is one of the most treatment-resistant malignancies in humans. Therefore, the identification of new agents with better antitumor activity merits a high priority in the treatment of advanced RCC. In this regard, gene therapy with adenoviral (Ad) vectors is a promising new modality for cancer. However, a primary limiting factor for the use of Ad vectors for cancer gene therapy is their critical dependence on cellular expression of the primary Ad receptor, the coxsackie and adenovirus receptor (CAR), known to be down-regulated in many cancer types. Following the identification of CAR deficiency in RCC lines, we have found abundant membrane expression of alpha(v)beta 3 and alpha(v)beta 5 integrins and of the putative receptor to Ad serotype 3 (Ad3). As an alternative gene therapy approach for RCC that would circumvent CAR deficiency, we employed retargeting of replication-incompetent Ad vectors and replication-competent Ad viruses to alpha(v)beta 3 and alpha(v)beta 5 integrins and to the putative Ad3 receptor. These strategies to genetically alter Ad tropism were based on either the insertion of a cysteine-aspartate-cysteine-arginine-glycine-aspartate-cysteine-phenylalanine-cysteine (RGD) motif into the HI loop of the Ad fiber knob domain or on generation of a chimeric Ad fiber composed of adenovirus serotype 5 shaft/Ad3 knob. Both strategies proved highly efficient to circumvent CAR deficiency and enhance gene delivery into RCC cells. Furthermore, in the context of replication-competent Ad, tropism alteration resulted in distinct capacity of the retargeted viruses to infect, replicate, and lyse RCC models in vitro and in vivo. The retargeting strategies were particularly beneficial in the context of replication-competent Ad. These findings underscore the importance of CAR-independent cellular entry mechanisms in RCC and are highly consequential for the development of viral antitumor agents for RCC and other CAR-negative tumors.