Enhanced transduction of fibroblasts in transplanted kidney with an adenovirus having an RGD motif in the HI loop.

Application of gene therapy to the renal graft has a powerful potential to improve the outcome of kidney transplantation and eliminate detrimental side effects associated with systemic therapy, through local expression of immunoregulatory or other protective molecules. However, the search for the optimal vector is still ongoing. In this study, we used a modified adenovirus that has an Arg-Gly-Asp (RGD) motif inserted in the HI loop of the fiber knob, as a successful strategy to transduce the renal graft. Donor Lewis rat kidneys were infused via the renal artery with a solution containing either a fiber-modified adenovirus (AdTL-RGD) or an unmodified adenovirus (AdTL), or with saline. Syngeneic recipients were killed after 3, 7 or 14 days. Efficiency, selectivity, localization, time course of gene expression and side effects were studied using biochemical and immunohistological techniques. Enhanced gene expression was achieved selectively in the transplanted kidney by AdTL-RGD, when compared to AdTL. Transgene expression lasted for at least 2 weeks. With the AdTL-RGD vector, the transgene was abundantly expressed in the renal interstitial fibroblasts. An increase in the number of cytotoxic T lymphocytes accompanied the use of either vector, when compared to saline. These data convincingly show enhanced and selective gene transfer to the fibroblasts of transplanted kidneys using an RGD-modified adenovirus, providing a highly efficient vector system for future therapeutic interventions.

Chronic blockade of angiotensin II action prevents glomerulosclerosis, but induces graft vasculopathy in experimental kidney transplantation.

Long-term renin-angiotensin system blockade is beneficial in a variety of renal diseases. This study examines the long-term (34 weeks) effects of the angiotensin-converting enzyme inhibitor lisinopril and the angiotensin II receptor type I blocker L158,809 in the Fisher to Lewis rat model of chronic renal transplant failure. Treatment in allografted rats with lisinopril or L158,809 was initiated 10 days after transplantation, or at the time when proteinuria exceeded 50 mg/24 h. Untreated allografts and syngrafts served as controls. In contrast to syngrafts, untreated allografts developed proteinuria, hypercholesterolaemia, interstitial damage, and glomerulosclerosis. Lisinopril or L158,809 treatment in allografts starting at day 10 after transplantation completely prevented this, with the exception of interstitial damage, but this treatment also caused a reduction in blood pressure and renal function. Moreover, the intimal surface area of the renal arteries was dramatically increased in allografts treated with either lisinopril or L158,809 compared with untreated allografted rats. Treatment once proteinuria had developed was less effective in preventing glomerulosclerosis, but also caused less intimal expansion. Thus, chronic renin-angiotensin system blockade preserves glomerular morphology in the absence of proteinuria, but enhances intimal hyperplasia and reduces renal function in experimental transplantation. In view of these results, it should be questioned whether such treatment benefits renal transplant patients in the long term.