Adenovirus 5 fibers mutated at the putative HSPG-binding site show restricted retargeting with targeting peptides in the HI loop.

Adenoviral vectors are commonly used for liver-directed gene therapy following systemic administration owing to their strong propensity for hepatocyte transduction. However, many disease applications would benefit from the delivery of adenoviruses to alternate tissues via this route. Research has thus focused on stripping the virus of native hepatic tropism in conjunction with modifying virus capsid proteins to incorporate novel tropism.

Development of efficient viral vectors selective for vascular smooth muscle cells.

The vascular smooth muscle cell (SMC) is integral to the pathogenesis of neointimal formation associated with late vein graft failure, in-stent restenosis, and transplant arteriopathy. Viral vectors transduce SMC with low efficiency and hence, there is a need for improvement. We aimed to enhance the efficiency and selectivity of gene delivery to human SMC.

Transductional and transcriptional targeting of cancer cells using genetically engineered viral vectors.

Gene delivery vectors, including adenovirus (Ad) and adeno-associated virus (AAV), are inefficient and non-selective for cancer due to low levels of viral receptors with high levels on other tissues, including liver. We tested Ads and AAVs with the SIGYPLP-targeting peptide inserted into virus capsids for transduction in a panel of cancer cells. Six of twelve lines (C8161, PC-3, G-CCM, MKN-45, LnCAP and A549) were transduced, independently of native viral tropism.

Third-generation lentivirus vectors efficiently transduce and phenotypically modify vascular cells: implications for gene therapy.

Grafting of saphenous vein (SV) conduits into the arterial circulation triggers a number of adaptive pathological changes characterized by progressive medial thickening, neointima formation and accelerated atheroma. Previous studies have shown that modification of vein graft biology is possible by adenovirus (Ad)-mediated gene transfer, although gene expression is transient. Advancement of vascular gene therapy to the clinic is compromised by the lack of safe and efficient vector systems that provide sustained therapeutic gene delivery to the vasculature.

Gene Therapy for Cardiovascular Disease.

The last decade has seen substantial advances in the development of gene therapy strategies and vector technology for the treatment of a diverse number of diseases, with a view to translating the successes observed in animal models into the clinic. Perhaps the overwhelming drive for the increase in vascular gene transfer studies is the current lack of successful long-term pharmacological treatments for complex cardiovascular diseases. The increase in cardiovascular disease to epidemic proportions has also led many to conclude that drug therapy may have reached a plateau in its efficacy and that gene therapy may represent a realistic solution to a long-term problem.