Abstract

Within the first year, 15-20% of coronary artery saphenous bypass vein grafts (SVGs) occlude because of thrombosis or progressive intimal hyperplasia. One potential new strategy to reduce this complication would be to introduce antithrombotic or antiproliferative genes in vein grafts before implantation. The success of this approach requires an efficient DNA delivery system. In the present study we tested the feasibility of using adenovirus-transferrin/polylysine-DNA complexes (TfAdpl/DNA) to achieve high-efficiency gene transfer into vascular interposition vein grafts. All studies used the Escherichia coli LacZ (beta-galactosidase [beta-Gal]) reporter gene under the control of the cytomegalovirus (CMV) earlier promoter and enhancer (pCMV/LacZ). Autologous rabbit jugular vein segments were incubated ex vivo for 60 min in a solution of TfAdpl/DNA complexes (1.2 x 10(10) biotinylated adenovirus particles, 2,430 ng of streptavindylated polylysine. 10 micrograms of plasmid DNA, and 9 micrograms of transferrin-polylysine per ml), and then reimplanted across the ligated right carotid artery. Control veins were incubated in TfAdpl solution in which DNA was omitted. A total of six grafts were treated with TfAdpl/DNA, and two grafts were treated with TfAdpl. Veins were harvested 3 (n = 3) and 7 (n = 3) days later and beta-Gal activity was determined by X-Gal chromogen staining. All six TfAdpl/DNA-treated grafts stained intensely blue, whereas control grafts were negative. Microscopic examination of serial sections revealed intracellular blue granules consistent with beta-Gal activity to be present in all of the endothelial cells and in numerous medial and advential cells.(ABSTRACT TRUNCATED AT 250 WORDS)