However, we were unable to demonstrate a specific differential up-regulation of VCAM-1 in LOX-1-transduced cells because VCAM-1 expression was detected in all endothelial cells, suggesting NFκB activation was ubiquitous in this model (this may also be due to the semiquantitative nature of immunohistochemistry limiting a difference in expression from being observed—data not Angiogenesis inhibitor shown). The precise mechanism(s)
by which endothelial overexpression of LOX-1 enhances atherosclerosis in this model is undefined and is likely to be a combination of increased production of ROS, NFκB activation, adhesion molecule expression, and leukocyte binding and extravasation [6] and [10]. Thus a detailed study of the pro-atherogenic mechanisms of LOX-1 in endothelial cells in vivo is warranted. We chose
to perform these experiments in the common high throughput screening assay carotid artery of hyperlipidemic mice because this site normally remains free of atherosclerotic plaques even after months of high-fat feeding, due to its lack of curvature and side branches. Thus it is a good test site for the analysis of genes which may have pro-atherogenic function. Adenoviral vectors provide an efficient means of ectopically inducing gene expression in the carotid artery; however, strong expression from these vectors is not expected to last for more than 2–3 weeks. This makes them useful for studies looking at atherogenic gene function in the mouse hyperlipidemic model, where atherosclerosis develops rapidly, enabling even short-term transgene expression of proatherogenic genes to initiate a lesion. Fibrotic deposition around transduced arteries is observed in this model, as a response to surgically induced injury. En face oil red O staining was used to visualize lipid deposition in transduced and control arteries (see Supplementary Information); however, there was variable staining of the fibrotic tissue surrounding the artery, with some arteries exhibiting significant perivascular staining, presumably because of foam cell accumulation in the surrounding tissue. Because it was not possible to accurately discriminate between
luminal and adventitial oil red O staining in all the transduced arteries, measurement of plaque area on longitudinal sections was used. The approach used here worked well to examine the proatherogenic Histone demethylase effect of a cell-surface molecule, without the need for creating a transgenic animal, allowing rapid analysis of gene function. The experimental design should also work for anti-atherogenic molecules, as the combination of surgery and control virus induced significant initiation of plaque coverage (no plaque is observed in unoperated vessels—S. White, unpublished data). This gives the possibility of a simple single procedure for observing either pro- or anti-atherogenic effects of gene overexpression, in the ApoE−/− mouse.