O16: TARGETING THE LOX-1 SCAVENGER RECEPTOR ATTENUATES ATHEROSCLEROSIS AND NEOINTIMAL HYPERPLASIA IN APO-E NULL TRANSGENIC MICE

Abstract

Abstract Introduction The clinical consequences of atherosclerosis and post-procedure neointimal hyperplasia (NIH) represent a significant proportion of the vascular surgeon's workload. Lectin-like oxidized low density lipoprotein receptor-1 (LOX-1) is a class E scavenger receptor expressed in endothelial cells implicated in atherosclerosis and NIH. This study aims to demonstrate the therapeutic potential of LOX-1 targeting using a transgenic mouse model and LOX-1-specific non-antibody synthetic protein scaffolds called affimers. Method Apolipoprotein-E (APO-E) null and APO-E/LOX-1 double-null transgenic mice were fed a high cholesterol western diet for 12 weeks. One group of APO-E null mice was treated subcutaneously with LOX-1 affimer. All mice underwent unilateral common femoral artery wire injury at week 8. Mice were culled and tissues harvested for evaluation of atherosclerotic burden and femoral artery NIH. Studies were carried out with Home Office approval. Result Compared with APO-E null controls, carotid and femoral bifurcation atherosclerosis (p<0.05) and total aortic plaque coverage (p<0.01) were significantly reduced in APO-E/LOX-1 double-null mice. Reductions were observed in APO-E null mice treated with LOX-1 affimer, however these were non-significant. Femoral artery NIH was reduced by 16% in APO-E/LOX-1 double null and 11% in LOX-1 affimer treated APO-E null mice compared with untreated APO-E controls, however these reductions were non-significant. Conclusion This study demonstrates the therapeutic potential of LOX-1 targeting in large vessel atherosclerotic disease and NIH. Knockout of the LOX-1 transgene produced promising results, while results following LOX-1 affimer therapy were less impressive. Improvements in affimer pharmacokinetics and drug delivery optimisation are avenues for future studies. Take-home message The LOX-1 scavenger receptor is a potential novel therapeutic target in large-vessel atherosclerosis and neointimal hyperplasia.