Novel Therapy for Atherosclerosis Using Recombinant Immunotoxin Against Folate Receptor β–Expressing Macrophages

Macrophage apoptosis occurs throughout all stages of atherosclerosis, yet new findings in vivo suggest that the consequences of this event may be very different in early versus late atherosclerotic lesions. In early lesions, where phagocytic clearance of apoptotic cells appears to be efficient, macrophage apoptosis is associated with diminished lesion cellularity and decreased lesion progression. In late lesions, however, a number of factors may contribute to defective phagocytic clearance of apoptotic macrophages, leading to secondary necrosis of these cells and a proinflammatory response. The cumulative effect of these late lesional events is generation of the necrotic core, which, in concert with proatherogenic effects of residual surviving macrophages, promotes further inflammation, plaque instability, and thrombosis. Thus, the ability or lack thereof of lesional phagocytes to safely clear apoptotic macrophages may be an important determinant of acute atherothrombotic clinical events. Further understanding of the mechanisms involved in macrophage apoptosis and phagocytic clearance might lead to novel therapeutic strategies directed against the progression of advanced plaques.

Atherosclerosis is a complex disease with both genetic and environmental determinants. Apolipoprotein (Apo) E-deficient mice have been created that are highly susceptible to atherosclerosis. In order to assess the role of human apolipoprotein (hApo) A-I and high density lipoprotein (HDL) in atherosclerosis susceptibility, transgenic mice overexpressing the hApo A-I gene were crossed with Apo E-deficient mice. Apo E-/-, hApo A-I mice with two-fold elevation in HDL cholesterol have markedly diminished atherosclerosis with less fibroproliferative lesions by 8 months of age. A strong reciprocal relationship between HDL cholesterol levels and atherosclerosis was found with HDL levels accounting for 78% of the observed variance in mean lesion area. The effect of HDL on atherosclerosis resistance was independent of non-HDL cholesterol.

Although monocytes/macrophages are considered important in atherogenesis, their role in established plaques is unclear. For example, macrophage content is associated with plaque instability, but their loss through cell death is observed at sites of plaque rupture. To examine the role of monocytes/macrophages in atherosclerosis, we developed CD11b-diphtheria toxin (DT) receptor (DTR) transgenic mice, whereby administration of DT selectively kills monocytes/macrophages. DT treatment reduced peripheral blood monocytes and tissue macrophages and inhibited macrophage function in CD11b-DTR mice and apolipoprotein E-null (apoE(-/-)) mice transplanted with CD11b-DTR bone marrow. In atherogenesis experiments, DT markedly reduced plaque development and altered plaque composition, reducing collagen content and necrotic core formation. In mice with established plaques, acute DT treatment induced macrophage apoptosis and reduced macrophage content but did not induce plaque inflammation, thrombosis, or rupture. Furthermore, despite a 50% reduction in monocytes, chronic DT treatment of these mice did not alter plaque extent or composition, most likely because of ongoing recruitment/proliferation of monocytes with recovery of macrophage content. We conclude that monocytes/macrophages are critical to atherogenesis, but established plaques are more resistant to reductions in monocytes.