Abstract Body (Do not enter title and authors here): Introduction: Oxidized phospholipids (OxPL) derived from LDL play a crucial role in the development and progression of atherosclerosis by promoting chronic inflammation and formation of foam cells. The natural antibody E06, binding to OxPL, diminishes macrophage uptake of OxLDL in vitro and decreases atherosclerosis progression in vivo. In our prior work using a model of plasma cholesterol cycling (high-low-high), resulting in atherosclerotic plaque Progression (P)-Regression (PR)-re-Progression (PRP), respectively, we observed accelerated plaque inflammation in the PRP group relative to mice with non-cycling high cholesterol.
Hypothesis: OxPL promotes plaque inflammation in the cholesterol cycling model via trained immunity and that the E06 antibody will mitigate this process.
Methods: We utilized transgenic "E06 mice" that expressed a single-chain variable fragment of E06 (E06-scFv) using the Apoe promoter on the Ldlr−/− background. Both E06 mice and Ldlr-/- mice were subjected to high cholesterol diets (HCD) and categorized into three groups in the cholesterol cycling model: Baseline Progression (P), PR and PRP. Plaque regression was induced by ApoB-ASO injection, which significantly lowered cholesterol levels by inhibiting LDL production.
Results: As before, Ldlr-/- mice in the PRP group exhibited accelerated plaque inflammation post-regression shown by CD68 staining on aortic roots. Notably, this acceleration was significantly inhibited in the E06 mice, highlighting the protective effects of E06 against plaque re-progression. Additionally, flow cytometry of peripheral blood exhibited reduced total monocytes and Ly6Chi-monocytes (thought to become inflammatory macrophages in plaques), alongside increased Ly6Clo-monocytes (thought to become inflammation resolving macrophages in plaques) among E06 mice in the PRP group compared to Ldlr-/- mice. Ex-vivo stimulation of bone marrow cells with the inflammatory stimulus LPS demonstrated higher IL-6 levels in supernatant in Ldlr-/- mice versus E06 mice in the PRP group, suggesting OXPL-induced trained immunity in bone marrow precursors of monocytes and macrophages is involved.
Conclusion: The acceleration of plaque inflammation in cholesterol cycling model was significantly inhibited in the E06 mice. These results provide insight into the increased risk of cardiovascular disease in individuals with intermittent adherence to statins who undergo cholesterol cycling.