Abstract
High plasma levels of apolipoprotein A-I (apoA-I) correlate with cardiovascular health, whereas dysfunctional apoA-I is a cause of atherosclerosis. In the atherosclerotic plaques, amyloid deposition increases with aging. Notably, apoA-I is the main component of these amyloids. Recent studies identified high levels of oxidized lipid-free apoA-I in atherosclerotic plaques. Likely, myeloperoxidase (MPO) secreted by activated macrophages in atherosclerotic lesions is the promoter of such apoA-I oxidation. We hypothesized that apoA-I oxidation by MPO levels similar to those present in the artery walls in atherosclerosis can promote apoA-I structural changes and amyloid fibril formation. ApoA-I was exposed to exhaustive chemical (H2O2) oxidation or physiological levels of enzymatic (MPO) oxidation and incubated at 37 °C and pH 6.0 to induce fibril formation. Both chemically and enzymatically oxidized apoA-I produced fibrillar amyloids after a few hours of incubation. The amyloid fibrils were composed of full-length apoA-I with differential oxidation of the three methionines. Met to Leu apoA-I variants were used to establish the predominant role of oxidation of Met-86 and Met-148 in the fibril formation process. Importantly, a small amount of preformed apoA-I fibrils was able to seed amyloid formation in oxidized apoA-I at pH 7.0. In contrast to hereditary amyloidosis, wherein specific mutations of apoA-I cause protein destabilization and amyloid deposition, oxidative conditions similar to those promoted by local inflammation in atherosclerosis are sufficient to transform full-length wild-type apoA-I into an amyloidogenic protein. Thus, MPO-mediated oxidation may be implicated in the mechanism that leads to amyloid deposition in the atherosclerotic plaques in vivo.
Highlights
Amyloids made of apolipoprotein A-I contribute to the growth of the atherosclerotic plaques
ApoA-I Oxidation—To investigate whether levels of MPOmediated apolipoprotein A-I (apoA-I) oxidation similar to those encountered in atherosclerotic arteries are sufficient to promote apoA-I amyloid fibril formation [2], we incubated human plasma purified apoA-I in the presence of the MPO-H2O2-ClϪ system
The current study demonstrates that apoA-I Met oxidation promoted by MPO levels similar to those occurring in atherosclerotic lesions induces amyloid fibril formation
Summary
Amyloids made of apolipoprotein A-I (apoA-I) contribute to the growth of the atherosclerotic plaques. In contrast to hereditary amyloidosis, wherein specific mutations of apoA-I cause protein destabilization and amyloid deposition, oxidative conditions similar to those promoted by local inflammation in atherosclerosis are sufficient to transform full-length wild-type apoA-I into an amyloidogenic protein. Prompted by this observation and the ability of MPO to facilitate Met oxidation in vivo [12], we hypothesized that MPO-mediated oxidation of apoA-I can produce protein variants that are structurally destabilized and amyloidogenic To test this hypothesis, we exposed plasma apoA-I to physiological levels of MPO (in the MPO-H2O2-ClϪ system). Our results support the hypothesis that oxidation of apoA-I by MPO levels similar to those found in atherosclerotic lesions is sufficient to render apoA-I amyloidogenic and identify a potential mechanistic link between local inflammation and amyloid deposition in atherosclerosis
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