Statin action enriches HDL3 in polyunsaturated phospholipids and plasmalogens and reduces LDL-derived phospholipid hydroperoxides in atherogenic mixed dyslipidemia

In the context of the CAPITAIN trial (, ), we presently evaluated the potential impact of statin treatment on the capacity of HDL to inactivate proinflammatory PCOOHs in mixed dyslipidemic, insulin-resistant subjects in a manner relevant to the pathophysiology of atherosclerotic vascular disease. Specifically, and for the first time to our knowledge, we observed that statin treatment i) reduced the content of oxidizable, PUPC molecular species containing DHA and linoleic acid (LA) in LDL; ii) preferentially increased the content of PC molecular species containing AA in small, dense HDL3 relative to HDL2; iii) induced significant elevation in the content of antioxidant PC and PE plasmalogens containing AA and DHA preferentially in HDL3; and finally, iv) induced formation of HDL3 particles with increased capacity to reduce PCOOH to redox-inactive PCOH, thereby attenuating propagation of lipid peroxidation and formation of potentially atherogenic secondary oxidation products. Interestingly, minor changes occurred in the absolute concentrations of HDL2 and HDL3 on treatment, but did not attain significance; these findings contrast with those of Asztalos et al. () who documented preferential increase in large CE-rich α-migrating HDL particles by 2D electrophoresis in patients treated with either atorvastatin, simvastatin, pravastatin, lovastatin, or fluvastatin. The mechanistic basis for such differences in HDL particle profile are indeterminate but may derive from differences between statins on their impact on direct pathways for secretion of HDL particles from the intestine and liver (). Interestingly, CE/TG ratios in both HDL subfractions increased significantly on pitavastatin treatment, consistent with marked reduction in VLDL-TG levels and in plasma CETP activity (unpublished observations). Critically, our experimental design involved use of the same relative mass concentrations of LDL and HDL subfractions (HDL2 and HDL3) in vitro as those in native plasmas of the MetS subjects pre- and poststatin treatment.

The susceptibility of LDL particles to oxidative modification has multiple, mutually interactive lipid and protein determinants, including content of esterified PUFAs, vitamin E, other small molecules with antioxidant activity, sphingophospholipidome composition, and neutral core lipid composition (, , , , , , , ). Importantly, both 1-electron and 2-electron oxidants (lipophilic and hydrophilic free radicals on the one hand and hypochlorite and peroxynitrite on the other) contribute to LDL oxidation in vivo (). Thus, oxidized LDL contains multiple products of free-radical-induced lipid peroxidation, and notably, LOOHs, short-chain oxidized PLs and oxidized sterols (). HDL particles efficaciously inhibit the formation of such primary and secondary peroxidation products in LDL (). Thus, while there is ample evidence for the presence of oxidatively modified LDL in atherosclerotic plaques in humans and in animal species (), and while both enzymatic and nonenzymatic mechanisms are implicated in the underlying oxidative processes, HDL protects against the action of a wide spectrum of reactive oxygen species (ROS) and attenuates LDL oxidation in part by removal of seeding LOOH species (, , , , , , , ). Central to HDL-mediated antioxidative activity is the direct reduction of LOOHs by methionine residues of apoAI and apoAII, with conversion to residue-specific methionine sulfoxides (apoAI + 16, apoAI + 32, and apoAII + 16) (, , , ). Such LOOHs have their origin in LDL; transfer to HDL occurs by aqueous diffusion in the absence of CETP and is limited to PL-derived LOOH ().

Our experimental approach involved an in vitro model of mild LDL oxidation resembling oxidative processes as they occur in the arterial intima (, ). In this way, the rate of formation of free radicals is constant and apolipoprotein oxidation is a secondary process mediated by LOOH (, ). Furthermore purified HDL subfractions (HDL2 or HDL3) were added to LDL in the in vitro oxidation system prior to initiation of oxidation itself. Indeed, we established earlier that HDL3 particles protect LDL from oxidative free radical damage via apoAI-mediated reduction of PCOOH to the corresponding redox-inactive PCOH (). For this reason, we chose to measure the maximum formation of PCOOH and of CDs at the end of the propagation phase in LDL + HDL mixtures at 6 h; the pitavastatin molecule was absent from these oxidation systems in order to exclude any possible endogenous antioxidative activity. It is noteworthy that pitavastatin is an efficacious LDL lowering agent and was used here as a model for the statin class (Table 2).

Multiple molecular mechanisms are implicated in the observed enhancement of the PCOOH-inactivating capacity of statin-induced HDL3, which were concomitant with reduced content of oxidizable PUPC in statin-induced LDL. Indeed, statin treatment favored a reduction (−10% to −18%) in LDL content of four diacyl species of PUPCs (PC 16:0/18:2, PC 16:0/22:6, PC 18:0/18:2, and PC 18:0/22:6); this modification occurred, however, in the absence of change in % weight composition of LDL lipids and protein (Table 2). This finding is not inconsistent with our recent report that plasma enrichment of PC diacylglycerol species containing AA is observed when lipid levels are normalized to nonHDL-C in patients with mixed dyslipidemia and MetS ().

In contrast to poststatin LDL, the preferential elevation in PUPC (i.e., diacyl PCs 16:0/20:4 and 18:0/20:4) seen in HDL3 can result from several mechanisms. One involves reduction in oxidative PUPC degradation as a result of statin-induced decrement in the production of ROS (). A second may arise from enhanced protection of HDL3-PUPC against oxidative degradation due to elevated poststatin content of plasmalogens in HDL3 (see below); these lipids are highly effective antioxidants (, , , , ). Third, pitavastatin has been shown to reduce endothelial lipase (EL) activity by up to 15% (); this enzyme exerts phospholipase activity on HDL (), and therefore, we cannot exclude the possibility that statin-mediated inhibition of EL might contribute to sparing of PUPC.

We recently reported a significant trend to normalization of the abnormal plasma lipidome in insulin-resistant, MetS subjects with a high TG/low HDL-C phenotype in the CAPITAIN study and demonstrated a relative enrichment of both the alkyl (ether-linked) PC and PE species as well as of the alkenyl (vinyl ether-linked) species of PE and PC (the latter corresponding specifically to plasmalogens) after 4 mg/day pitavastatin during 26 weeks (). The present investigations, which focus on vinyl ether-linked plasmalogen species, confirm these data and reveal that statin-induced, small, dense HDL3 are preferentially and significantly enriched in PC-P and PE-P containing AA and DHA at the sn-2 position respectively (PC-P, +12%; PE-P, +24%; PC-P + PE-P, +18%) as compared with LDL and HDL2 in which lesser, nonsignificant changes were observed; values were normalized to nonHDL-C in order to assess these findings independently of change in baseline plasma cholesterol levels (Table 5). Plasmalogens are mainly classified into vinyl-ether choline plasmalogens (PC-P) or ethanolamine plasmalogens (PE-P). The predominant plasmalogen species in plasma LDL, HDL2, and HDL3 were previously shown to be PE-P containing AA (20:4) and DHA (22:6) in the sn-2 position (, , ); in this context, it is relevant that statin action may upregulate the hepatic biosynthetic pathway from LA to AA, as suggested earlier (). Interestingly, total concentrations of PC and PE alkyl ethers [PC(O) and PE(O)] resembled those of the total plasmalogens across the three lipoprotein classes (Table 5). It is established that HDL contained the majority (60%) of plasma PE-P, PE-P species containing 20:4 at the sn-2 position predominating as seen earlier (, ). Their vinyl-ether bond, coupled with enrichment in AA and DHA at the sn-2 position, endow plasmalogens with unique biological functions in an environment of oxidative stress, such as a reservoir for second messengers and the ability to protect membrane lipids from oxidation by scavenging ROS via the vinyl-ether moiety (, , , ). Plasmalogens are consumed during this reaction, leading to the conclusion that they spare the oxidation of unsaturated esterified fatty acids in diacylglycerophospholipids such as PC and PE (, , , ); our present experimental findings confirm major loss of plasmalogens over the oxidation time course. It was equally established that the oxidation products of plasmalogens are unable to further propagate lipid peroxidation (, , ).