Rationale: The HDL-mediated stimulation of cellular cholesterol efflux initiates the reverse cholesterol pathway from macrophages (m-RCT), which ends in the fecal excretion of macrophage-derived unesterified cholesterol (UC). Early studies established that LDL particles could act as efficient intermediate acceptors of cellular-derived UC, thereby preventing the saturation of HDL particles and facilitating their cholesterol efflux capacity (CEC). However, the capacity of LDL to act as a plasma cholesterol reservoir and its potential impact in supporting the m-RCT pathway in vivo both remain unknown. Objective: We investigated LDL contributions to the m-RCT pathway in hypercholesterolemic mice. Methods and Results: Macrophage cholesterol efflux induced either in vitro by LDL added to the culture media either alone or together with HDL, or ex vivo by plasma derived from subjects with familial hypercholesterolemia (FH), was assessed. In vivo, m-RCT was evaluated in mouse models of hypercholesterolemia that were naturally deficient in CETP and fed a Western-type diet. LDL induced the efflux of radiolabeled UC from cultured macrophages, and, in the simultaneous presence of HDL, a rapid transfer of the radiolabeled UC from HDL to LDL occurred. However, LDL did not exert a synergistic effect on HDL CEC in the FH plasma. The m-RCT rates of the LDL receptor (LDLr)-KO, LDLr-KO/APOB100, and PCSK9-overexpressing mice were all significantly reduced relative to the wild-type mice. In contrast, m-RCT remained unchanged in human APOB100 transgenic mice with fully functional LDLr, despite increased levels of plasma APOB-containing lipoproteins. Conclusions: Hepatic LDLr plays a critical role in the flow of macrophage-derived UC to feces, while the plasma increase of APOB-containing lipoproteins is unable to stimulate m-RCT. The results indicate that, besides the major HDL-dependent m-RCT pathway via SR-BI to the liver, a CETP-independent m-RCT path exists, in which LDL mediates the transfer of cholesterol from macrophages to feces.
miR-33 is an intronic microRNA within the gene encoding the SREBP2 transcription factor. Like its host gene, miR-33 has been shown to be an important regulator of lipid metabolism. Inhibition of miR-33 has been shown to promote cholesterol efflux in macrophages by targeting the cholesterol transporter ABCA1, thus reducing atherosclerotic plaque burden. Inhibition of miR-33 has also been shown to improve high-density lipoprotein (HDL) biogenesis in the liver and increase circulating HDL-C levels in both rodents and nonhuman primates. However, evaluating the extent to which these changes in HDL metabolism contribute to atherogenesis has been hindered by the obesity and metabolic dysfunction observed in whole-body miR-33–knockout mice. To determine the impact of hepatic miR-33 deficiency on obesity, metabolic function, and atherosclerosis, we have generated a conditional knockout mouse model that lacks miR-33 only in the liver. Characterization of this model demonstrates that loss of miR-33 in the liver does not lead to increased body weight or adiposity. Hepatic miR-33 deficiency actually improves regulation of glucose homeostasis and impedes the development of fibrosis and inflammation. We further demonstrate that hepatic miR-33 deficiency increases circulating HDL-C levels and reverse cholesterol transport capacity in mice fed a chow diet, but these changes are not sufficient to reduce atherosclerotic plaque size under hyperlipidemic conditions. By elucidating the role of miR-33 in the liver and the impact of hepatic miR-33 deficiency on obesity and atherosclerosis, this work will help inform ongoing efforts to develop novel targeted therapies against cardiometabolic diseases.
Angiopoietin-like 4 (ANGPTL4) is a major regulator of lipoprotein lipase (LPL) activity, which is responsible for maintaining optimal levels of circulating triacylglycerol (TAG) for distribution to different tissues including the adipose tissues (ATs), heart, muscle and liver. Dysregulation of trafficking and portioning of fatty acids (FA) can promote ectopic lipid accumulation in metabolic tissues such as the liver, ultimately leading to systemic metabolic dysfunction. To investigate how ANGPTL4 regulates hepatic lipid and glucose metabolism, we generated liver-specific ANGPTL4 knockout mice (LKO). Using metabolic turnover studies, we demonstrate that hepatic ANGPTL4 deficiency facilitates catabolism of TAG-rich lipoprotein (TRL) remnants in the liver via increased hepatic lipase (HL) activity, which results in a significant reduction in circulating TAG and cholesterol levels. Deletion of hepatocyte ANGPTL4 protects against diet-induce obesity, glucose intolerance, liver steatosis, and atherogenesis. Mechanistically, we demonstrate that absence of ANGPTL4 in hepatocytes promotes FA uptake which results in increased FA oxidation, ROS production, and AMPK activation. Finally, we demonstrate the utility of a targeted pharmacologic therapy that specifically inhibits ANGPTL4 in the liver and protects against diet-induced obesity, dyslipidemia, glucose intolerance, and liver damage without causing any of the deleterious effects previously observed with neutralizing antibodies.
BACKGROUND: Cross-talk between sterol metabolism and inflammatory pathways has been demonstrated to significantly affect the development of atherosclerosis. Cholesterol biosynthetic intermediates and derivatives are increasingly recognized as key immune regulators of macrophages in response to innate immune activation and lipid overloading. 25-Hydroxycholesterol (25-HC) is produced as an oxidation product of cholesterol by the enzyme cholesterol 25-hydroxylase (CH25H) and belongs to a family of bioactive cholesterol derivatives produced by cells in response to fluctuating cholesterol levels and immune activation. Despite the major role of 25-HC as a mediator of innate and adaptive immune responses, its contribution during the progression of atherosclerosis remains unclear. METHODS: The levels of 25-HC were analyzed by liquid chromatography-mass spectrometry, and the expression of CH25H in different macrophage populations of human or mouse atherosclerotic plaques, respectively. The effect of CH25H on atherosclerosis progression was analyzed by bone marrow adoptive transfer of cells from wild-type or Ch25h –/– mice to lethally irradiated Ldlr –/– mice, followed by a Western diet feeding for 12 weeks. Lipidomic, transcriptomic analysis and effects on macrophage function and signaling were analyzed in vitro from lipid-loaded macrophage isolated from Ldlr –/– or Ch25h–/–;Ldlr–/– mice . The contribution of secreted 25-HC to fibrous cap formation was analyzed using a smooth muscle cell lineage–tracing mouse model, Myh11 ERT2CRE mT/mG;Ldlr –/– , adoptively transferred with wild-type or Ch25h –/– mice bone marrow followed by 12 weeks of Western diet feeding. RESULTS: We found that 25-HC accumulated in human coronary atherosclerotic lesions and that macrophage-derived 25-HC accelerated atherosclerosis progression, promoting plaque instability through autocrine and paracrine actions. 25-HC amplified the inflammatory response of lipid-loaded macrophages and inhibited the migration of smooth muscle cells within the plaque. 25-HC intensified inflammatory responses of lipid-laden macrophages by modifying the pool of accessible cholesterol in the plasma membrane, which altered Toll-like receptor 4 signaling, promoted nuclear factor-κB–mediated proinflammatory gene expression, and increased apoptosis susceptibility. These effects were independent of 25-HC–mediated modulation of liver X receptor or SREBP (sterol regulatory element–binding protein) transcriptional activity. CONCLUSIONS: Production of 25-HC by activated macrophages amplifies their inflammatory phenotype, thus promoting atherogenesis.
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