Project description:Apolipoprotein F (ApoF) modulates lipoprotein metabolism by selectively inhibiting cholesteryl ester transfer protein (CETP) activity on LDL. This ApoF activity requires that it is bound to LDL. How hyperlipidemia alters total plasma ApoF and its binding to LDL are poorly understood. In this study, total ApoF and LDL-bound ApoF were quantified by ELISA. Plasma ApoF is increased 34% in hypercholesterolemic plasma. In hypertriglyceridemic plasma, ApoF was statistically unchanged. However, in donors with combined hypercholesterolemia and hypertriglyceridemia, the elevated triglyceride ameliorated the rise in ApoF caused by hypercholesterolemia alone. Compared to normolipidemic LDL, hypercholesterolemic LDL contained ~2-fold more ApoF per LDL particle, whereas ApoF bound to LDL in hypertriglyceridemia plasma was < 20% of control. To understand the basis for altered association of ApoF with hyperlipidemic LDL, the physiochemical properties of LDL were modified in vitro by CETP ± LCAT activities. The time-dependent change in LDL lipid composition, proteome, core and surface lipid packing, LDL surface charge, and LDL size caused by these factors were compared with the ApoF binding capacity of these LDL. Only LDL particle size correlated with ApoF binding capacity. This positive association between LDL size and ApoF content was confirmed in hyperlipidemic plasmas. Similarly, when in vitro-produced, enlarged LDL with elevated ApoF binding capacity were incubated with LPL to reduce their size, ApoF binding was reduced by 90%. Thus, plasma ApoF levels and the activation status of this ApoF are differentially altered by hypercholesterolemia and hypertriglyceridemia. LDL size is a key determinate of ApoF binding and activation.

Project description:Usp21 knockout causes abnormal lipid metabolism in mouse and its polymorphism correlates with hypercholesterolemia in outpatients

Project description:To reveal the function of FABP7 in the inner ear, we evaluated gene expressions between Wild-type and Fabp7 KO mice one day after noise exposure at 10 weeks, using RNA sequencing analysis. The read number was approximately 27–32 million paired-end reads per sample. A total of 24 and 23 genes were identified as upregulated and downregulated differentially expressed genes (DEGs), respectively in Fabp7 KO mice. The upregulation of genes related to nicotinamide-adenine dinucleotide (NADH) dehydrogenase (mt-Nd1, 2, 3, 4, and 6) and a glial high-affinity glutamate transporter (solute carrier family 1, member 2: Slc1a2) and downregulation of genes related to C/D box small nucleolar RNAs were observed in Fabp7 KO mice.

Project description:Metabolic reprogramming has emerged as a crucial regulator of immune cell activation but how systemic metabolism influences immune cell metabolism and function remains to be investigated. To investigate the effect of dyslipidemia on immune cell metabolism, we performed in-depth transcriptional, metabolic and functional characterization of macrophages isolated from hypercholesterolemic mice. Systemic metabolic changes in such mice alter cellular macrophage metabolism and attenuate inflammatory macrophage responses. In addition to diminished maximal mitochondrial respiration, hypercholesterolemia reduces the LPS-mediated induction of the pentose phosphate pathway (PPP) and the Nrf2-mediated oxidative stress response. Our observation that suppression of the PPP diminishes LPS-induced cytokine secretion supports the notion that this pathway contributes to inflammatory macrophage responses. Overall, this study reveals that systemic and cellular metabolism are strongly interconnected, together dictating macrophage phenotype and function.

Project description:Deubiquitinases (DUBs) play a role in regulating protein degradation which is critical for maintaining protein homeostasis. The purpose of this study was to verify biological consequence of genetic depletion of USP21 in human cells on proteome changes and cellular function. Comparison of proteomic analysis of HAP-1 USP21 knockout and HAP-1 WT cells revealed that down-regulated proteins in HAP-1 USP21 KO cell are mostly engaged in mitochondrial function and ATP production. Cellular assays confirmed disturbance of mitochondrial metabolism and decrease in ATP production in HAP-1 USP21 knock-out cells.

Project description:To further elucidate the molecular mechanisms by which microglial NLRC5 exacerbates post-stroke inflammation, we performed proteomic profiling of primary microglia isolated from WT and Nlrc5 KO mice following OGD/R treatment.

Project description:The study demonstrates (i) spatial heterogeneity of endothelial responses to hypercholesterolemia in the aortic valve, (ii) that endothelial metabolism is not dysfunctional in early focal lipid insudation, and (iii) that protective endothelial pathways induced by hypercholesterolemia may initially inhibit the onset of AVS in regions most susceptible.

Project description:In this study, mice with different genotypes and fed diets with different lipid content were enrolled, aiming to set up an atlas of miRNA expression levels in different organs with a relevant role in lipid/lipoprotein metabolism. Specifically, three genotypes were investigated: C57Bl/6 mice as controls, together with mice knock-out (KO) for LDLr (low-density lipoprotein receptor) and for PCSK9 (proprotein convertase subtilisin/kexin type 9). LDLr and PCSK9 are both involved in LDL turnover, the former mediating LDL clearance [PMID: 19299327], the latter causing the degradation of the LDLr protein [PMID: 17080197]. As a result, LDLrKO mice, because of their impaired LDL catabolism, are hypercholesterolemic and prone to atherosclerosis development, particularly when fed high-fat, cholesterol-containing diets [PMID: 8349823; PMID: 8182121]. On the contrary, PCSK9KO mice, characterized by an accelerated LDL catabolism, are hypocholesterolemic and atherosclerosis resistant [PMID: 15805190]. miRNA expression was investigated in liver, intestine, aorta, white adipose tissue and brain of mice on both standard and Western diet.

Project description:BACKGROUND: Vascular smooth muscle cells (VSMC) are the most abundant cell type in the artery’s media layer and regulate vascular tone and lesion remodeling during atherogenesis. Like monocyte-derived macrophages, VSMCs accumulate excess lipids and contribute to the total intimal foam cell population in human coronary plaque and mouse aortic atheroma. While there are extensive studies characterizing the contribution of lipid metabolism in macrophage immunometabolic responses in atherosclerotic plaques, the role of VSMC lipid metabolism in regulating vascular function and lesion remodeling in vivo remains poorly understood. METHODS: We re-analyzed publicly available single-cell RNA sequencing (scRNA-seq) data from mouse atherosclerosis studies and found Liver X receptor (LXR) signaling in VSMCs was continuously activated during atherogenesis. We thus generated mice with an inducible SMC-specific knockout of LXR/LXR on a fate mapping background by crossbreeding LXRf/fLXRf/f mice with Myh11-CreERT2;mTmGf/f mice. Mice were administered with tamoxifen (1 mg/day) for 10 consecutive days and followed by a 2-week resting period to induce CreERT2 mediated recombination. To induce hypercholesterolemia and atherosclerosis, we injected Myh11-CreERT2;mT/mGf/f;LXRf/fLXRf/f mice and Myh11-CreERT2;mT/mGf/f mice with AAV8-PCSK9 and fed them with a Western diet (WD) for 16 weeks. Metabolic, immunocytochemistry and genomic analysis were conducted to assess lesion size and morphology and unravel the molecular mechanism by which LXR in VSMC contributes to lesion formation. RESULTS: Deficiency of LXR in SMCs under hypercholesterolemic condition influenced lesion remodeling by altering the fate of de-differentiated SMC and promoting the accumulation of VSMC-derived transitional cells. This phenotypic switching is accompanied with reduced index of plaque stability characterized by larger necrotic core area and reduced fibrous cap thickness. Moreover, SMC-specific LXR deficiency impaired vascular function and caused visceral myopathy characterized by bladder maladaptive remodeling and gut lipid malabsorption. CONCLUSIONS: We unveil an essential role of hypercholesterolemia-induced LXR signaling in atherosclerotic lesion remodeling, controlling the fate decision of VSMCs and regulating vascular and visceral SMCs functions.

Project description:Statins are efficient in preventing cardiovascular disease progression, but their effects in the absence of low density lipoprotein receptor (LDLR) and on the risk of diabetes are not yet well characterized. The aim was to clarify systemic and pleiotropic effects of Rosuvastatin on cardiovascular and diabetic phenotypes in hypercholesterolemic prediabetic mice. The IGF-II/LDLR-/-ApoB100/100 animals were tested for Rosuvastatin effects on plasma glucose, insulin, lipids, atherosclerosis and liver steatosis. To achieve a more comprehensive view, genes differentially expressed in response to Rosuvastatin were identified by RNA sequencing in liver tissue. Rosuvastatin significantly reduced plasma cholesterol in hypercholesterolemic LDLR – deficient mice, but had no effects on atherosclerosis development at aortic sinus level and in coronary arteries. Rosuvastatin also significantly reduced liver steatosis without any pronounced effects on glucose or insulin levels. RNA sequencing revealed that Rosuvastatin – responsive hepatic genes are involved in cholesterol metabolism and in anti-inflammatory response. In addition, significant changes were detected in the expression of Perilipin 4 and 5 which are involved in lipid droplet formation in the liver. For the first time it was shown that Tribbles proteins are affected by Rosuvastatin treatment in the hypercholesterolemic mice. In conclusion, Rosuvastatin treatment had several positive effects in hypercholesterolemic mice showing early signs of diabetes, and many of these outcomes are unrelated to direct effects on cholesterol and lipoprotein metabolism. These results increase our understanding about the systemic and pleiotropic effects of Rosuvastatin in the absence of LDLR expression.