Fenofibrate reduces cisplatin-induced apoptosis by inhibiting the p53/Puma/Caspase-9 pathway and the MAPK/Caspase-8 pathway rather than by promoting autophagy in murine renal proximal tubular cells.

The main lesion of cisplatin nephrotoxicity is damage to proximal tubular cells due to increased apoptosis via the mitochondrial and death receptor pathways, which may be alleviated by appropriate promotion of autophagy. Fenofibrate, a peroxisome proliferator-activated receptor-alpha (PPAR-α) activator, is recently reported to promote autophagy as well as protect against cisplatin nephrotoxicity, although the mechanisms were only partially analyzed. Here, the detailed mechanisms of these putative protective effects were investigated in a murine renal proximal tubular (mProx) cell line. Fenofibrate attenuated cisplatin-induced apoptosis of mProx cells based on flow cytometry. As for the mitochondrial apoptotic pathway, the reagent reduced cisplatin-stimulated caspase-3 activation by decreasing the phosphorylation of p53, JNK, and 14-3-3, cytosolic and mitochondrial Puma accumulation, cytochrome C release to the cytosol, and resulting cytosolic caspase-9 activation. Fenofibrate also decreased cisplatin-stimulated activation of caspases-8 by suppressing MAPK and NFkB pathways and reducing the gene expression of TNF-α, TL1A, and Fas, main mediators of the death receptor apoptotic pathway. Autophagy defined by p62 reduction and an increase in LC3 II/I was promoted by fenofibrate in mProx cells under starvation. Autophagy inhibition using 3-MA further increased basal and cisplatin-induced caspase-3 and -8 activation, but had no influence on the inhibitory effects of fenofibrate on caspase activation. In conclusion, our study suggests fenofibrate to be a candidate agent to mitigate cisplatin nephrotoxicity by inhibiting the mitochondrial and death apoptotic pathways rather than by promoting autophagy.

Smaller low-density lipoprotein size as a possible risk factor for the prevalence of coronary artery diseases in haemodialysis patients: associations of cholesteryl ester transfer protein and the hepatic lipase gene polymorphism with low-density lipoprotein size.

AIM: Smaller low-density lipoprotein (LDL) size has recently been reported as a non-traditional lipid risk factor for coronary artery disease (CAD). Cholesteryl ester transfer protein (CETP) and the C/T hepatic lipase (HL) gene polymorphism may promote LDL size reduction via the CETP-mediated exchange of CE for triglyceride (TG) and subsequent HL-mediated TG hydrolysis in LDL. However, little is known about LDL size status and its relationship with CAD prevalence in haemodialysis (HD) patients who are at high risk for atherosclerosis. METHODS: CETP levels, HL genotypes and LDL size were determined, and the determinants of LDL size and its association with CAD prevalence in HD patients (n = 236) aged over 30 years were investigated. RESULTS: The HD patients had a similar LDL size to the healthy subjects. In the HD group, high-density lipoprotein cholesterol was an independent positive determinant of LDL size, while log(10) (TG) was an independent negative determinant in the high (≥2.1 µg/mL) but not low (<2.1 µg/mL) CETP group. In the patients with hypertriglyceridemia, the high CETP group had a significantly smaller LDL size than the low CETP group. Among the patients with above-median TG levels, the CC genotype and CETP were independent negative determinants of LDL size. In the whole group and the high CETP group, the patients with CAD had a significantly smaller LDL size than those without CAD. Finally, DM and smaller LDL size were identified as independent risk factors for CAD prevalence. CONCLUSION: These suggest that a smaller LDL size, which is associated with higher levels of TG and CETP and the HL/CC genotype, may serve as a risk factor for CAD in HD patients.

Hepatic lipase mutation may reduce vascular disease prevalence in hemodialysis patients with high CETP levels.

BACKGROUND: Uremic dyslipidemia characterized by reduced high-density lipoprotein (HDL) cholesterol levels is one of the major contributors to the high incidence of cardiovascular disease in hemodialysis patients. Hepatic lipase (HL), together with cholesteryl ester transfer protein (CETP), may not only promote reverse cholesterol transport but also enhance production of small, dense, more atherogenic low-density lipoprotein (LDL). A common C-514T mutation of the promoter region of the HL gene reportedly increases HDL cholesterol levels. However, whether the HL mutation is antiatherogenic or proatherogenic has remained unknown in uremic patients and the general population. METHODS: We investigated the influence of the mutation and its interaction with CETP on HDL cholesterol levels and the apparent atherosclerotic complications in 183 hemodialysis patients aged over 30 years who had received no antilipemic drugs. RESULTS: In patients with CETP levels > or =2.2 microg/mL [high CETP (HCT) group, N = 97], subjects with the TT genotype had a significantly higher level of HDL cholesterol than those without TT genotype (56.8 +/- 15.9 mg/dL vs. 45.7 +/- 13.4 mg/dL, P < 0.001), but not in patients with CETP levels <2.2 microg/mL [low CETP (LCT) group]. Multiple linear regression analysis showed that the TT genotype was a major independent positive determinant for HDL cholesterol levels in the HCT not LCT group. Among the HCT group patients, subjects with the TT genotype (N = 25) had a tendency toward lower prevalence of vascular disease than those without TT genotype (N = 72) (4.0% vs. 22.2%, P < 0.07). In this subgroup, TT genotype had an independent odds ratio of 0.041 (95% CI 0.002 to 0.75, P < 0.05) after adjusting for other risk factors. CONCLUSION: The TT genotype of HL mutation may serve as a protective factor against vascular disease by increasing HDL cholesterol levels in hemodialysis patients with higher CETP levels.