Catabolism of HDL1 cholesteryl ester in the rat. Effect of ethinyl estradiol treatment.

The present study was performed in control and ethinyl estradiol-treated rats in order to determine the mechanisms involved in the catabolism of HDL1 cholesteryl ester. Ligand blottings on liver membranes showed that purified HDL1, containing about 70% apolipoprotein E and 10% apolipoprotein AI, bind to the LDL receptor (130 kDa) and not to HB2 (100 kDa) or SR-BI (82 kDa), candidate HDL receptors. Immunoblots showed that the treatment increased the hepatic level of the LDL receptor five- to ten-fold, strongly decreased that of SRBI and did not change that of HB2. An in vivo kinetic study showed that the turnover of HDL1 cholesteryl ester is more rapid in treated than control rats. The liver participation (60%) in this clearance was not modified by the treatment. Therefore, it can be concluded that the catabolism of HDL1 cholesteryl ester, in control as in treated rats, is essentially ensured by the uptake of entire particles in the hepatocytes via LDL receptors.

Regional cholesterol synthesis in the intestinal mucosa of the genetically hypercholesterolaemic RICO rat: kinetic study following whole-body gamma-irradiation.

PURPOSE: To investigate regional cholesterol synthesis and kinetics following whole-body gamma-irradiation in the genetically hypercholesterolaemic RICO rat. MATERIALS AND METHODS: Male RICO rats were fed a semi-purified diet for 1 month. At 10 weeks old they were exposed to gamma-irradiation (4 Gy, 1.5 Gy/min) together with controls. At intervals from 1-8 days after irradiation an intraperitoneal administration of [1-14C] acetate was given in order to estimate cholesterogenesis in mucosal cells located at different sites in the small intestine. The protein and DNA contents of the different enterocytes isolated along the crypt/villus axis in four equal parts of the intestine were also determined. RESULTS: A marked decrease of the mean quantities of cholesterol, DNA or protein in mucosa was seen 1 and 2 days after irradiation, showing the loss of 30-40% of the intestinal epithelium. An overshoot of the cell amount was observed after 4 days with a return to basal values by 8 days after irradiation. The kinetic and topological evolution of cholesterol radioactivity, which reflects in situ cholesterol synthesis, showed a typical gradient in controls and at 8 days after irradiation. Cholesterogenesis decreased from the first to the third quarter of the small intestine (duodenum to proximal ileum), and then increased in the fourth quarter (distal ileum). In all segments of the small intestine, cholesterogenesis decreased from crypt cells to villus tip. At days 1 and 2 the gradient of cholesterogenesis on the villus was abolished. A slow recovery was seen from day 4 with a strong overshoot of cholesterol synthesis in crypt cells in every part of the small intestine. CONCLUSIONS: The RICO rat is a useful model for studying the effect of irradiation on regional cholesterogenesis in intestinal mucosa. Cholesterol synthesis in crypt cells was lowered 1 and 2 days after irradiation, over-expressed after 4 days and subsequently returned to its normal level.

Ionizing radiation alters hepatic cholesterol metabolism and plasma lipoproteins in Syrian hamster.

PURPOSE: The investigation of the effects of ionizing radiation on hepatic cholesterol metabolism and the concentration and composition of plasma lipoproteins in the male Syrian hamster. MATERIALS AND METHODS: After sublethal whole-body 60Co gamma-irradiation (8 Gy, 1 Gy/min), plasma lipoproteins were separated by density-gradient ultracentrifugation. Activities of hydroxymethylglutarylCoA (HMGCoA) reductase and of cholesterol 7alpha-hydroxylase were measured in hepatic microsomes and the low-density lipoprotein (LDL) receptor mass was determined in hepatic total membranes. Lipid peroxidation in LDL was assessed in vitro as the formation of conjugated dienes at 234 nm. A group of pair-fed animals served as controls as the food intake was markedly decreased with exposure to radiation. RESULTS: Plasma lipid concentrations decreased 2 days post-irradiation and then markedly increased by day 6 post-irradiation; plasma cholesterol was increased by 77% and triglycerides by +207%. LDL accumulated in plasma while high-density lipoprotein (HDL) levels decreased. HDL contained significant amounts of apo SAA, the acute phase apolipoprotein. The activities of hepatic HMGCoA reductase, the rate-limiting enzyme for cholesterol synthesis, increased (+125%, p=0.06); hepatic cholesterol 7alpha-hydroxylase, the rate-limiting enzyme for bile acid synthesis, decreased (-85%); and the hepatic LDL receptor mass also decreased (-44%). The susceptibility of LDL to oxidation was also increased when animals were exposed to radiation. CONCLUSIONS: Lipoprotein modifications that appeared following radiation exposure may result from an induced inflammatory state and may further contribute to vascular damage.

Effects of ionizing radiation (neutrons/gamma rays) on plasma lipids and lipoproteins in rats.

Male Wistar rats weighing 250 g were exposed to 4 Gy of neutrons/gamma radiation (3.33 Gy of neutrons and 0.66 Gy of gamma rays). After whole-body irradiation, plasma cholesterol and phospholipid levels increased up to 62 and 37%, respectively, at day 4 and then returned to control values 12 days after irradiation. Plasma triglyceride concentrations decreased concomitantly with decreased food intake after irradiation but remained higher than in pair-fed control rats. Plasma lipoproteins were separated by ultracentrifugation on a density gradient (1.006-1.210 g/ml). Four days after irradiation, most of the cholesterol (62% compared to 31% in controls, P < 0.001) is transported by apolipoprotein E-rich high-density lipoproteins. At the same time, plasma levels of apolipoproteins B and E were increased by 28 and 65%, respectively, while those of apolipoproteins AI and AIV were reduced by 21 and 59%, respectively. While in the liver of irradiated rats the apolipoprotein B/E receptor number was not modified, the hydroxymethylglutaryl coenzyme A reductase activity was fivefold higher than in control pair-fed rats. Four days after irradiation, the susceptibility of lipoproteins to peroxidation, as measured by the formation of conjugated dienes in the presence of Cu2+, was markedly increased while plasma vitamin E levels were decreased, demonstrating that irradiation reduces antioxidant stores markedly. These results suggest that such modified lipoproteins could be involved in radiation-induced vascular damage.