LDL (low-density lipoprotein) is the major carrier of cholesterol in human plasma, and as such is intimately involved in the process of atherosclerosis. The lipoprotein class comprises a number of distinct subfractions, and is commonly divided into large, intermediate and small sized particles. Small, dense LDLs are held to be particularly atherogenic, since these particles are retained preferentially by the artery wall, are readily oxidized and carry an enzyme believed to have an important role in atherosclerosis, i.e. lipoprotein-associated phospholipase A(2). Generation of small, dense LDL occurs by intravascular lipoprotein remodelling as a result of disturbances such as Type II diabetes, metabolic syndrome, renal disease and pre-eclampsia. The key predisposing factor is the development of hypertriglyceridaemia, in particular elevation in the plasma concentration of large, triacylglycerol-rich VLDL (very-low-density lipoprotein). This leads to the formation of slowly metabolized LDL particles (5-day residence time), which are subject to exchange processes that remove cholesteryl ester from the particle core and replace it with triacylglycerol. LDL, so altered, is a potential substrate for hepatic lipase; if the activity of the enzyme is high enough, lipolysis will generate smaller, denser particles. Correction of the dyslipidaemia associated with small, dense LDL is possible using fibrates and statins, and this may contribute to the clinical benefits seen with these drugs. Fibrates act to lower plasma triacylglycerol (VLDL) levels, and so correct the underlying metabolic disturbance. Statins remove VLDL particles via receptor-mediated pathways and reduce the residence time (and hence limit the potential for remodelling) of LDL in the circulation.
The objective of the study was to examine the potential differential effect of insulin and acipimox (both of which reduce free fatty acid [FFA] availability) on VLDL apolipoprotein (apo) B metabolism. We studied eight healthy men (age 40 +/- 4 years, BMI 25.8 +/- 0.9 kg/m2, plasma triglycerides 1.30 +/- 0.12 mmol/l) after an overnight fast (control study, n = 8), during inhibition of lipolysis with an antilipolytic agent, acipimox (n = 8), and under 8.5-h euglycemic-hyperinsulinemic conditions (n = 5). Plasma FFAs were similarly suppressed in the acipimox and insulin studies (approximately 70% suppression). 2H3-leucine was used to trace apo B kinetics in VLDL1 and VLDL2 subclasses (Svedberg flotation rates: 60-400 and 20-60), and a non-steady-state multicompartmental model was used to derive the kinetic constants. The mean rate of VLDL1 apo B production was 708 +/- 106 mg/day at the beginning and 602 +/- 140 mg/day at the end of the control study. Production of the lipoprotein decreased to 248 +/- 93 mg/day during the insulin study (P < 0.05 vs. control study) and to 375 +/- 92 mg/day (NS) during the acipimox study. Mean VLDL2 apo B production was significantly increased during the acipimox study (399 +/- 42 vs. 236 +/- 27 mg/day, acipimox vs. control, P < 0.05) but not during the insulin study (332 +/- 51 mg/day, NS). The fractional catabolic rates of VLDL1 and VLDL2 apo B were similar in all three studies. We conclude that acute lowering of FFAs does not change the overall production rate of VLDL particles, but there is a shift toward production of smaller and denser VLDL2 particles, and, thus, the amount of total VLDL particles secreted remained constant. Insulin acutely suppresses the total production rate of VLDL apo B by decreasing the production of large triglyceride-rich VLDL1 particles. Based on these findings, we postulate that insulin has a direct suppressive effect on the production of VLDL apo B in the liver, independent of the availability of FFAs.
We studied the influence of cholestyramine (24 g per day) on receptor-mediated and receptor-independent low-density-lipoprotein catabolism in five women with heterozygous familial hypercholesterolemia. Cholestyramine lowered the level of circulating low-density-lipoprotein apoprotein by doubling (P less than 0.01) its fractional clearance via the receptor path, but fractional catabolism by the receptor-independent route remained unchanged. Moreover, although the absolute rate of catabolism of the apoprotein was not affected by treatment, the amounts handled by each pathway altered. Catabolism via the physiologically controllable receptor route increased by 71 per cent (P less than 0.05), but there was a 12 per cent drop in clearance by the nonreceptor pathway. These data demonstrate the utility of cholestyramine in promoting low-density-lipoprotein catabolism via its specific physiologic clearance pathway. They also show that heterozygotes with familial hypercholesterolemia can increase the activity of their low-density-lipoprotein receptors when presented with an appropriate stimulus.
Non-insulin-dependent diabetic (NIDDM) subjects exhibit abnormalities in their plasma lipid and lipoprotein profiles that increase the risk of ischemic heart disease. This study was designed to examine the metabolic behavior of very-low-density (VLDL), intermediate-density (IDL), and low-density (LDL) lipoproteins in NIDDM patients before treatment and after 4 wk of insulin therapy. Basal turnover studies of 131I-labeled VLDL1 (svedberg units [Sf] 60-400) and 131I-labeled VLDL2 (Sf 20-60) apolipoprotein B (apoB) were conducted in a group of seven NIDDM patients who had been off oral therapy for 1 wk. The subjects exhibited higher than normal transport rates for VLDL1 and a diminished input of apoB into the VLDL2 density range. These observations are concordant with the hypothesis that NIDDM patients overproduce VLDL triglyceride but not apoB. VLDL1 and VLDL2 were converted to IDL and ultimately to LDL at approximately normal rates, although the delipidation pathway by which apoB-containing particles were processed exhibited different properties from that seen in control subjects. Insulin therapy reduced plasma triglyceride by 38%, and this was associated with a 41% fall in VLDL1 mass (P less than 0.01). VLDL2 was less affected (19% reduction, P less than 0.05), IDL was unchanged, and LDL fell 17% (P less than 0.05). Repeat metabolic studies revealed that the major effects of insulin were to reduce VLDL1-apoB transport (from 811 to 488 mg/day) and increase the direct input of VLDL2 into the plasma (from 182 to 533 mg/day, P less than 0.05). These alterations in VLDL production led to normalization of apoB kinetics in IDL and LDL. The fractional catabolic rate of LDL increased 19% (P less than 0.05), whereas direct input into this fraction, which had been high before treatment, was reduced. Postheparin plasma lipoprotein lipase (LPL) and hepatic lipase levels were unaffected by insulin, although the hormone did increase LPL in adipose tissue. This lack of effect on lipase activities correlated well with the observation that the rates of catabolism of apoB in VLDL1, VLDL2, and IDL were not significantly affected by insulin therapy.
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