Quantification of the hepatic contribution to the catabolism of high density lipoproteins in rats.

Isolated rat livers were perfused for four hours in a recirculating system containing washed rat erythrocytes. Biologically screened radioiodinated rat high density lipoproteins (1.090 < d < 1.21 g/ml) were added to the perfusate with different amounts of whole serum to supply unlabeled rat high density lipoproteins. The protein moiety of the lipoprotein contained more than 95% of the radioiodine. The fraction of apolipoprotein mass degraded during the perfusion was quantified by the linear increment of non-protein-bound radioiodine in the perfusate, corrected for the increment observed during recirculation of the perfusate in the absence of a liver. The small amount of (131)I secreted into bile was added to calculate the fractional catabolic rate. The fractional catabolic rate ranged from 0.22 to 0.63% per hour in 12 experiments and was inversely related to the size of the perfusate pool of high density apolipoprotein. The absolute catabolic rate of high density apolipoprotein (fractional catabolic rate x pool size) in three livers in which the concentration of rat HDL in the perfusate approximated that in intact rats was 69.5 +/- 10.4 micro g hr(-1) (mean +/- SD). The rate of disappearance of cholesteryl esters of rat high density lipoproteins (labeled biologically by injecting donor rats with [5-(3)H]mevalonic acid) from the liver perfusate did not exceed that of the apoprotein component. These rates were compared with catabolic rates for rat high density lipoproteins in intact rats. Fractional catabolic rate in vivo, obtained by multicompartmental analysis of the disappearance curve of (131)I-high density apolipoprotein from blood plasma, was 11.9 +/- 1.3% hr(-1) (mean +/- SD). Total catabolic rate in vivo (fractional catabolic rate x intravascular pool of high density apolipoprotein) was 986 +/- 145 micro g hr(-1) (mean +/- SD). The results suggest that only a small fraction of high density lipoproteins in blood plasma of rats is degraded directly by the liver.-Sigurdsson, G., S-P. Noel, and R. J. Havel. Quantification of the hepatic contribution to the catabolism of high density lipoproteins in rats.     

Cholesterol metabolism in the genetically hypercholesterolemic rat (RICO). I. Measurement of turnover processes

The rates of mobile cholesterol turnover processes were measured by the isotopic equilibrium method in normocholesterolemic (SW) and hypercholesterolemic homozygote (RICO) rats fed a semi-synthetic base diet containing 0.05% cholesterol. When the absorption rate is similar in SW and RICO rats, the internal secretion rate is 60% higher in RICO (25.3 mg/day) than in SW (16.2 mg/day). This increase is compensated by an increase in fecal excretion (RICO: 5 mg/day; SW: 3.8 mg/day), urinary excretion (RICO: 1.7 mg/day; SW: 1.1 mg/day) and above all the transformation of cholesterol into bile acids (RICO: 24.2 mg/day; SW: 15.3 mg/day). The fact that 70 minutes after [14C]acetate administration, the only variations obtained in RICO compared to SW rats are a doubled sterol radioactivity in the small intestine and a tripled one in the liver suggests that the increase in internal secretion of the RICO rat has both an intestinal and hepatic origin. This cholesterogenic stimulation in RICO rats takes place in the jejunum as well as in the ileum and in the crypt cells as well as in the villosities. It is concomitant with a doubled cholesterolemia, a doubled intestinal, caecal and colon bile acid pool and a 20% increase in the enterocyte protein content.     

The RICO rat (genetically hypercholesteremic): a good model for testing a food substance or a drug specific for a key enzyme of cholesterol metabolism]

The genetically hypercholesterolemic RICO rat: a good model for testing a food substance or a drug specific for a key enzyme involved in cholesterol metabolism? The genetically hypercholesterolemic RICO rat, whose cholesterolemia is situated between 1.3 and 1.5 mg x mL(-1), possibly reaching 2 mg x mL(-1), after the addition of cholesterol to its food, possesses a different lipoprotein spectrum than man, because approximatively 70% of the plasma cholesterol is carried by HDL (28% of which are carried by the light HDL1 subfraction, rich in apolipoproteinE (apoE). The effects of certain substances in food (carbohydrates, cholesterol, allyldisulfide, etc.) or drugs (ethinylestradiol, streptozotocin, statins, inhibitors of ACAT, etc.) on the cholesterolemia of the rat were studied, in relation to certain important parameters of cholesterol metabolism (LDLr, VLDL liver secretion, activities of lipolytic enzymes: LPL, HL, etc.). The increase in a number of LDL receptors (LDLr) in the RICO rat, induced by ethinylestradiol, streptozotocin, etc., provokes an important decrease in the apoE-rich HDL concentration, filtered out by its receptors. This decrease is observed in man for LDL. Simvastatin, which stimulates LDLr in man and not in rat, lowers the level of LDL in man and has no effect on the cholesterolemia of the RICO rat. In rat and man, the concentration of plasma cholesterol is inversely proportional to the rate of cholesterol synthesis in the organism and to its plasma turnover rate. The concentration of cholesterol in the plasma carried by the HDL1 of the rat, is however, proportional to hepatic cholesterogenesis. This fraction is positively correlated to the activity of hepatic lipase (HL) and negatively to the activity of lipoprotein lipase (LPL), released by heparin. These data demonstrate the importance of the liver and lipolytic enzymes in the intraplasmatic hydrolysis of HDL3 (precursors of HDL1), murine particles that can be considered similar to human LDL.     

Urea synthesis from ammonia in periportal and pericentral regions of the liver lobule. Effect of oxygen

Rates of urea synthesis were determined in periportal and pericentral regions of the liver lobule in perfused liver from fed, phenobarbital-treated rats by measuring the extra O2 consumed upon infusion of NH4Cl with miniature O2 electrodes and from decreases in NADPH fluorescence detected with micro-light-guides. Urea synthesis by the perfused rat liver supplemented with lactate (5 mM), ornithine (2 mM) and methionine sulfoximine (0.15 mM), an inhibitor of glutamine synthetase, was stimulated by stepwise infusion of NH4Cl at doses ranging from 0.24 mM to 3.0 mM. A good correlation (r = 0.92) between decreases in NADPH fluorescence and urea production was observed when the NH4Cl concentration was increased. Sublobular rates of O2 uptake were determined by placing miniature oxygen electrodes on periportal or pericentral regions of the lobule on the liver surface, stopping the flow and measuring decreases in oxygen tension. From such measurements local rates of O2 uptake were calculated in the presence and absence of NH4Cl and local rates of urea synthesis were calculated from the extra O2 consumed in the presence of NH4Cl and the stoichiometry between O2 uptake and urea formation. Rates of urea synthesis were also estimated from the fractional decrease in NADPH fluorescence, caused by NH4Cl infusion in each region, measured with micro-light-guides and the rate of urea synthesis by the whole organ. When perfusion was in the anterograde direction, maximal rates of urea synthesis, calculated from changes in fluorescence, were 177 +/- 31 mumol g-1 h-1 and 61 +/- 24 mumol g-1 h-1 in periportal and pericentral regions, respectively. When perfusion was in the retrograde direction, however, rates were 76 +/- 23 mumol g-1 h-1 in periportal areas and 152 +/- 19 mumol g-1 h-1 in pericentral regions. During perfusion in the anterograde direction, urea synthesis, calculated by changes in O2 uptake, was 307 +/- 76 mumol g-1 h-1 and 72 +/- 34 mumol g-1 h-1 in periportal and pericentral regions, respectively. When perfusion was in the retrograde direction, urea was synthesized at rates of 54 +/- 17 mumol g-1 h-1 and 387 +/- 99 mumol g-1 h-1 in periportal and pericentral regions, respectively. Thus, maximal rates of urea synthesis were dependent upon the direction of perfusion. In addition, rates of urea synthesis were elevated dramatically in periportal regions when the flow rate per gram liver was increased (e.g. 307 versus 177 mumol g-1 h-1).(ABSTRACT TRUNCATED AT 400 WORDS)     

Enterohepatic circulation in hamsters with an extracorporeal bile duct.

The present study describes a novel technique for investigations of the enterohepatic circulation in the hamster with an extracorporeal bile duct that allows long-term bile collection in the free-moving animal. The animals recovered for 7 days after the operation before the external loop was cut and bile was collected over a period of 78 h. Under these optimal conditions, initial bile flow (651 +/- 89 microliters per 100 g.h-1) and the secretion rates of biliary lipids were several-fold higher than reported in an earlier study using the acute fistula hamster. Biliary cholesterol secretion amounted to 369 +/- 32 nmol per 100 g.h-1, phospholipid secretion was 2.6 +/- 0.3 mumol per 100 g.h-1, and total bile acid secretion was 31.9 +/- 2.2 mumol per 100 g.h-1. A clearcut diurnal rhythm was demonstrated for bile flow and all biliary constituents. After 9 h the depletion of the bile acid pool was complete and cholic acid synthesis derepressed 1.4-fold from a basal rate of 818 nmol per 100 g.h-1, whereas the derepression of chenodeoxycholic acid synthesis was even less pronounced. Biliary cholesterol output increased 2.2-fold, but the phospholipid secretion was constant during the full experiment. It may be concluded that the technique of an extracorporeal bile duct in the free-moving animal allows studies of bile secretion under optimal conditions. Most likely the bile secretion rates given above approach the physiological rates in the hamster.     

Effect of coconut oil on plasma apo A-I levels in WHHL and NZW rabbits

Age-matched Watanabe (WHHL) and New Zealand White (NZW) rabbits were fed a coconut oil-enriched diet (14%, w/w) for 2 weeks. Lipid and apolipoprotein (apo) A-I levels in plasma and lipoprotein fractions were monitored. Within 3 days after the start of the coconut oil diet, plasma apo A-I and high-density lipoprotein (HDL)-apo A-I levels increased 3-fold in the WHHL rabbits. A smaller but significant increase (63%) in apo A-I and HDL-apo A-I levels was also observed in the NZW rabbits. HDL cholesterol levels also increased from 16 +/- 3 mg/dl during a regular diet to 46 +/- 16 mg/dl (288%) during the coconut oil diet in the WHHL rabbits and from 37 +/- 7 mg/dl to 69 +/- 19 mg/dl (186%), respectively, in the NZW rabbits. Apo A-I and HDL cholesterol levels fell sharply to the original levels soon after switching back to a regular diet (within 3 days for WHHL rabbits and within 5 days for NZW rabbits). The fractional catabolic rate calculated from 125I-HDL kinetic studies indicated that the turnover rate for HDL was significantly slower in WHHL rabbits fed the coconut oil diet than the control diet (0.018 +/- 0.004 h-1 vs. 0.027 +/- 0.007 h-1, P less than 0.01). No changes were found in the NZW rabbits fed either diet. Trilaurin, the main component of the coconut oil (46.9%) supplemented diet (6.5%, w/w), was also used in this study. The effect of trilaurin on plasma apo A-I and HDL-cholesterol levels is discussed.     

Tissue sites of degradation of native and reductively methylated [14C]sucrose-labeled low density lipoprotein in rats. Contribution of receptor-dependent and receptor-independent pathways

Low density lipoprotein (LDL) is catabolized by both receptor-dependent and receptor-independent pathways; methylated LDL (MeLDL) is catabolized only by receptor-independent mechanisms. Rats were injected with either LDL or MeLDL labeled with [14C]sucrose and the tissue sites of degradation were determined 24 h later. On degradation, the 14C-labeled ligand remains trapped intracellularly as a cumulative measure of degradation. The fractional catabolic rate (FCR) of [14C]sucrose-MeLDL was lower than that of [14C]sucrose-LDL (0.056 +/- 0.015 versus 0.118 +/- 0.025 h-1, p less than 0.01). Liver was the predominant site of catabolism of both LDL and MeLDL; more than 85% of catabolism was attributable to parenchymal cells in both cases. The fraction of the plasma LDL pool "cleared" per tissue weight per unit of time was determined for individual tissues. The differences in these rates for LDL and MeLDL are an approximation of receptor-mediated uptake of LDL. According to this method, 67.4% of hepatic uptake was attributable to receptors, as was 69.5% of adrenal, 65.4% of ovarian, 52.4% of intestinal, and 44.2% of renal uptake. In other studies, rats were continuously infused with LDL to down-regulate and saturate receptor prior to injection of labeled LDL or MeLDL. Rats infused with LDL exhibited a lower FCR for [14C]sucrose-LDL compared to controls (0.077 versus 0.120 h-1); the FCR for sucrose-MeLDL was unchanged by LDL infusion. The fractional degradation rate of [14C]sucrose-LDL by individual tissues was lowered by LDL infusion in liver, adrenal, ovary, and intestine (41.4, 57.3, 23.1, and 32.4% lower than controls, respectively). The determination of receptor dependency by this independent approach supports the conclusions reached using [14C]sucrose-LDL and [14C]sucrose-MeLDL in normolipemic animals.     

Catabolism of the apoprotein of low density lipoproteins by the isolated perfused rat liver.

Isolated rat livers were perfused for 4 hours in a recirculating system containing washed rat erythrocytes. Biologically screened, radioiodinated low density lipoproteins (1.030 < d < 1.055 g/ml) were added to the perfusate with different amounts of whole serum to supply unlabeled rat low density lipoproteins. Apolipoprotein B contained 90% of the bound (131)I, other apolipoproteins contained 4%, and lipids contained the remainder. The fraction of apolipoprotein mass degraded during the perfusion was quantified by the linear increment of non-protein-bound radioiodine in the perfusate, corrected for the increment observed during recirculation of the perfusate in the absence of a liver. The fractional catabolic rate ranged from 0.3 to 1.7%/hr in seven experiments and was inversely related to the size of perfusate pool of low density apolipoprotein. The catabolic rate of low density apolipoprotein (fractional catabolic rate x pool size) in four livers, in which the concentration of rat low density lipoproteins was 50-100% of that present in intact rats, was 5.3 +/- 2.7 micro g hr(-1) (mean +/- SD). Similar results were obtained with human low density lipoproteins. These rates were compared with catabolic rates for the apoprotein of rat low density lipoproteins in intact animals. Fractional catabolic rate in vivo, obtained by multi-compartmental analysis of the disappearance curve of (131)I-labeled low density apolipoprotein from blood plasma, was 15.2 +/- 3.1% hr(-1) (mean +/- SD). Total catabolic rate in vivo (fractional catabolic rate x intravascular pool of low density apolipoprotein) was 76 +/- 14 micro g hr(-1) (mean +/- SD). The results suggest that only a small fraction of low density apolipoprotein mass in rats is degraded by the liver.     

In vivo apoprotein catabolism of high density lipoproteins in copper-deficient, hypercholesterolemic rats

High density lipoprotein (HDL) apoprotein catabolism was examined in male Sprague-Dawley rats deficient in dietary copper. Twenty-four rats were randomly divided into two groups: copper-adequate (control, 5 mg of copper/kg diet) and copper-deficient (0.6 mg of copper/kg diet). After 5 weeks, animals were administered a tracer dose of iodinated HDL protein previously isolated from donor rats that were subjected to the same dietary treatments as the test animals. Copper-deficient rats exhibited a 54% increase in plasma volume and a 26% increase in HDL protein concentration above controls. Consequently, the intravascular pool of total HDL protein was increased 2-fold. The fractional catabolic rate of total HDL protein was similar between groups. However, because of the increased intravascular HDL pool in copper-deficient animals, the absolute catabolic rate was greater (640 +/- 49 micrograms/hr vs 316 +/- 12 micrograms/hr in controls). Tissue uptake of total HDL protein in copper-deficient rats tended to be greater in the kidneys, spleen, and testes compared with controls; the heart exhibited a significant 2.3-fold increase. In contrast, the catabolic rate of HDL protein in the liver and adrenal gland were not different between treatment groups. That an obligatory increase in HDL protein uptake was not observed in the liver and adrenal gland (organs which are sensitive to and can further metabolize cholesterol) suggests that these organs may be regulated, possibly contributing to the observed hypercholesterolemia in this model. These data imply that total HDL apoprotein catabolism is increased in response to the increased intravascular pool of HDL in copper-deficient rats.     

Correlation of low and high density lipoprotein binding in vivo with rates of lipoprotein degradation in the rat. A comparison of lipoproteins of rat and human origin

These studies were done in the rat to correlate the ability of low and high density lipoproteins of rat (rLDL and rHDL) and human (hLDL and hHDL) origin to bind in vivo to specific tissues with the rates at which these same lipoprotein fractions were cleared from the circulation. The adrenal gland and liver manifested the greatest amounts of rLDL binding in vivo, but activity also was found in spleen, lung, kidney, ovary, and intestine. In contrast, little or no such binding was found utilizing either methyl-rLDL or hLDL. rHDL containing E apoprotein bound to the same group of tissues although in lesser amounts, except in the case of ovary and adrenal gland which bound disproportionately greater amounts of rHDL than rLDL. In keeping with these marked differences in tissue binding, the clearance of rLDL from the plasma equaled 847 +/- 36 microliters/h/100 g of rat while that of methyl-rLDL and hLDL was only 368 +/- 8 and 363 +/- 11 microliters/h/100 g of rat, respectively. When the steady state plasma level of rLDL was raised 2.5-fold, the clearance decreased slightly to 705 +/- 20 microliters/h/100 g of rat. The clearance of hLDL remained constant, however, at about 350 microliters/h/100 g of rat even when the plasma hLDL level was raised to very high values. The clearance of rHDL and hHDL equaled 644 +/- 16 and 408 +/- 13 microliters/h/100 g of rat, respectively, reflecting the more similar rate of binding of rHDL and hHDL to the tissues of the rat. Rates of whole animal sterol synthesis were lowered from 28 mumol/h to 8.8 mumol/h or 13 mumol/h by fasting and cholesterol feeding, respectively, and stimulated to 71 mumol/h by cholestyramine treatment. Under these same conditions, hepatic cholesterol synthesis could be lowered from the normal rate of 15 mumol/h to 4.2 mumol/h and raised to 50 mumol/h. None of these treatments, however, affected the plasma clearance of rLDL and rHDL. In contrast, treatment with ethinyl estradiol increased by 3-fold both the hepatic binding and the whole animal plasma clearance of rLDL. Following resection of approximately two-thirds of the liver under carefully controlled metabolic conditions, there was no change in the rate of hepatic cholesterol synthesis or rLDL binding in the remaining liver, but the clearance of chylomicrons, rLDL, and rHDL diminished by 67%, 26%, and 17%, respectively, suggesting that in the rat the liver was responsible for the degradation of approximately 97%, 39%, and 27%, respectively, of these lipoprotein fractions.     

Effect of insulin and glucagon on the uptake of carnitine by perfused rat liver

The possible direct effects of insulin and glucagon on carnitine uptake by perfused rat liver were studied with L-[3H]carnitine of an initial concentration of 50 microM in the perfusate. Insulin (10 nM) did not significantly affect the uptake by livers from fed animals. However, insulin could reverse the stimulated transport by livers from 24-h fasted animals, reducing the uptake rate from 852 +/- 54.1 to 480 +/- 39.9 (mean +/- S.E.), P less than 0.01 (rates are expressed as nmol per h per 100 g body wt). Glucagon (50 nM) stimulated the uptake rate when livers were either from fed (551 +/- 40.1 vs. 915 +/- 55.3, P less than 0.01) or from fasted animals (852 +/- 54.1 vs. 1142 +/- 88.1, P less than 0.02). Based on these and earlier observations, we propose that the carnitine concentration in rat liver is controlled by insulin and glucagon via cellular transport processes.     

Gluconeogenesis predominates in periportal regions of the liver lobule

Rates of gluconeogenesis from lactate were calculated in periportal and pericentral regions of the liver lobule in perfused rat livers from increases in O2 uptake due to lactate. When lactate (0.1-2.0 mM) was infused into livers from fasted rats perfused in either anterograde or the retrograde direction, a good correlation (r = 0.97) between rates of glucose production and extra O2 uptake by the liver was observed as expected. Rates of oxygen uptake were determined subsequently in periportal and pericentral regions of the liver lobule by placing miniature oxygen electrodes on the liver surface and measuring the local change in oxygen concentration when the flow was stopped. Basal rates of oxygen uptake of 142 +/- 11 and 60 +/- 4 mumol X g-1 X h-1 were calculated for periportal and pericentral regions, respectively. Infusion of 2 mM lactate increased oxygen uptake by 71 mumol X g-1 X h-1 in periportal regions and by 29 mumol X g-1 X h-1 in pericentral areas of the liver lobule. Since the stoichiometry between glucose production and extra oxygen uptake is well-established, rates of glucose production in periportal and pericentral regions of the liver lobule were calculated from local changes in rates of oxygen uptake for the first time. Maximal rates of glucose production from lactate (2 mM) were 60 +/- 7 and 25 +/- 4 mumol X g-1 X h-1 in periportal and pericentral zones of the liver lobule, respectively. The lactate concentrations required for half-maximal glucose synthesis were similar (0.4-0.5 mM) in both regions of the liver lobule in the presence or absence of epinephrine (0.1 microM). In the presence of epinephrine, maximal rates of glucose production from lactate were 79 +/- 5 and 59 +/- 3 mumol X g-1 X h-1 in periportal and pericentral regions, respectively. Thus, gluconeogenesis from lactate predominates in periportal areas of the liver lobule during perfusion in the anterograde direction; however, the stimulation by added epinephrine was greatest in pericentral areas. Differences in local rates of glucose synthesis may be due to ATP availability, as a good correlation between basal rates of O2 uptake and rates of gluconeogenesis were observed in both regions of the liver lobule in the presence and absence of epinephrine. In marked contrast, when livers were perfused in the retrograde direction, glucose production was 28 +/- 5 mumol X g-1 X h-1 in periportal areas and 74 +/- 6 mumol X g-1 X h-1 in pericentral regions.(ABSTRACT TRUNCATED AT 400 WORDS)     

Acute inflammation increases selective uptake of HDL cholesteryl esters into adrenals of mice overexpressing human sPLA2

The acute-phase protein secretory phospholipase A2 (sPLA2) influences the metabolism of high-density lipoproteins (HDL). The adrenals are known to utilize HDL cholesterol as a source of sterols. The aim of the present study was to test the hypothesis that sPLA2 enhances the selective uptake of HDL into the adrenals in response to acute inflammation as a possible physiological role for the sPLA2-HDL interaction. Human sPLA2-transgenic mice, in which sPLA2 expression is upregulated by inflammatory stimuli, were used. Ten hours after induction of the acute-phase response (APR) by injection of bacterial lipopolysaccharide (LPS), plasma levels of HDL cholesterol decreased significantly in sPLA2-transgenic mice (-18%, P < 0.05) but remained unchanged in wild-type mice. The fractional catabolic rates of both 125I-labeled tyraminecellobiose (TC)-HDL and [3H]cholesteryl ether increased significantly in the sPLA2-transgenic mice after induction of the APR (0.18 +/- 0.01 vs. 0.21 +/- 0.01 pool/h, P < 0.05, and 0.31 +/- 0.02 vs. 0.42 +/- 0.05 pool/h, P < 0.05, respectively) but remained unchanged in the wild-type mice (0.10 +/- 0.01 vs. 0.22 +/- 0.02 pool/h, respectively). After induction of the APR, in both groups HDL holoparticle uptake by the liver was increased (P < 0.001). sPLA2-transgenic mice had 2.4-fold higher selective uptake into the adrenals after induction of the APR than wild-type mice (156 +/- 6 vs. 65 +/- 5%/ micro g tissue protein, P < 0.001). In summary, upregulation of sPLA2 expression during the APR specifically increases the selective uptake of HDL cholesteryl ester into the adrenals. These data suggest a novel metabolic role for sPLA2: modification of HDL during the APR to promote increased adrenal uptake of HDL cholesteryl ester to serve as source for steroid hormone synthesis.     

Turnover of 125I-VLDL and 131I-LDL apolipoprotein B in rabbits fed diets containing casein or soy protein

Rabbits fed low-fat, cholesterol-free, semi-purified diets containing casein developed a marked hypercholesterolemia compared to rabbits fed a similar diet containing soy protein (plasma cholesterol 281 +/- 31 vs. 86 +/- 9 mg/dl; P less than 0.05). Turnover studies (three per dietary group) were carried out in which homologous 125I-labeled VLDL and 131I-labeled LDL were injected simultaneously into casein- (n = 8) or soy protein- (n = 9) fed rabbits. ApoB-specific activities were determined in VLDL, IDL and LDL isolated from the pooled plasma of two or three rabbits per dietary group. The production rate of VLDL apoB (1.20 +/- 0.3 vs. 1.09 +/- 0.1 mg/h per kg) was similar for the two dietary groups. The fractional catabolic rate of VLDL apoB was lower for the casein group (0.15 +/- 0.03 vs. 0.23 +/- 0.01.h-1; 0.05 less than P less than 0.10). Although the pool size of VLDL apoB was higher in the casein group (8 +/- 2 vs. 5 +/- 0.3 mg/kg), this value did not reach statistical significance. For LDL apoB, the increased pool size in casein-fed rabbits (30 +/- 5 vs. 5 +/- 1 mg/kg; P less than 0.01) was associated with a decreased fractional catabolic rate (0.03 +/- 0.005 vs. 0.08 +/- 0.008.h-1; P less than 0.01) and a 2-fold increase in the production rate of LDL apoB (1 +/- 0.3 vs. 0.4 +/- 0.06 mg/kg per h; 0.05 less than P less than 0.10) compared to rabbits fed soy protein. Analysis of precursor-product relationships between the various lipoprotein fractions showed that casein-fed rabbits synthesized a higher proportion of LDL apoB (95% +/- 2 vs. 67% +/- 2; P less than 0.001) independent of VLDL catabolism. These results support the concept that the hypercholesterolemia in casein-fed rabbits is associated with impaired LDL removal consistent with a down-regulation of LDL receptors. These changes do not occur when the casein is replaced by soy protein.     

Regulation of the selective uptake of high density lipoprotein-associated cholesteryl esters

We have previously shown in rats that the cholesteryl ester component of high density lipoproteins (HDL) is taken up at a greater fractional rate than is the apolipoprotein A-I component (selective uptake) by liver and steroidogenic tissues. Selective uptake was also exhibited by cultured cells from these organs as well as by a wider range of cells in vitro (e.g., rat and human fibroblasts). We report here regulation of this pathway according to the cholesterol status of cells. Uptake of HDL cholesteryl esters by rat fibroblasts was decreased by prior loading of the cells with cholesterol, even while uptake of HDL-associated apoA-I actually increased. At high levels of cholesterol, the two were taken up about in parallel, i.e., selective uptake was suppressed. A similar regulation of selective uptake in primary rat hepatocytes in culture was not observed. To examine regulation of selective uptake in vivo, hypocholesterolemia was induced in rats using either 4-aminopyrazolo[3,4-d]pyrimidine or 17 alpha-ethinyl estradiol. Rat HDL, doubly labeled in both the apoprotein A-I and cholesteryl ester moieties with intracellularly trapped tracers, were injected into untreated and treated rats. The plasma decay kinetics and the tissue sites of uptake were then determined. Hypocholesterolemia increased the plasma fractional catabolic rates of both tracers. Selective uptake was observed in tissues of treated rats that did not exhibit selective uptake in untreated rats (muscle, adipose tissue, and skin). Similarly, hypocholesterolemia increased the contribution of selective uptake to total HDL cholesteryl ester uptake by adrenal and ovary. In contrast, regulation of selective uptake by liver could not be demonstrated under these conditions. Thus, selective uptake of HDL cholesteryl esters can be regulated in extrahepatic tissues of rats in vivo and in vitro, suggesting a role for selective uptake in the maintenance of cholesterol homeostasis in these tissues.     

Role of insulin in regulation of high density lipoprotein metabolism

The effect of alloxan-induced insulin deficiency on high density lipoprotein (HDL) metabolism was studied in rabbits. Rabbits with alloxan-induced diabetes had significantly higher (P less than 0.001, mean +/- SEM) plasma concentrations of glucose (541 +/- 13 vs. 130 +/- 2 mg/dl), triglyceride (2851 +/- 332 vs. 101 +/- 10 mg/dl), and total plasma cholesterol (228 +/- 55 vs. 42 +/- 4 mg/dl) than did normal control rabbits. However, diabetic rabbits had lower plasma HDL-cholesterol (7.2 +/- 1 vs. 51.3 +/- 1.3 mg/dl, P less than 0.001) and HDL apoA-I (38.3 +/- 6.0 vs. 87.2 +/- 4.3 mg/dl, P less than 0.001) concentrations. HDL kinetics were compared in diabetic and normal rabbits, using either 125I-labeled HDL or HDL labeled with 125I-labeled apoA-I, and it was demonstrated that HDL fractional catabolic rate (FCR) was slower and residence time was longer in the diabetic rabbits when either tracer was used. The slow FCR and the low apoA-I pool size led to reduced apoA-I/HDL synthetic rate in diabetic rabbits (0.97 +/- 0.11 vs. 0.34 +/- 0.07 mg per kg per hr). Thus, the reduced plasma HDL-cholesterol concentrations seen in rabbits with alloxan-induced insulin deficiency was associated with a lower total apoA-I/HDL synthetic rate. Since insulin treatment restored to normal all of the changes in plasma lipoprotein concentration and kinetics seen in diabetic rabbits, it is unlikely that the phenomena observed were secondary to a nonspecific toxic effect of alloxan. These data strongly support the view that insulin plays an important role in regulation of HDL metabolism.     

Characterization of high-density lipoprotein binding to rat adipocytes and adipocyte plasma membranes

The interaction of high-density lipoproteins (HDL) with adipocytes is important in the regulation of cellular cholesterol flux. To study the mechanisms of HDL binding and cellular processing, we incubated adipocytes isolated from epididymal and perirenal adipose tissue of male Wistar rats (300 g) with HDL1 (1.07-1.10 g/mL) and HDL2 (1.10-1.14 g/mL) fractions separated from rat plasma by gradient ultracentrifugation. Freshly isolated adipocytes were incubated with 125I-labeled HDL for 2 h at 37 degrees C to determine cell-associated uptake and degradation. Adipocytes from both fat regions showed significant cell-associated HDL1 and HDL2 uptake and very high medium degradation (2- to 6-fold higher than uptake). To assess 125I-labeled HDL binding independent of cellular metabolism, we purified adipocyte plasma membranes from isolated adipocytes and used them in binding assays. Binding of HDL1 and HDL2 in the membrane system was 85-95% specific, sensitive to high NaCl concentrations, and abolished by pronase treatment. In contrast to HDL2 binding, the maximum HDL1 binding to perirenal plasma membranes was significantly higher than its binding to epididymal membranes (7.2 +/- 1.3 vs. 4.4 +/- 0.2 micrograms/mg, n = 6, p less than 0.05). This increment in HDL1 binding to perirenal membranes represented an EDTA- sensitive, calcium-dependent component. These results indicate that HDL binding to adipocyte plasma membranes depends on both adipose tissue region and HDL subtype. The membrane binding characteristics, taken together with the cellular uptake results, suggest that adipocytes bind and metabolize HDL and that this interaction may involve a protein receptor.     

Dietary n-3 polyunsaturated fat increases the fractional catabolic rate of medium-sized HDL particles in African green monkeys

We have previously described a novel pathway for the metabolism of HDL subfractions in which small [2 apolipoprotein (apoA-I) molecules per particle] HDL particles are converted in a unidirectional manner outside the plasma compartment to medium (3 apoA-I molecules per particle) or large (4 apoA-I molecules per particle) HDL particles, which are subsequently removed from the circulation by the liver (Colvin et al. 1999. J. Lipid Res. 40: 1782;-1792; Huggins et al. 2000. J. Lipid Res. 41: 384;-394). The purpose of the present study was to determine whether the reduction in concentration of medium HDL in African green monkeys consuming n-3 polyunsaturated versus saturated fat diets resulted from decreased in vivo production or increased catabolism. Tracer small LpA-I (HDL containing only apoA-I) were isolated, without ultracentrifugation, by gel filtration and immunoaffinity chromatography and radiolabeled. After injection, the specific activity of apoA-I in small, medium, and large HDL was determined, and the kinetic data were analyzed using our previously published multicompartmental model for HDL subfraction metabolism. We found a significant reduction of apoA-I concentration in medium HDL in the animals fed n-3 polyunsaturated fat (31.2 +/- 0.7 mg/dl) compared with animals fed saturated fat (85.4 +/- 11.9 mg/dl; P = 0.002). The production rates of apoA-I in small, medium, and large HDL were similar in both diet groups; however, there was a significant increase in the fractional catabolic rate of apoA-I in medium HDL in the animals fed n-3 polyunsaturated fat (2.188 +/- 0.501 pools/day) compared with animals fed saturated fat (0.714 +/- 0.191 pools/day; P = 0.02).We conclude that n-3 polyunsaturated fat reduces HDL cholesterol concentration by increasing the fractional catabolic rate of medium-sized HDL particles in African green monkeys.     

Cholesteryl ester transfer protein corrects dysfunctional high density lipoproteins and reduces aortic atherosclerosis in lecithin cholesterol acyltransferase transgenic mice

Expression of human lecithin cholesterol acyltransferase (LCAT) in mice (LCAT-Tg) leads to increased high density lipoprotein (HDL) cholesterol levels but paradoxically, enhanced atherosclerosis. We have hypothesized that the absence of cholesteryl ester transfer protein (CETP) in LCAT-Tg mice facilitates the accumulation of dysfunctional HDL leading to impaired reverse cholesterol transport and the development of a pro-atherogenic state. To test this hypothesis we cross-bred LCAT-Tg with CETP-Tg mice. On both regular chow and high fat, high cholesterol diets, expression of CETP in LCAT-Tg mice reduced total cholesterol (-39% and -13%, respectively; p < 0.05), reflecting a decrease in HDL cholesterol levels. CETP normalized both the plasma clearance of [(3)H]cholesteryl esters ([(3)H]CE) from HDL (fractional catabolic rate in days(-1): LCAT-Tg = 3.7 +/- 0.34, LCATxCETP-Tg = 6.1 +/- 0.16, and controls = 6.4 +/- 0.16) as well as the liver uptake of [(3)H]CE from HDL (LCAT-Tg = 36%, LCATxCETP-Tg = 65%, and controls = 63%) in LCAT-Tg mice. On the pro-atherogenic diet the mean aortic lesion area was reduced by 41% in LCATxCETP-Tg (21.2 +/- 2.0 micrometer(2) x 10(3)) compared with LCAT-Tg mice (35.7 +/- 2.0 micrometer(2) x 10(3); p < 0.001). Adenovirus-mediated expression of scavenger receptor class B (SR-BI) failed to normalize the plasma clearance and liver uptake of [(3)H]CE from LCAT-Tg HDL. Thus, the ability of SR-BI to facilitate the selective uptake of CE from LCAT-Tg HDL is impaired, indicating a potential mechanism leading to impaired reverse cholesterol transport and atherosclerosis in these animals. We conclude that CETP expression reduces atherosclerosis in LCAT-Tg mice by restoring the functional properties of LCAT-Tg mouse HDL and promoting the hepatic uptake of HDL-CE. These findings provide definitive in vivo evidence supporting the proposed anti-atherogenic role of CETP in facilitating HDL-mediated reverse cholesterol transport and demonstrate that CETP expression is beneficial in pro-atherogenic states that result from impaired reverse cholesterol transport.     

High levels of human apolipoprotein A-I in transgenic mice result in increased plasma levels of small high density lipoprotein (HDL) particles comparable to human HDL3

Five lines of transgenic mice, which had integrated the human apolipoprotein (apo) A-I gene and various amounts of flanking sequences, were established. Normally, apoA-I is expressed mainly in liver and intestine, but all of the transgenic lines only expressed apoA-I mRNA in liver, strongly suggesting that 256 base pairs of 5'-flanking sequence was sufficient for liver apoA-I gene expression but that 5.5 kilobase pairs was not sufficient for intestinal expression. Mean plasma levels of human apoA-I varied in different lines from approximately 0.1 to 200% of normal mouse levels. This was not dependent on the amount of flanking sequence. Lipoprotein levels were studied in detail in one of the lines with a significantly increased apoA-I pool size. In one study, the total plasma apoA-I level (mouse plus human) was 381 +/- 43 mg/dl in six animals from this line, compared to 153 +/- 17 mg/dl in matched controls. Total and high density lipoprotein cholesterol (HDL-C) levels were increased 60% in transgenic animals, compared to controls (total cholesterol: 125 +/- 12 versus 78 +/- 13 mg/dl, p = 0.0001; HDL-C 90 +/- 7 versus 55 +/- 11 mg/dl, p = 0.0001). The molar ratio of HDL-C/apoA-I was significantly lower in transgenic animals, 17 +/- 1 versus 25 +/- 2 (p = 0.0001), suggesting the increase was in smaller HDL particles. This was confirmed by native gradient gel electrophoresis. This was not due to aberrant metabolism of human apoA-I in the mouse, since human apoA-I was distributed throughout the HDL particle size range and was catabolized at the same rate as mouse apoA-I. In another study of 23 transgenic mice, HDL-C and human apoA-I levels were highly correlated (r = 0.87, p less than 0.001). The slope of the correlation line also indicated the additional HDL particles were in the smaller size range. We conclude that human apoA-I can be incorporated into mouse HDL, and excessive amounts increase HDL-C levels primarily by increasing smaller HDL particles, comparable to human HDL3 (HDL-C/apoA-I molar ratio = 18).