Receptor-dependent and receptor-independent degradation of low density lipoprotein in normal rabbits and in receptor-deficient mutant rabbits

Low density lipoprotein (LDL) catabolism was studied using WHHL rabbits, an inbred strain deficient in LDL receptor activity and, thus, an animal model for homozygous familial hypercholesterolemia. WHHL and normal rabbits were injected with [14C]sucrose-LDL and the tissue sites of LDL degradation were determined 24 h later. On degradation of [14C]sucrose-LDL, the [14C]sucrose ligand remains trapped within tissues as a cumulative measure of degradation. The fractional catabolic rate of [14C]sucrose-LDL in Watanabe heritable hyperlipidemic (WHHL) rabbits was reduced (0.024 +/- 0.010 versus 0.063 +/- 0.026 h-1) but, by virtue of the increased plasma pool, total LDL flux was increased (33.5 +/- 9.6 versus 10.6 +/- 4.4 mg of LDL protein/kg/day). Liver was the predominant site of catabolism in both WHHL and normal rabbits (52.7 +/- 6.9 and 56.6 +/- 6.2% of total degradation). About 90% of hepatic catabolism was attributable to parenchymal cells in both cases. Thus, Kupffer cells, a major component of the reticuloendothelial system, do not play a major role in LDL catabolism in WHHL rabbits. Despite receptor deficiency, the relative contribution of various tissues to overall LDL degradation was not greatly altered and the absolute rate of delivery of LDL to all tissues was increased with the exception of the adrenal. Thus, there was no evidence that the increased degradation occurred in any special subset of "scavenger" cells. Nevertheless, local scavenger cell uptake may be critically important, especially in atherogenesis. If it is assumed that receptor-independent degradation occurs at the same rate in the tissues of WHHL and normal rabbits and that catabolism in the absence of receptors is a linear function of concentration, then one can estimate the fraction of uptake in normal tissues mediated by receptors. The difference in the fraction of the plasma LDL pool cleared per unit of time in normal and WHHL rabbits would reflect the contribution of receptors to fractional clearance. By this calculation, receptor-mediated degradation in normal rabbits was 62% overall, 63% in liver, 92% in adrenal, and 83% in gut.     

Measurement of receptor-independent metabolism of low-density lipoprotein. An application of glycosylated low-density lipoprotein

Incubation of human low-density lipoprotein (LDL) with glucose results in a nonenzymatic formation of a Schiff base between the monosaccharide and lysyl residues of apolipoprotein B. Increasing the percentage of lysyl residues of apolipoprotein B modified by glycosylation decreases the fractional catabolic rate of the glycosylated LDL, and decreases the metabolism of the glycosylated LDL by human skin fibroblasts. The glycosylated LDL, containing 20-40% of total lysyl residues of apoprotein B modified, was metabolized at a slow rate by both human skin fibroblasts and mouse peritoneal macrophages. These results led to the suggestion that glycosylated LDL is primarily catabolized via a receptor-independent process. Assuming LDL catabolism occurs via receptor-dependent and receptor-independent processes, the ratio of (fractional catabolic rate of glycosylated LDL)/(fractional catabolic rate of native LDL) should be an estimate of the percentage of LDL catabolism via the receptor-independent process. From the fractional catabolic rates of glucose-LDL (20-40% of lysyl residues modified) and galactose-LDL (30-60% of lysyl residues modified) 41% and 30% respectively, of LDL catabolism occurred by a receptor-independent process.     

Radiolabeled sucrose covalently linked to protein. A device for quantifying degradation of plasma proteins catabolized by lysosomal mechanisms.

A general method is described for assessing the degradation of proteins metabolized by lysosomal mechanisms. The method depends on the lysosomal trapping of sucrose which is covalently bound to the protein of interest and thus caried into the lysosome with it. The validity of the method was demonstrated in vitro in studies of the catabolism of low density lipoprotein (LDL) by cultured fibroblasts. Sucrose-derivatized LDL was not distinguished from 125I-LDL by fibroblasts, either in terms of surface binding or rate of uptake. 14C from [14C]sucrose-LDL accumulated in the cells as predicted; very little appeared in the trichloroacetic acid-soluble fraction of the medium (2% of total uptake). 14C-labeled metabolites in the cells (modal apparent Mr = 1000-2000) were separated from undegraded LDL by gel filtration. LDL degradation calculated from the 14C metabolites accumulating intracellularly was in excellent agreement with that calculated from paired studies using 125I-LDL. Finally, the validity of the method was demonstrated in vivo using asialofetuin, a protein previously shown to be selectively taken up and degraded by the liver. In principle, the method described should be applicable to the study of the sites of degradation of any of the plasma proteins.     

In vivo clearance of low density lipoprotein in pigeons occurs by a receptor-like mechanism that is not down-regulated by cholesterol feeding

The contribution of receptor-dependent and receptor-independent mechanisms for low density lipoprotein (LDL) clearance in vivo was determined in White Carneau and Show Racer pigeons fed either cholesterol free or cholesterol containing diets. The methylation of pigeon LDL resulted in the inhibition of recognition by the LDL receptor which allowed its use as a tracer of receptor-independent clearance. The fractional catabolic rate (FCR) of radiolabeled LDL in 20 control pigeons (means +/- S.E., 0.277 +/- 0.013 pools/h) was approximately seven times faster than for methylated LDL indicating that 86% of the total LDL clearance occurred by a receptor-mediated process. Total LDL clearance was reduced by 27% (FCR = 0.202 +/- 0.012 pools/h) in 14 cholesterol-fed pigeons, but receptor-mediated mechanisms were still responsible for 80% of the total LDL clearance. LDL uptake by individual tissues was measured using the residualizing label 125I-tyramine cellobiose. The liver was the primary site of LDL clearance in both control and cholesterol-fed birds. LDL receptors were active in every tissue examined and accounted for over 85% of the LDL clearance in the liver and over 90% in the adrenal gland. Consistent with the whole body LDL clearance findings, cholesterol-feeding did not significantly reduce receptor-mediated clearance of 125I-tyramine cellobiose-LDL by the liver or any of the other tissues. Hepatic sterol synthesis, however, was reduced by greater than 90% in cholesterol-fed animals. These data are consistent with the conclusion that LDL clearance in vivo in pigeons is mediated primarily by an LDL receptor-like mechanism that shows little down-regulation with hypercholesterolemia even though cholesterol synthesis is efficiently down-regulated.     

Rates of cholesterol synthesis and low-density lipoprotein uptake in the adrenal glands of the rat, hamster and rabbit in vivo

The absolute rate of cholesterol acquisition from de novo synthesis and from receptor-dependent and receptor-independent low-density lipoprotein (LDL) uptake was determined in the adrenal glands of the rat, hamster and rabbit under in vivo conditions. The rate of incorporation of [3H]water into cholesterol in the adrenal gland was much higher in the hamster (1727 nmol/h per g) and rabbit (853 nmol/h per g) than in the rat (71 nmol/h per g). Assuming that 23 atoms of 3H are incorporated into the cholesterol molecule during its biosynthesis, the absolute rates of cholesterol synthesis were then calculated to equal 59, 29 and 2.4 micrograms/h per g of adrenal gland in the hamster, rabbit and rat, respectively. Rates of LDL-cholesterol uptake were measured using a primed continuous infusion of [14C]sucrose-labeled homologous LDL (total LDL transport) and methylated human LDL (receptor-independent LDL transport). The rate of total LDL-cholesterol uptake in the adrenal gland was much higher in the rabbit (227 micrograms/h per g) than in the rat (18 micrograms/h per g) or hamster (6 micrograms/h per g). In all three species LDL uptake was mediated largely (greater than 93%) by receptor-dependent mechanisms. In terms of total cholesterol acquisition, the hamster adrenal gland derived 10-times more cholesterol from de novo synthesis than from LDL uptake, whereas the converse was true in the rabbit. Rates of de novo synthesis and LDL-cholesterol uptake were both low in the rat adrenal gland, which is known to derive cholesterol mainly from circulating high-density lipoproteins. Thus, the adrenal gland acquires cholesterol for hormone synthesis from at least three different sources and the quantitative importance of these sources varies markedly in different animal species, including man.     

Plasma kinetics of a cholesterol-rich emulsion in subjects with or without coronary artery disease

A cholesterol-rich emulsion (LDE) that resembles the LDL lipidic structure is taken-up by LDL receptors after intravenous injection by means of apolipoprotein E it acquires in the circulation and can be used to probe LDL metabolism. In this study, LDE was labeled with [14C]cholesteryl oleate and [3H]cholesterol and injected into 19 patients with coronary artery disease (CAD) and into 14 subjects without CAD to verify whether the kinetic behavior of the radioactive lipids is different in CAD. Blood was sampled over 24 h for radioactivity measurement after lipid extraction and separation by thin-layer chromatography. Fractional clearance rate (FCR, in h-1) of [14C]cholesteryl ester was not different in CAD and nonCAD expressed as median (25%; 75%): 0.08 (0.062; 0.134) h-1 versus 0.06 (0.04; 0.083) h-1, P = 0.167. However, [3H]cholesterol FCR was greater in CAD than in nonCAD (mean +/- SEM): 0.163 +/- 0.016 h-1 versus 0.077 +/- 0.014 h-1, P < 0.001. Esterification of the LDE [3H]cholesterol was also greater in CAD subjects than nonCAD at 10 h and 24 h after emulsion injection (P = 0.029 and 0.024 respectively). In conclusion, both removal from the plasma and esterification of the LDE-cholesterol were increased in CAD. These findings may contribute for unraveling pro-atherogenic mechanisms and the establishment of novel CAD markers.     

Quantitative role of parenchymal and non-parenchymal liver cells in the uptake of [14C]sucrose-labelled low-density lipoprotein in vivo.

In order to assess the relative importance of the receptor for low-density lipoprotein (LDL) (apo-B,E receptor) in the various liver cell types for the catabolism of lipoproteins in vivo, human LDL was labelled with [14C]sucrose. Up to 4.5h after intravenous injection, [14C]sucrose becomes associated with liver almost linearly with time. During this time the liver is responsible for 70-80% of the removal of LDL from blood. A comparison of the uptake of [14C]sucrose-labelled LDL and reductive-methylated [14C]sucrose-labelled LDL ([14C]sucrose-labelled Me-LDL) by the liver shows that methylation leads to a 65% decrease of the LDL uptake. This indicated that 65% of the LDL uptake by liver is mediated by a specific apo-B,E receptor. Parenchymal and non-parenchymal liver cells were isolated at various times after intravenous injection of [14C]sucrose-labelled LDL and [14C]sucrose-labelled Me-LDL. Non-parenchymal liver cells accumulate at least 60 times as much [14C]sucrose-labelled LDL than do parenchymal cells accumulate at least 60 times as much [14C]sucrose-labelled LDL than do parenchymal cells when expressed per mg of cell protein. This factor is independent of the time after injection of LDL. Taking into account the relative protein contribution of the various liver cell types to the total liver, it can be calculated that non-parenchymal cells are responsible for 71% of the total liver uptake of [14C]sucrose-labelled LDL. A comparison of the cellular uptake of [14C]sucrose-labelled LDL and [14C]sucrose-labelled Me-LDL after 4.5h circulation indicates that 79% of the uptake of LDL by non-parenchymal cells is receptor-dependent. With parenchymal cells no significant difference in uptake between [14C]sucrose-labelled LDL and [14C]sucrose-labelled Me-LDL was found. A further separation of the nonparenchymal cells into Kupffer and endothelial cells by centrifugal elutriation shows that within the non-parenchymal-cell preparation solely the Kupffer cells are responsible for the receptor-dependent uptake of LDL. It is concluded that in rats the Kupffer cell is the main cell type responsible for the receptor-dependent catabolism of lipoproteins containing only apolipoprotein B.     

Abnormal in vivo metabolism of apoB-containing lipoproteins in human apoE deficiency

The present study was undertaken to elucidate the metabolic basis for the increased remnants and lipoprotein(a) [Lp(a)] and decreased LDL apolipoprotein B (apoB) levels in human apoE deficiency. A primed constant infusion of (13)C(6)-phenylalanine was administered to a homozygous apoE-deficient subject. apoB-100 and apoB-48 were isolated, and tracer enrichments were determined by gas chromatography-mass spectrometry, then kinetic parameters were calculated by multicompartmental modeling. In the apoE-deficient subject, fractional catabolic rates (FCRs) of apoB-100 in VLDL and intermediate density lipoprotein and apoB-48 in VLDL were 3x, 12x, and 12x slower than those of controls. On the other hand, the LDL apoB-100 FCR was increased by 2.6x. The production rate of VLDL apoB-100 was decreased by 45%. In the Lp(a) kinetic study, two types of Lp(a) were isolated from plasma with apoE deficiency: buoyant and normal Lp(a). (125)I-buoyant Lp(a) was catabolized at a slower rate in the patient. However, (125)I-buoyant Lp(a) was catabolized at twice as fast as (131)I-normal Lp(a) in the control subjects. In summary, apoE deficiency results in: 1) a markedly impaired catabolism of VLDL/chylomicron and their remnants due to lack of direct removal and impaired lipolysis; 2) an increased rate of catabolism of LDL apoB-100, likely due to upregulation of LDL receptor activity; 3) reduced VLDL apoB production; and 4) a delayed catabolism of a portion of Lp(a).     

Impaired hepatocyte binding, uptake and degradation of glucosylated low-density lipoproteins

The catabolism of low-density lipoproteins (LDL), the major cholesterol-carrying lipoproteins in plasma, is mediated in part via a high-affinity uptake pathway in the liver. Non-enzymatic glucosylation of lysine residues of apolipoprotein B, the major protein of LDL, blocks receptor-mediated uptake of LDL by fibroblasts and endothelial cells. We investigated the effect of the degree of glucosylation on the binding, uptake and degradation of radioiodinated LDL by the human hepatoma cell line Hep G2. Human LDL was glucosylated with 250 mM glucose and 30 mM cyanoborohydride at 37 degrees C. Incubations ranging from 3 to 48 h in duration resulted in the formation of 6-27% of glucitol-lysine adducts as demonstrated by coincubation with [14C]glucose. The degree of glucose incorporation corresponded to the extent of inhibition of binding, uptake and degradation of LDL (10-90%). The data are consistent with the view that glucosylation of LDL markedly impairs their catabolism. This phenomenon may be related to the pathophysiology of the premature atherosclerosis observed in diabetes mellitus.     

Role of the reticuloendothelial system in the catabolism of low density lipoprotein in the rat

The role of the reticuloendothelial system (RES) in receptor-independent catabolism of human low density lipoprotein (h-LDL) was evaluated in the rat in vivo after blockade of its phagocytic activity with gadolinium chloride (GaCl3). After blockade of the RES with GaCl3, the recovery of [125I] h-LDL in the liver of 17 alpha-ethinyl oestradiol-treated rats (EE-rats), was decreased by 37 and 16%, 15 and 60 min after h-LDL injection, respectively. This decrease did not result in a decreased LDL degradation which represented 14 and 55% of the injected dose in the two groups of rats after 15 and 60 min respectively, both on GaCl3 and control rats. Contrasting with EE-rats, the catabolism of h-LDL in untreated rats is much slower and takes place essentially through a receptor-independent mechanism. Six hours after the injection of [125I] h-LDL, 64% of the dose was degraded. This proportion decreased to 45% after blockade of the RES phagocytic activity. This 30 percent difference represents the proportion of h-LDL catabolized by receptor-independent mechanisms present in the Küpffer and endothelial cells. We conclude from our study that in the normal rat, the parenchymal cells of the liver on the one hand and the Küpffer and endothelial cells on the other hand contribute 70 and 30% respectively to the receptor-independent catabolism of low density lipoproteins in vivo.     

Modulation of low density lipoprotein receptor activity by bile acids: differential effects of chenodeoxycholic and ursodeoxycholic acids in the hamster

Hamsters were fed chenodeoxycholic acid (CDC), ursodeoxycholic acid, (UDC), or no bile acid. [14C]Sucrose-labeled hamster low density lipoprotein (LDL) and methylated human LDL were infused intravenously to study LDL receptor-dependent and LDL receptor-independent organ uptake, respectively, of LDL. Biliary CDC increased during both CDC and UDC treatment. The UDC enrichment of bile after UDC feeding was relatively small. Bile acid synthesis was suppressed after both bile acid treatments. Under the condition of an acute bile fistula, the hamster LDL uptake increased in the liver, heart, and adrenals in the CDC-treated animals. During an intact enterohepatic circulation, the hepatic uptake of hamster LDL, which accounted for a major portion of the total uptake, was increased after UDC treatment. The hamster LDL uptake in the colon, which represented only a small fraction of the total uptake, increased after CDC treatment. When hamster LDL was infused at increasing concentrations, its uptake was significantly higher in the UDC-treated than in the control and CDC-treated animals. The methylated human LDL uptake showed no significant changes in the different treatment groups under either experimental condition. The study shows significantly different effects of CDC and UDC on LDL receptor activity. Since these differences are expressed in spite of a similar suppression of bile acid synthesis, UDC may directly influence LDL receptor activity.     

Binding, internalization, and degradation of high density lipoprotein by cultured normal human fibroblasts.

Comparative studies were made of the metabolism of plasma high density lipoprotein (HDL) and low density lipoprotein (LDL) by cultured normal human fibroblasts. On a molar basis, the surface binding of (125)I-HDL was only slightly less than that of (125)I-LDL, whereas the rates of internalization and degradation of (125)I-HDL were very low relative to those of (125)I-LDL. The relationships of internalization and degradation to binding suggested the presence of a saturable uptake mechanism for LDL functionally related to high-affinity binding. This was confirmed by the finding that the total uptake of (125)I-LDL (internalized plus degraded) at 5 micro g LDL protein/ml was 100-fold greater than that attributable to fluid or bulk pinocytosis, quantified with [(14)C]sucrose, and 10-fold greater than that attributable to the sum of fluid endocytosis and adsorptive endocytosis. In contrast, (125)I-HDL uptake could be almost completely accounted for by the uptake of medium during pinocytosis and by invagination of surface membrane (bearing bound lipoprotein) during pinocytosis. These findings imply that, at most, only a small fraction of bound HDL binds to the high-affinity LDL receptor and/or that HDL binding there is internalized very slowly. The rate of (125)I-HDL degradation by cultured fibroblasts (per unit cell mass) exceeded an estimate of the turnover rate of HDL in vivo, suggesting that peripheral tissues may contribute to HDL catabolism. In accordance with their differing rates of uptake and cholesterol content, LDL increased the cholesterol content of fibroblasts and selectively inhibited sterol biosynthesis, whereas HDL had neither effect.     

In vivo clearance of low-density lipoproteins and beta-very-low-density lipoproteins in normal and hypercholesterolemic White Carneau pigeons

Low-density lipoproteins (hLDL) and beta-migrating-very-low-density lipoproteins (beta-VLDL) were isolated from the plasma of cholesterol-fed White Carneau (WC) pigeons and low-density lipoproteins (nLDL) were isolated from the plasma of grain-fed WC pigeons. The lipoproteins were radiolabeled with 125I or 131I and injected into normocholesterolemic or hypercholesterolemic WC pigeons to determine their rate of clearance from the plasma. The fractional catabolic rate (FCR) of nLDL and hLDL in normocholesterolemic pigeons averaged 0.202 and 0.206 pools/h.respectively. beta-VLDL was cleared at a significantly slower rate of 0.155 pools/h. The FCR of the same lipoproteins injected into hypercholesterolemic pigeons was reduced by 17% for nLDL, 50% for hLDL and 57% for beta-VLDL, indicating that the effect of hypercholesterolemia on clearance in vivo was different for the three lipoproteins. The FCR of reductively methylated pigeon LDL (MeLDL), which gives a measure of receptor-independent clearance of LDL, was shown previously to be 0.037 pools/h. These studies suggest therefore that LDL and beta-VLDL are cleared from the plasma of normocholesterolemic and hypercholesterolemic pigeons at a rate substantially greater than that predicted for non-specific processes. Despite the reduction in the clearance rate of hLDL and beta-VLDL due to cholesterol feeding, the absolute amount of cholesterol that was cleared from the plasma by these lipoproteins was increased from approx. 200 mg/kg body weight per day in the normocholesterolemic pigeons to greater than 1000 mg/kg body weight per day in the hypercholesterolemic pigeons. This is due principally to the enrichment in cholesterol relative to protein of the lipoproteins isolated from cholesterol-fed pigeons and the failure of hypercholesterolemia to completely inhibit receptor-dependent clearance of LDL and beta-VLDL. The lower rate of clearance of beta-VLDL relative to LDL is in marked contrast to mammalian beta-VLDL, which is cleared much faster than LDL, but is consistent with the lack of apo E on pigeon lipoproteins. Apo E is the apoprotein that is thought to be responsible for the rapid clearance of beta-VLDL in normocholesterolemic mammals. The low rate of beta-VLDL clearance in pigeons also suggests that pigeons lack an apolipoprotein that function like mammalian apo E.     

14C-labeled substrate catabolism by human diploid fibroblasts derived from infants and adults

Untransformed diploid skin fibroblasts from eight normal adults, aged 24 to 74 years, catabolized several 14C-labeled substrates less effectively than cells from ten normal male infants. 14C-labeled substrate metabolism was quantitated either by measuring the evolution of 14CO2 from the 14C-labeled compounds or the incorporation of 14C into cellular protein via transamination of tricarboxylic acid cycle intermediates derived from the 14C-labeled substrates. With these methods, adult cells catabolized [1-14C]butyrate, [1-14C]octanoate, and 1-[2-14C]leucine at rates 44 to 64% of those found in infant cells. The oxidation of [1,4-14C]succinate and [U-14C]malate was identical in both infant and adult cells, while [2,3-14C]succinate catabolism was mildly decreased in adult cells (65-80% of control). These observations parallel those made in rat tissues and confirm that the same phenomenon occurs in cultured human fibroblasts.     

Uptake and metabolism of lactosylceramide on low density lipoproteins in cultured proximal tubular cells from normal and familial hypercholesterolemic homozygotes

The metabolism of low density lipoproteins (LDL), and LDL modified by reductive methylation (M-LDL) of lysine residues, was studied in proximal tubular (PT) cells both from normal human kidney and from urine of patients with homozygous (LDL receptor-negative) familial hypercholesterolemia (FH). LDL and M-LDL was labeled either in the protein moiety with 125I or in the lactosylceramide moiety with 3H. The binding and degradation of 125I-LDL in normal cells was saturable and displaced by unlabeled LDL but not by M-LDL. The uptake of [3H]lactosylceramide (LacCer) low density lipoprotein in normal renal cells was saturable, and time and temperature-dependent. Exogenously derived [3H]LacCer on LDL was rapidly taken up and catabolized to monoglycosylceramide, or it was utilized for the endogenous synthesis of globotriaosylceramide (trihexosylceramide) and globotetraosylceramide (tetraglycosylceramide). [3H]LacCer M-LDL was taken up less avidly and metabolized less extensively than [3H]LacCer-LDL in normal cells. In homozygous FH renal cells the binding of 125I-LDL was not saturable and not displaced by unlabeled LDL. 125I-LDL degradation did not occur in FH cells. The homozygous FH PT cells took up a 2-fold greater amount of exogenously derived [3H]LacCer on LDL than normal cells. Yet, most of the [3H]LacCer taken up by FH PT cells accumulated as LacCer, and only small amounts were metabolized to monoglycosylceramide, globotriaosylceramide (trihexosylceramide), or globotetraosylceramide (tetraglycosylceramide). When normal and FH PT cells were preincubated with LDL (0-100 micrograms/ml medium), there was a 5-fold increase in cellular LacCer levels in FH cells at saturating levels of LDL, whereas there was about a 50% decrease in LacCer levels in normal cells. While the high affinity binding of LDL was not essential for the delivery of LacCer to cells, the data support the conclusion that LDL binding to the LDL receptor facilitates further LacCer processing and metabolism in normal renal cells. We speculate that [3H] LacCer is taken up by FH homozygous cells via a LDL receptor-independent mechanism and accumulates in the cells without significant metabolism. LacCer taken up by this mechanism contributes to the storage of LacCer in FH PT cells.     

Mechanisms by which lipoprotein lipase alters cellular metabolism of lipoprotein(a), low density lipoprotein, and nascent lipoproteins. Roles for low density lipoprotein receptors and heparan sulfate proteoglycans.

We sought to investigate effects of lipoprotein lipase (LpL) on cellular catabolism of lipoproteins rich in apolipoprotein B-100. LpL increased cellular degradation of lipoprotein(a) (Lp(a)) and low density lipoprotein (LDL) by 277% +/- 3.8% and 32.5% +/- 4.1%, respectively, and cell association by 509% +/- 8.7% and 83.9% +/- 4.0%. The enhanced degradation was entirely lysosomal. Enhanced degradation of Lp(a) had at least two components, one LDL receptor-dependent and unaffected by heparitinase digestion of the cells, and the other LDL receptor-independent and heparitinase-sensitive. The effect of LpL on LDL degradation was entirely LDL receptor-independent, heparitinase-sensitive, and essentially absent from mutant Chinese hamster ovary cells that lack cell surface heparan sulfate proteoglycans. Enhanced cell association of Lp(a) and LDL was largely LDL receptor-independent and heparitinase-sensitive. The ability of LpL to reduce net secretion of apolipoprotein B-100 by HepG2 cells by enhancing cellular reuptake of nascent lipoproteins was also LDL receptor-independent and heparitinase-sensitive. None of these effects on Lp(a), LDL, or nascent lipoproteins required LpL enzymatic activity. We conclude that LpL promotes binding of apolipoprotein B-100-rich lipoproteins to cell surface heparan sulfate proteoglycans. LpL also enhanced the otherwise weak binding of Lp(a) to LDL receptors. The heparan sulfate proteoglycan pathway represents a novel catabolic mechanism that may allow substantial cellular and interstitial accumulation of cholesteryl ester-rich lipoproteins, independent of feedback inhibition by cellular sterol content.     

Cerebral low-density lipoprotein (LDL) uptake is stimulated by acute bile drainage

Although the cholesterol pool in the central nervous system is considered to be relatively stable, few studies have tested this assumption. The aim of the study was to gain further information on the communication between the extracerebral organs and the brain as far as cholesterol and lipoprotein transport are concerned. Receptor-dependent as well as receptor-independent LDL uptake in the brain were measured, by established methods, after constant 1-h intravenous infusions of [14C]sucrose-labelled hamster LDL and methylated human LDL, both in hamsters with an acute bile fistula and in control animals with an intact enterohepatic circulation. The receptor-dependent LDL uptake in the brain promptly showed a significant increase after the construction of the bile fistula. However, there was no difference in the receptor-independent LDL uptake between the bile fistula and control animals. The studies indicate the presence of close communications between extracerebral and brain cholesterol. Changes in the extracerebral compartments of cholesterol are, apparently, readily sensed by the LDL receptor in the brain and promptly evoke appropriate modifications in its activity.     

Mechanisms subserving the steroidogenic synergism between follicle-stimulating hormone and insulin-like growth factor I (somatomedin C). Alterations in cellular sterol metabolism in swine granulosa cells

Swine granulosa cells respond to follicle-stimulating hormone (FSH) and the insulin-like growth factor, IGF-I (somatomedin C), with synergistic increases in progesterone production. This facilitative interaction was not attributable to decreased catabolism of progesterone to 20 alpha-hydroxypregn-4-en-3-one, but rather to enhanced pregnenolone biosynthesis observed in response to provision of 25-hydroxycholesterol as exogenous sterol substrate. The latter evidence of increased functional cholesterol side-chain cleavage activity was accompanied by augmented incorporation of [35S]methionine into specific immunoisolated components of the cholesterol side-chain cleavage apparatus, viz. cytochrome P-450scc and adrenodoxin. The synergism between FSH and IGF-I could be sustained over 4 days of serum-free monolayer culture. Under these conditions, compactin, a competitive inhibitor of de novo endogenous cholesterol biosynthesis, suppressed stimulated progesterone production by approximately equal to 50%. However, synergism was not expressed at the levels of [14C]acetate incorporation into nonsaponifiable lipids or endogenous 3-hydroxy-3-methylglutaryl coenzyme A reductase activity per se. Conversely, exogenous sterol substrate provided in the form of low-density lipoprotein (LDL)-borne cholesterol increased the absolute magnitude of the combined actions of IGF-I and FSH by 3-6-fold. This increase in steroidogenesis in response to LDL was associated with enhanced surface binding, internalization, and degradation of [125I] iodo-LDL. In addition, when granulosa cells were incubated with [3H]cholesteryl linoleate-labeled LDL, FSH and IGF-I synergistically augmented the intracellular accumulation of [3H]cholesterol and [3H]cholesteryl ester and the production of [3H]progesterone. Moreover, FSH and IGF-I coordinately increased the total mass of free and esterified cholesterol contained in granulosa cells. We conclude that FSH and IGF-I can augment absolute rates of progestin biosynthesis by granulosa cells by activating dual mechanisms: stimulation of functional cholesterol side chain cleavage activity and enhancement of effective cellular uptake and utilization of low-density lipoprotein-borne sterol substrate.     

Anaerobic degradation of pteridines and purines by intestinal organisms.

Microorganisms located within rat cecal contents degraded or catabolized [2-14C]pteridines and [2-14C]purines under anaerobic conditions, resulting in the release of 14CO2. A saturating concentration of guanosine did not affect the rate of release of CO2 from biopterin, and, likewise, the presence of a saturating level of biopterin did not significantly alter the release of CO2 from guanosine, indicating that the catabolism of these two compounds was by different systems. Part of the catabolic organisms for guanosine were segregated in a culture dilution experiment. These catabolic activities were detected in feces of humans and various other mammals. The results are compared with previously published data on the degradation of pteridines and purines.     

Glycosylation of LDL decreases its ability to interact with high-affinity receptors of human fibroblasts in vitro and decreases its clearance from rabbit plasma in vivo

Incubation of human LDL in vitro at 37 degrees C for 48 h with [14C]glucose at concentrations from 5 to 200 mM resulted in a glycosylated LDL, containing 0.4-20 mol of glucose incorporated per apolipoprotein B of 250 000 daltons. The extent of glucose incorporated was proportional to the time of incubation and concentration of glucose. Glycosylation of LDL abolished its uptake and degradation by the high-affinity process for LDL in normal human skin fibroblasts. 125I-labeled glycosylated LDL was bound, internalized and degraded by the fibroblasts via a nonspecific low-affinity process. The 125I-labeled glycosylated LDL and 125I-labeled LDL were taken up and degraded at similar rates in a non-saturable, low-affinity process by peritoneal macrophages isolated from mice. When 125I-labeled glycosylated LDL or 125I-labeled LDL were injected into rabbits, the glycosylated LDL had a delayed plasma clearance in comparison to the LDL. The mean fractional catabolic rates were 0.67 day-1 and 1.70 day-1 for 125I-labeled glycosylated LDL and 125I-labeled LDL, respectively. The uptake and degradation of 125I-labeled LDL by human skin fibroblasts was decreased as the concentration of free carbohydrate, glucose, sucrose or sorbitol, in the medium was increased from 10 mM to 1 M. It is speculated that pathologic levels of plasma glucose in vivo could result in a decrease in LDL uptake as a result of glycosylation of LDL. A decrease in uptake of native or modified LDL in vivo could contribute to hypercholesterolemia and its pathophysiology.