Stimulation of the in Vivo Production of Very Low Density Lipoproteins by Apolipoprotein E Is Independent of the Presence of the Low Density Lipoprotein Receptor

doi:10.1074/jbc.M106396200

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Stimulation of the in Vivo Production of Very Low Density Lipoproteins by Apolipoprotein E Is Independent of the Presence of the Low Density Lipoprotein Receptor^*

Bas Teusink^§, Arjen R. Mensenkamp^¶, Hans van der Boom, Folkert Kuipers^¶, Ko Willems van Dijk, and Louis M. Havekes^**

From the TNO Prevention and Health, Gaubius Laboratory, NL-2301 CE Leiden, The Netherlands, ^¶ Center for Liver, Digestive and Metabolic Diseases, Laboratory of Pediatrics, University Hospital Groningen, 9713 GZ Groningen, The Netherlands, and Departments of Human and Clinical Genetics, ^** Cardiology, and Internal Medicine, Leiden University Medical Center, 2300 RA Leiden, The Netherlands

Received for publication, July 9, 2001, and in revised form, August 9, 2001

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Apolipoprotein (apo) E stimulates the secretion of very low density lipoproteins (VLDLs) by an as yet unknown mechanism. Recently,a working mechanism for apoE was proposed (Twisk, J., Gillian-Daniel,D. L., Tebon, A., Wang, L., Barrett, P. H., and Attie, A. D. (2000)J. Clin. Invest. 105, 521-532) in which apoE prevents the inhibitoryaction of the low density lipoprotein receptor (LDLr) by bindingto it. We have first tested whether this newly described effectof the LDLr on VLDL secretion, obtained in vitro, is also observedin vivo. In LDLr knockout mice (LDLr $-$ / $-$ ), the production of VLDLtriglycerides and apoB was 30% higher than that in controls. Alsothe ratio of apoB100:apoB48 secretion was increased in the LDLr $-$ / $-$ mice. The composition of nascent VLDL was similar in both strains.To test whether the action of apoE depends on the presence ofthe LDLr, VLDL production was measured in LDLr $-$ / $-$ and apoE $-$ / $-$ LDLr $-$ / $-$ mice. Deletion of apoE on a LDLr $-$ / $-$ background still causeda 50% decrease of VLDL triglycerides and apoB production. Thecomposition of nascent VLDL was again similar for both strains.We conclude that the effect of apoE on hepatic VLDL productionis independent of the presence of the LDLr.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Apolipoprotein (apo)¹ E is a 34.2-kDa protein that acts as a ligand for receptor-mediated endocytosis of lipoproteins (1).The role of apoE in lipoprotein metabolism is not confined, however,to the clearance of lipoprotein particles from the circulation.ApoE inhibits lipolysis of lipoproteins by lipoprotein lipase(2, 3). More recently, it was demonstrated that apoE alsoaffects the hepatic secretion of very low density lipoproteins(VLDLs): apoE-deficient (apoE $-$ / $-$ ) mice showed a reduction in VLDLsecretion by some 50% (4), whereas adenoviral gene transferof human apoE3 led to a gene dose-dependent increase in VLDL production(5). Similar results were obtained in transgenic rabbits expressinghuman apoE3 (6). Hepatic overexpression of apoE2, apoE3, andapoE4 all stimulated VLDL secretion (7-9). In contrast, the mutantisoform apoE3Leiden is not capable of stimulating VLDL secretion(10).

The mechanism by which apoE affects VLDL assembly and secretion is poorly understood. A recent in vitro study by Twisk etal. (11) offered a potential mechanism by which apoE might affectVLDL secretion. These authors studied the role of the LDL receptor(LDLr) in production of VLDL. Experiments in cultured hepatocytesof LDLr $-$ / $-$ and control mice showed that LDLr $-$ / $-$ hepatocytes hada strongly increased apoB secretion. This was explained in partby a decreased intracellular degradation of apoB protein. It wasconcluded that the LDLr binds nascent apoB intracellularly duringthe course of VLDL assembly, thereby promoting its intracellulardegradation. Because apoE and apoB are both ligands for the LDLr,it was suggested that apoE's stimulatory action on VLDL secretionmight occur by preventing apoB from binding to the LDLr.

In this study, we tested the hypothesis that the effect of apoE on VLDL secretion is LDLr-dependent. After verification thatthe reported in vitro effects of the LDLr can also be observedin the in vivo situation, we tested whether the effect of apoEis LDLr-dependent by knocking out apoE on a LDLr-deficient background.Our results confirm that the LDLr modulates the VLDL productionrate in vivo, but they also clearly indicate that the effect ofapoE on VLDL production is independent of the presence of theLDLr.

EXPERIMENTAL PROCEDURES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Animals-- all mice were housed under standard conditions with free access to water and regular lab chow. For the comparison betweenwild type and LDLr $-$ / $-$ mice, male mice with a C57BL/6 backgroundwere used. Male animals were also used for comparison of apoE $-$ / $-$ LDLr $-$ / $-$ mice with LDLr $-$ / $-$ mice. Because the apoE $-$ / $-$ LDLr $-$ / $-$ doubleknockout mice were on a mixed background of C57BL/6 and 129, LDLr $-$ / $-$ mice on the same mixed genetic background as the double knockoutmice were used in these experiments as controls. All experimentswere approved by the institutional animal carecommittee.

VLDL Production and Composition-- The in vivo VLDL production was measured after intravenous administration of 500 mg/kg Triton WR1339 as described previously(4, 12). To measure de novo synthesis of VLDL apoB, 100 µCiof ³⁵S-Tran label (ICN, Zoetermeer, The Netherlands) was injected i.v.30 min before Triton WR1339 injection. Blood samples were withdrawnfrom the tail at regular intervals after Triton WR1339 injection.At t = 120 min, an additional large blood sample was withdrawnvia the orbital plexus. In each sample, plasma triglycerides (TGs)were determined, and the rate of triglyceride accumulation inplasma was taken as the in vivo rate of VLDL TGproduction.

From the large blood sample at t = 120 min after Triton WR1339 administration, 200 µl of plasma was brought to 1.063 g/mlwith potassium bromide in a volume of 2 ml, transferred to SW41centrifuge tubes, and layered with a 1.006 g/ml salt solution.After 16 h of centrifugation at 37,000 rpm and 4 °C, the VLDLfraction was carefully removed by pipetting off 1.2 ml. ApoB in0.2 ml of this VLDL fraction was precipitated with isopropanol(13), dissolved in 20% (w/v) SDS, and counted for assessmentof total VLDL apoB production. Pilots with blood samples takenat t = 1 min after Triton WR1339 administration showed that basalactivity was less than 10% of the value at t = 120 min, and thereforethe t = 120 min point was taken as the total de novo VLDL apoBproduction. In the remaining VLDL, triglycerides, phospholipids,and cholesterol were measured with commercially available kitsas described previously (4). This composition of VLDL is amixture of VLDL that circulated before administration of TritonWR1339 and nascent VLDL produced during the 2-h period after TritonWR1339 administration. To obtain the composition of nascent VLDL,the contribution of circulating VLDL was determined and correctedfor, as described previously (14).

For determination of apoB100 and apoB48 production, an aliquot of the blood samples at t = 1 and t = 120 min after TritonWR1339 administration (10 µl) was delipidated by 1.8 ml of $-$ 20°C diethyl ether:methanol (1:1), and, after centrifugation inan Eppendorff centrifuge (13,000 rpm, 10 min), the pellet wasdissolved in sample buffer for SDS-PAGE analysis on a 5% (w/v)polyacrylamide gel. A volume corresponding to 5 µl of plasma wasloaded onto the gel. The gel was fixed by Coomassie staining (BioSafeCoomassie; Bio-Rad) and dried overnight between two cellophanesheets using a GradiDry gel drying solution (Gradipore). Afterdrying, one sheet was carefully removed, and the uncovered partof the gel was autoradiographed with phosphoimagertechnology.

Statistical Analysis-- Nonparametric Mann-Whitney U tests were used for all statistical analyses. p $<=$ 0.05 was considered statisticallysignificant.

RESULTS

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Effect of the LDL Receptor on VLDL Secretion in Vivo-- First we tested whether the LDLr affects the VLDL secretion rate in vivo. Hepatic VLDL triglyceride and apoB production rateswere measured by intravenous injection of ³⁵S-Tran label and Triton WR1339 in 4-h-fasted mice. As shown inFig. 1A, LDLr $-$ / $-$ mice showed a 30% increase in the triglycerideproduction rate as compared with wild type animals (162 ± 42 and211 ± 12 µmol·kg¹·h¹ for wild type and LDLr $-$ / $-$ animals, respectively; p < 0.005).Total apoB production (Fig. 1B) was also significantly increasedby ~30% in LDLr $-$ / $-$ mice as compared with wild type mice (100 ±19% and 132 ± 42% for wild type and LDLr $-$ / $-$ mice, respectively;p < 0.05). We also measured the de novo synthesis rate of B100and B48 by SDS-PAGE analysis of plasma collected 1 and 120 minafter Triton WR1339 injection (Fig. 1C). No significant differencescould be observed between the LDLr $-$ / $-$ and wild type mice for apoB100and apoB48 production rates, although the former strain secretedrelatively more apoB100. This was evident from a significantlyhigher apoB100:apoB48 ratio (2.02 ± 0.39 and 1.26 ± 0.42 for LDLr $-$ / $-$ and wild type mice, respectively; p < 0.02).

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Fig. 1. VLDL production in C57BL/6 and LDLr $-$ / $-$ mice measured by ³⁵S-Tran label and Triton WR1339 administration. A, accumulation of triglycerides in plasma.

, C57BL/6 mice; $black-square$ , LDLr $-$ / $-$ mice. B, total VLDL apoB secretion. VLDL was isolated 2 h after Triton WR1339 injection, and label incorporation in apoB was counted after isopropanol precipitation.

, C57BL/6 mice; $black-square$ , LDLr $-$ / $-$ mice. C, apoB100 and apoB48 production as analyzed by SDS-PAGE analysis of plasma. Plasma from 1 and 120 min after Triton WR1339 injection was delipidated and subjected to SDS-PAGE analysis. The black bars indicate the average label incorporation in the apoB100 and apoB48 bands. For B and C, label incorporation was normalized to the B100 incorporation in the C57BL/6 mice.

We have also analyzed the lipid composition of the nascent VLDL particles after Triton WR1339 injection (Fig. 2). We confirmedthat Triton WR1339 itself did not affect the lipid compositionof lipoprotein particles.² The composition of nascent VLDL was very similar between theLDLr $-$ / $-$ and wild type mice; both groups had triglycerides comprising~75% of total lipid mass. Circulating VLDL from LDLr $-$ / $-$ mice wassomewhat lower in triglyceride content than VLDL of the wild typemice (50% and 69%, respectively).

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Fig. 2. Composition of nascent and circulating VLDL in C57BL/6 mice and LDLr $-$ / $-$ mice. VLDL was isolated by ultracentrifugation from plasma after a 4-h fast (circulating VLDL) or 2 h after Triton WR1339 administration (nascent VLDL), and lipid composition was determined (in w/w% of total lipids).

The Effect of apoE on VLDL Production in the Absence of the LDL Receptor-- To determine whether the effect of apoE is dependent on the LDLr, we have characterized VLDL production and composition inapoE $-$ / $-$ LDLr $-$ / $-$ double knockout mice and LDLr $-$ / $-$ mice. As seenin Fig. 3A, the VLDL TG production was approximately 2-fold lowerin the apoE $-$ / $-$ LDLr $-$ / $-$ mice as compared with the LDLr $-$ / $-$ mice(77 ± 16 and 132 ± 39 µmol·kg¹·h¹ for apoE $-$ / $-$ LDLr $-$ / $-$ mice and LDLr $-$ / $-$ mice, respectively; p <0.005). A similar result was obtained for the total VLDL apoBproduction (Fig. 3B). The rate of total apoB production was significantlylower in the apoE $-$ / $-$ LDLr $-$ / $-$ mice than in the LDLr $-$ / $-$ mice (53± 17% and 100 ± 39% for apoE $-$ / $-$ LDLr $-$ / $-$ mice and LDLr $-$ / $-$ mice,respectively; p = 0.01). In Fig. 3C, SDS-PAGE analysis of plasmacollected 1 and 120 min after Triton WR1339 administration isshown for the apoE $-$ / $-$ LDLr $-$ / $-$ double knockout mice and the LDLr $-$ / $-$ mice. Most strikingly, apoB100 production in the apoE $-$ / $-$ LDLr $-$ / $-$ mice was severely diminished to only 10% of that of the LDLr $-$ / $-$ mice.

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Fig. 3. VLDL production in LDLr $-$ / $-$ and apoE $-$ / $-$ LDLr $-$ / $-$ mice measured by ³⁵S-Tran label and Triton WR1339 administration. See the Fig. 1 legend for more details. A, accumulation of triglycerides in plasma.

, LDLr $-$ / $-$ mice; $black-square$ , apoE $-$ / $-$ LDLr $-$ / $-$ mice. B, total VLDL apoB secretion.

, LDLr $-$ / $-$ mice; $black-square$ , apoE $-$ / $-$ LDLr $-$ / $-$ mice. C, apoB100 and apoB48 production. For B and C, label incorporation was normalized to the B100 incorporation in the LDLr $-$ / $-$ mice.

In Fig. 4, the average composition of nascent and circulating VLDL is shown. Because of the high lipid levels in apoE $-$ / $-$ LDLr $-$ / $-$ mice before Triton WR1339 injection, the nascent VLDL compositionis calculated using the differences in lipids between total VLDL2 h after Triton WR1339 administration and the circulating VLDLlipid content (i.e. the lipids present before Triton WR1339 administration).In both mouse models, nascent VLDL was rich in triglycerides.Large differences were found in circulating VLDL: VLDL of theapoE $-$ / $-$ LDLr $-$ / $-$ mice contained only 7% TGs as compared with 50%TGs in the LDLr $-$ / $-$ mice.

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Fig. 4. Composition of nascent and circulating VLDL in LDLr $-$ / $-$ and apoE $-$ / $-$ LDLr $-$ / $-$ mice. VLDL was isolated by ultracentrifugation from plasma after a 4-h fast (circulating VLDL) or 2 h after Triton WR1339 administration (nascent VLDL), and lipid composition was determined (in w/w% of total lipids). Values for nascent VLDL are corrected for circulating VLDL.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

In this study, we have tested the hypothesis that the effect of apoE on VLDL secretion is mediated via intracellular interactionwith the LDL receptor. If this hypothesis were true, we reasonedthat the 50% reduction of VLDL secretion as observed in the apoE $-$ / $-$ mouse compared with the wild type mouse controls (4, 5)should not be observed on a LDLr $-$ / $-$ background. Fig. 3 shows thatthe effect of deleting apoE in reducing VLDL secretion was independentof the LDL receptor: a 50% reduction of both VLDL apoB and TGswas observed in the apoE $-$ / $-$ LDLr $-$ / $-$ mouse as compared with theLDLr $-$ / $-$ controls.

The conclusion that apoE acts on the VLDL assembly pathway irrespective of the presence of the LDLr is indirectly supportedby other recent studies. On one hand, it was shown that apoE2,a variant of apoE that binds poorly to lipoprotein receptors (15),is still capable of stimulating VLDL secretion (3, 7, 9).On the other hand, truncation of apoE at the C-terminal lipid-bindingdomain abolishes the stimulatory effect of apoE on VLDL secretion(16, 17). This truncated form of apoE is properly transcribedand detectable in plasma associated with VLDL particles, and itstill contains an intact LDLr binding domain as judged by rescuefrom hyperlipidemia in apoE $-$ / $-$ mice. Thus, if competition of apoEwith apoB for binding to the LDLr was the mechanism of apoE'saction on VLDL secretion, the truncated apoE protein should stillbe able to increase VLDL secretion, whereas apoE2 should not beable to do so. Because the opposite is observed, we conclude thatlipid binding, rather than receptor binding, is important forthe stimulation of VLDL production byapoE.

Although apoE does not act via the LDL receptor, we did confirm in vivo that absence of the LDLr enhances VLDL apoB secretionas described previously for mouse hepatocytes (11). Thus, LDLrdeficiency leads to a 30% increase in VLDL apoB production. Also,the rate of VLDL TG secretion was increased by 30% in LDLr $-$ / $-$ mice. The effects of the LDL receptor on VLDL apoB100 and apoB48secretion were too small for our analysis to give significantdifferences. However, we found a significant increase in the ratioof secreted apoB100:apoB48 particles in the LDLr $-$ / $-$ mice. Thus,although the effect of the LDLr on VLDL apoB production in vivois much smaller than that observed in vitro, it is in line withthe previous in vitro observation that apoB100 secretion was increased3-4-fold, and apoB48 was increased only 1.5-2-fold (11).

It has been reported that the genetic background can have a large impact on the rate of VLDL secretion (18). Because theapoE $-$ / $-$ LDLr $-$ / $-$ mice were on a mixed background of C57BL/6 and129, we used LDLr $-$ / $-$ mice that were on the same mixed background.Our data confirm the impact of genetic background: when the rateof VLDL TG secretion is compared between the LDLr $-$ / $-$ mice on thetwo genetic backgrounds used in this study, the mice on a C57/BL6background clearly had a higher VLDL TG secretion as comparedwith mice on the mixed background (211 ± 12 and 132 ± 39 µmol·kg¹·h¹,respectively).

The composition of nascent VLDL was similar for all mouse models tested, comprising ~70-75% triglycerides (Figs. 2 and 4).The TG content of the apoE $-$ / $-$ LDLr $-$ / $-$ mice was higher, i.e. 88%,but this is likely the result of the large contribution of circulatingVLDL to the total VLDL fraction after Triton WR1339 administration.In particular, the cholesterol content of nascent VLDL is proneto large error because of the enormous amount of cholesterol alreadypresent in these mice (19, 20). Similar TG content of nascentVLDL is consistent with the fact that both total apoB and VLDLTG secretion were affected to the same extent in both Figs. 1and 3. Maugeais et al. (7) previously reached a similar conclusionregarding the effect of apoE isoforms on VLDL production, i.e.that both apoB and TGs were affected. However, we have recentlyseen that the particles secreted by hepatocytes of apoE $-$ / $-$ micewere smaller, although they were of similar composition (4).It appears that particle size and lipid composition are not alwaystightly correlated, but it remains to be seen whether this observationis specific for particles lackingapoE.

In the mouse models tested in this study and also in other mouse models, e.g. the VLDLr $-$ / $-$ LDLr $-$ / $-$ mouse (14) and the apoE $-$ / $-$ mouse (4), nascent VLDL invariably contained ~65-80% triglycerides.This contrasts with studies in humans or in vitro systems. Compartmentalmodeling of apoB lipoprotein metabolism in humans invariably requiresthe input of particles into the plasma compartment ranging fromlarge buoyant VLDL to LDL (21-23). Also, in in vitro experiments,the size (i.e. triglyceride content) of the lipoprotein particlesproduced varies and appears to be related to lipid availability(for review, see Ref. 24), although it has been suggested thatlipolytic activity in the medium may account for at least someof the observed effects (25). We² and others (26) have verified that catabolism of VLDL is completelyblocked by Triton WR1339 administration, thus the compositionof the VLDL that subsequently accumulates should be a direct measureof the composition of nascent VLDL. Therefore, we conclude thatin contrast to the human situation, mice secrete VLDL rather homogeneouslyas triglyceride-rich particles. It therefore appears that in mice,the rate of VLDL production is regulated not so much by VLDL compositionas by particle number, i.e. by degradation of nascent apoB proteinand/or pre-VLDL particles during the second stage of VLDL assembly(24, 27). The large differences in the TG content of circulatingVLDL as opposed to nascent VLDL (Figs. 2 and 4) reflect differencesin VLDL catabolism (10).

We observed an unexpected effect of combined apoE and LDLr deficiency on the secretion of apoB100 particles: in the apoE $-$ / $-$ LDLr $-$ / $-$ mice, the secretion of apoB100 was reduced to only 10%of that in LDLr $-$ / $-$ mice. In apoE $-$ / $-$ mice, apoB100 production isat most 50% lower (5, 7), indicating that the severely reducedapoB100 production is a specific effect of combined apoE and LDLrdeficiency. At this moment, we can only speculate on the mechanismthat underlies this striking observation. Rather, we would liketo discuss some fundamental differences between B100- and B48-containinglipoproteins that may be relevant in rationalizing ourobservations.

ApoB48 does not bind to the LDLr but rather requires the LDLr-related protein for endocytosis (28, 29). LDLr-related protein-mediateduptake of lipoproteins depends on apoE (30). Therefore, in theapoE $-$ / $-$ mouse, the LDLr and the LDLr-related protein are not ableto take up apoB48 particles. However, secretion of apoB48 particlesby the liver still continues (5, 7). Because the rate ofapoB48 particle secretion should equal the rate of apoB48 particleuptake in steady state, this implies that other receptors shouldbe present to clear these apoB48 particles. One receptor may bethe recently cloned apoB48 receptor (31).

In the LDLr $-$ / $-$ apoE $-$ / $-$ mouse, apoB100 particles must also be cleared by receptors other than the LDLr and the LDLr-relatedprotein. It appears that these back-up systems perform poorlybecause Ishibashi et al. (20) found that plasma B100 levelswere well detectable (~50% of normal) in these mice, despite thevery low production rate that we have observed in this study.The extremely low TG content of the circulating VLDL as comparedwith that in the wild type also suggests very poor clearance ofVLDL particles. It may be envisaged that the reduced VLDL apoB100secretion rate in apoE $-$ / $-$ LDLr $-$ / $-$ mice is the result of some unknownfeedback mechanism to maintain steady state and prevent unrestrainedaccumulation of apoB100 particles in the circulation. Such a feedbackon VLDL secretion is only hypothetical at this moment; yet itbecomes apparent that factors such as apoE and the LDLr that areclearly involved in lipoprotein uptake are also involved in VLDLproduction. The concept of hepatic VLDL production as a merelysubstrate-driven process (32) thus requires considerablesophistication.

ACKNOWLEDGEMENTS

We thank Elly de Wit for help with SDS-PAGE analysis and Peter Voshol for help with statisticalanalysis.

	FOOTNOTES

^* This work was supported by Dutch Heart Foundation Grants NHS 96011 and 97067.The costs of publication of this article weredefrayed in part by the payment of page charges. The article musttherefore be hereby marked "advertisement" in accordance with18 U.S.C. Section 1734 solely to indicate thisfact.

^§ To whom correspondence should be addressed: TNO Prevention and Health, Gaubius Laboratory, P. O. Box 2215, NL-2301 CE Leiden,The Netherlands. Tel.: 31-71-5181428; Fax: 31-71-5181904; E-mail:B.Teusink@pg.tno.nl.

Published, JBC Papers in Press, August 23, 2001, DOI 10.1074/jbc.M106396200

² B. Teusink and H. van der Boom, unpublishedobservations.

ABBREVIATIONS

The abbreviations used are: apo, apolipoprotein; LDL, low density lipoprotein; LDLr, low density lipoprotein receptor; TG, triglyceride; VLDL, very low density lipoprotein; SDS-PAGE, SDS-polyacrylamide gel electrophoresis.

	REFERENCES

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

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Stimulation of the in Vivo Production of Very Low Density Lipoproteins by Apolipoprotein E Is Independent of the Presence of the Low Density Lipoprotein Receptor*

Stimulation of the in Vivo Production of Very Low Density Lipoproteins by Apolipoprotein E Is Independent of the Presence of the Low Density Lipoprotein Receptor^*