Hostname: page-component-78c5997874-g7gxr Total loading time: 0 Render date: 2024-11-13T02:37:07.515Z Has data issue: false hasContentIssue false
  • English
  • Français

Plant sterols beyond low-density lipoprotein-cholesterol

Published online by Cambridge University Press:  01 September 2007

M. Naruszewicz  and
M. Kozlowska-Wojciechowska
M. Naruszewicz
Affiliation:
Department of Pharmacognosy and Molecular Basis of Phytotherapy Faculty of PharmacyMedical University of WarsawWarsawPolandmnarusze@farm.amwaw.edu.pl
M. Kozlowska-Wojciechowska
Affiliation:
Department of Pharmacognosy and Molecular Basis of Phytotherapy Faculty of PharmacyMedical University of WarsawWarsawPolandmnarusze@farm.amwaw.edu.pl
Rights & Permissions [Opens in a new window]

Abstract

An abstract is not available for this content. As you have access to this content, full HTML content is provided on this page. A PDF of this content is also available in through the ‘Save PDF’ action button.
Type
Invited Commentary
Information
British Journal of Nutrition , Volume 98 , Issue 3 , September 2007 , pp. 454 - 455
Copyright
Copyright © The Authors 2007

Moderate hypercholesterolaemia still remains one of the commonest metabolic disorders in developed societies, largely due to the effect of an inappropriate diet with high intake of saturated and trans fatty acids. This form of hypercholesterolaemia is often accompanied by arterial hypertension which may increase the atherogenicity of even moderately increased concentrations of the LDL fraction. In fact, it should be borne in mind that arterial hypertension increases the risk of LDL modification because angiotensin II stimulates the secretion of reactive oxygen species through increasing the activity of NADPH-oxidase by monocytes and macrophages in the vascular wallReference Aviram1, Reference Keidar, Heinrich, Kaplan, Hayek and Aviram2. An example illustrating the size of this problem on the population scale may be Poland, where 72 % of the 9 million individuals with hypertension have hypercholesterolaemiaReference Zdrojewski, Wyrzykowski, Szczech, Wierucki, Naruszewicz, Narkiewicz and Zarzeczna-Baran3. These data demonstrate the scale of the problem, because coexistence of even these two factors creates a risk of increased early mortality in such populations. Therefore, a primary prophylactic measure must be an attempt to lower plasma LDL concentration. Functional foods containing plant sterols may offer such an opportunity on a population-wide scale. The intake of plant sterols at a dose of 2 g/d may lower LDL-cholesterol concentration by as much as 20 %Reference Katan, Grundy and Jones4. The usefulness of such functional foods has been confirmed in various age groups, including childrenReference Vuorio, Gylling, Turtola, Kontula, Ketonen and Miettinen5, and also in combined treatment with statins in patients with coronary artery disease. It is worth emphasising that with such combined treatment there is a chance to lower statin doses, which reduces the potential side effects of the drugs and also the treatment costs.

Plant sterols esters may also affect other non-lipid risk factors of atherosclerosis, i.e. they may have pleiotropic properties. For example, administration of plant sterols to young individuals as primary prevention not only decreased LDL-cholesterol concentration (by 12 %), but also reduced platelet aggregationReference Kozlowska-Wojciechowska, Jastrzebska, Naruszewicz and Foltynska6. In other studies plant sterols decreased the levels of oxidised LDL by 20Reference Homma, Ikeda and Ishikawa7 or 22 %Reference Kozłowska-Wojciechowska and Naruszewicz8 and of C-reactive proteinReference Kozłowska-Wojciechowska and Naruszewicz8. Because these effects cannot be explained exclusively by the mean reduction in the LDL-cholesterol concentration, it is highly probable that sterols and stanols may display pleiotropic action through lowering the level of oxidative stress. The mechanism of this action seems to be based on limitation of intestinal absorption of not only cholesterol but also of oxysterols originating from food subjected to thermal processingReference Naruszewicz, Wozny, Mirkiewicz, Nowicka and Szostak9, Reference Staprans, Pan, Rapp and Feingold10. Indeed, we have shown parallel lowering of plasma oxidised LDL, 7-β-hydroxycholesterol and 7-ketocholesterol under the influence of plant sterols. It has been known for a long time that oxysterols not only exert cytotoxic effects on the vascular endothelium but also increase the activity of NADPH-oxidase of monocytic cells. Clearly these observations require confirmation, but these alternative actions of plant sterols are likely to become the subject of increased interest.

In this issue of the British Journal of Nutrition, Chan et al. Reference Chan, Demonty, Pelled and Jones11 present results indicating that a change in the method of esterification of plant sterols, i.e. replacement of sunflower-seed oil fatty acids by those from olive oil, may result in positive changes in the lipid profile and may reduce the susceptibility of the LDL fraction to oxidation. Such a change in the method of sterol esterification may also be beneficial in view of the fact that, in contrast to oleic acid, n-6 acids may reduce the content of the ABCA-1 protein responsible for cholesterol removal from cellsReference Wang and Oram12. From this point of view, in individuals with low HDL-cholesterol levels, plant sterols esterified with oleic acid may be more beneficial. Furthermore, recent findings indicate that esterification of plant sterols with fatty acids from fish oil may significantly lower the level of TAG in fasting and postprandial conditions in patients with hyperlipidaemiaReference Demonty, Chan, Pelled and Jones13. Although the authors of this latter study did not assess the effect of fish-oil esters of plant sterols on inflammatory markers, increased intake of EPA and DHA may have a positive effect on the inflammatory processes associated with atherosclerosis progression.

A new method of plant sterol esterification has recently been presentedReference Fuhrman, Plat, Herzog and Aviram14. This involved enzymic inter-esterification of plant sterols in a matrix containing 1,3-diacylglycerol. The biological effects of the sterol esters produced were examined in apo E-deficient miceReference Fuhrman, Plat, Herzog and Aviram14. Apart from a significant reduction in the cholesterol concentration by 21 %, a decrease in TAG concentration by 38 % was shown. This was accompanied by a significant reduction in oxidised LDL accumulation in macrophages, which confirms the positive effect of thus esterified sterols on oxidative stress.

In contrast to the above-described benefits of using plant sterols, studies indicating a pro-atherogenic effect have been publishedReference Glueck, Speirs, Tracy, Streicher, Illig and Vandegrift15, Reference Assmann, Cullen, Erbey, Ramey, Kannenberg and Schulte16. However, these studies were not confirmed by the Dallas Heart Study where no effect of phytosterol and compasterol on progression of atherosclerotic lesions was found both in mice with genetic phytosterolaemia as well as in human subjects with documented atherosclerosisReference Wilund, Yu, Xu, Vega, Grundy, Cohen and Hobbs17. Therefore, further clinical trials on plant sterols to assess the safety of their use are certainly warranted.

References

1Aviram, M (1999) Macrophage foam cell formation during early atherogenesis is determined by the balance between pro-oxidants and anti-oxidants in arterial cells and blood lipoproteins. Antioxid Redox Signal 1, 585594.CrossRefGoogle ScholarPubMed
2Keidar, S, Heinrich, R, Kaplan, M, Hayek, T & Aviram, M (2001) Angiotensin II administration to atherosclerotic mice increases macrophage uptake of oxidized LDL: a possible role for interleukin-6. Arterioscler Thromb Vasc Biol 21, 14641469.CrossRefGoogle ScholarPubMed
3Zdrojewski, T, Wyrzykowski, B, Szczech, R, Wierucki, L, Naruszewicz, M, Narkiewicz, K & Zarzeczna-Baran, M (2005) Epidemiology and prevention of arterial hypertension in Poland. Blood Press 14, Suppl. 2, 1016.CrossRefGoogle Scholar
4Katan, MB, Grundy, SM & Jones, P (2003) Efficacy and safety of plant stanols and sterols in the management of blood cholesterol levels. Mayo Clin Proc 78, 965978.CrossRefGoogle ScholarPubMed
5Vuorio, AF, Gylling, H, Turtola, H, Kontula, K, Ketonen, P & Miettinen, TA (2000) Stanol ester margarine alone and with simvastatin lowers serum cholesterol in families with familial hypercholesterolemia caused by the FH-North Karelia mutation. Arterioscler Thromb Vasc Biol 20, 500506.CrossRefGoogle ScholarPubMed
6Kozlowska-Wojciechowska, M, Jastrzebska, M, Naruszewicz, M & Foltynska, A (2003) The impact of margarine enriched with sterols on the blood lipids, platelet function and the fibrinogen level in young men. Metabolism 52, 13731378.CrossRefGoogle ScholarPubMed
7Homma, Y, Ikeda, I & Ishikawa, T (2003) Decrease in plasma low-density lipoprotein cholesterol, apolipoprotein B, cholesteryl ester transfer protein, and oxidized low-density lipoprotein by plant stanol ester-containing spread: a randomized, placebo-controlled trial. Nutrition 19, 369374.CrossRefGoogle ScholarPubMed
8Kozłowska-Wojciechowska, M & Naruszewicz, M (2003) Effect of plant sterol enriched margarine on plasma C-reactive protein. Possible relation to reduction in plasma oxysterols. Circulation 107, e7001.Google Scholar
9Naruszewicz, M, Wozny, E, Mirkiewicz, E, Nowicka, G & Szostak, WB (1987) The effect of thermally oxidized soya bean oil on metabolism of chylomicrons. Increased uptake and degradation of oxidized chylomicrons in cultured mouse macrophages. Atherosclerosis 66, 4553.CrossRefGoogle ScholarPubMed
10Staprans, I, Pan, XM, Rapp, JH & Feingold, KR (2003) Oxidized cholesterol in the diet is a source of oxidized lipoproteins in human serum. J Lipid Res 44, 705715.CrossRefGoogle ScholarPubMed
11Chan, Y-M, Demonty, I, Pelled, D & Jones, PJH (2007) Olive oil containing olive oil fatty acid esters of plant sterols and dietary diacylglycerol reduces low density lipoprotein cholesterol and decreases the tendency for peroxidation in hypercholesterolemic subjects. Br J Nutr 98, 564–571.CrossRefGoogle Scholar
12Wang, Y & Oram, JF (2002) Unsaturated fatty acids inhibit cholesterol efflux from macrophages by increasing degradation of ATP-binding cessette transporter A1. J Biol Chem 277, 56925697.CrossRefGoogle ScholarPubMed
13Demonty, I, Chan, YM, Pelled, D & Jones, PJ (2006) Fish-oil esters of plant sterols improve the lipid profile of dyslipidemic subjects more than do fish-oil or sunflower oil esters of plant sterols. Am J Clin Nutr 84, 1534–1542.CrossRefGoogle ScholarPubMed
14Fuhrman, B, Plat, D, Herzog, Y & Aviram, M (2007) Consumption of a novel dietary formula of plant sterol esters of canola oil fatty acids, in a canola oil matrix containing 1,3-diacylglycerol, reduces oxidative stress in atherosclerotic apolipoprotein E-deficient mice. J Agric Food Chem 55, 20282033.CrossRefGoogle Scholar
15Glueck, CJ, Speirs, J, Tracy, T, Streicher, P, Illig, E & Vandegrift, J (1991) Relationships of serum plant sterols (phytosterols) and cholesterol in 595 hypercholesterolemic subjects, and familial aggregation of phytosterols, cholesterol, and premature coronary heart disease in hyperphytosterolemic probands and their first-degree relatives. Metabolism 40, 842–848.CrossRefGoogle ScholarPubMed
16Assmann, G, Cullen, P, Erbey, J, Ramey, DR, Kannenberg, F & Schulte, H (2006) Plasma sitosterol elevations are associated with an increased incidence of coronary events in men: results of a nested case-control analysis of the Prospective Cardiovascular Munster (PROCAM) study. Nutr Metab Cardiovasc Dis 16, 13–21.CrossRefGoogle ScholarPubMed
17Wilund, KR, Yu, L, Xu, F, Vega, GL, Grundy, SM, Cohen, JC & Hobbs, HH (2005) No association between plasma levels of plant sterols and atherosclerosis in mice and men. Arterioscler Thromb Vasc Biol 24, 23262332.CrossRefGoogle Scholar