Browsing by Author "Kozarsky, KF"

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    Effects of hepatic expression of the high-density lipoprotein receptor SR-BI on lipoprotein metabolism and female fertility
    (ENDOCRINE SOC, 2006) Yesilaltay, A; Morales, MG; Amigo, L; Zanlungo, S; Rigotti, A; Karackattu, SL; Donahee, MH; Kozarsky, KF; Krieger, M
    The etiology of human female infertility is often uncertain. The sterility of high-density lipoprotein (HDL) receptor-negative (SR-BI-/-) female mice suggests a link between female infertility and abnormal lipoprotein metabolism. SR-BI-/- mice exhibit elevated plasma total cholesterol [ with normalsized and abnormally large HDL and high unesterified to total plasma cholesterol (UC:TC) ratio]. We explored the influence of hepatic SR-BI on female fertility by inducing hepatic SR-BI expression in SR-BI-/- animals by adenovirus transduction or stable transgenesis. For transgenes, we used both wild-type SR-BI and a double-point mutant, Q402R/Q418R (SR-BI-RR), which is unable to bind to and mediate lipid transfer from wild-type HDL normally, but retains virtually normal lipid transport activities with low-density lipoprotein. Essentially wild-type levels of hepatic SR-BI expression in SR-BI-/- mice restored to nearly normal the HDL size distribution and plasma UC: TC ratio, whereas approximately 7- to 40- fold overexpression dramatically lowered plasma TC and increased biliary cholesterol secretion. In contrast, SR-BI-RR overexpression had little effect on SR-BI-/- mice, but in SR-BI-/- mice, it substantially reduced levels of abnormally large HDL and normalized the UC: TC ratio. In all cases, hepatic transgenic expression restored female fertility. Overexpression in SR-BI-/- mice of lecithin: cholesterol acyl transferase, which esterifies plasma HDL cholesterol, did not normalize the UC: TC ratio, probably because the abnormal HDL was a poor substrate, and did not restore fertility. Thus, hepatic SR- BImediated lipoprotein metabolism influences murine female fertility, raising the possibility that dyslipidemia might contribute to human female infertility and that targeting lipoprotein metabolism might complement current assisted reproductive technologies.
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    Fibrates down-regulate hepatic scavenger receptor class B type I protein expression in mice
    (AMER SOC BIOCHEMISTRY MOLECULAR BIOLOGY INC, 2003) Mardones, P; Pilon, A; Bouly, M; Duran, D; Nishimoto, T; Arai, H; Kozarsky, KF; Altayo, M; Miquel, JF; Luc, G; Clavey, V; Staels, B; Rigotti, A
    Fibrates are normolipidemic drugs used in atherogenic dyslipidemia because of their ability to raise high density lipoprotein (HDL) and decrease triglyceride levels. They exert multiple effects on lipid metabolism by activating the peroxisome proliferator-activated receptor-a (PPAR-alpha), which controls the transcriptional regulation of genes involved in hepatic fatty acid, cholesterol, and lipoprotein metabolism. The hepatic expression of the scavenger receptor class B type I (SR-BI) plays a critical role in lipoprotein metabolism, mainly due to its ability to mediate selective cholesterol uptake. Because fibrates and PPAR-alpha agonists upregulate SR-BI expression in human and murine macrophages, we tested whether fibrates raised a similar regulatory response on hepatic SR-BI expression in mice. Surprisingly, fibrate treatment suppressed SR-BI protein expression in the liver without changing steady state SR-BI mRNA levels. Decreased hepatic SR-BI protein expression correlated with enlarged HDL particle size. This effect was concomitant with down-regulation of CLAMP, a putative SR-BI-stabilizing protein found in the hepatic plasma membrane, which was also not associated to changes in CLAMP mRNA levels. The posttranscriptional regulatory effect of fibrates over hepatic SR-BI protein levels was dependent on PPAR-alpha expression, because it was absent in PPAR-alpha-deficient mice. Restoring hepatic SR-BI expression in fibrate-treated mice by recombinant adenoviral gene transfer abolished fibrate-mediated HDL particle size enlargement. This study describes a novel effect of fibrates on hepatic SR-BI expression providing an alternative mechanism by which this drug family modulates HDL metabolism in vivo.