Gender-related differences in bile acid and sterol metabolism in outbred CD-1 mice fed low- and high-cholesterol diets

Cholesterol 7␣-hydroxylase (CYP7A1) catalyzes the rate-limiting step in the pathway responsible for the formation of the majority of bile acids. Transcription of the gene is regulated by the size of the bile acid pool and dietary and hormonal factors. The farnesoid X receptor and the liver X receptor (LXR) are responsible for regulation by bile acids and cholesterol, respectively. To study the effects of dietary cholesterol and fat upon expression of the human CYP7A1 gene, mice were generated by crossing transgenic mice carrying the human CYP7A1 gene with mice that were homozygous knockouts (CYP7A1 ؊/؊ ). The mice (mCYP7A1 ؊/؊ /hCYP7A1) expressed the human gene at much higher levels than did the transgenics bred in the wild-type background. A diet containing 1% cholic acid reduced the expression of the human gene in mCYP7A1 ؊/؊ /hCYP7A1 mice to undetectable levels. Cholestyramine (5%) increased the level of expression of the human gene and the mouse gene. Thus, farnesoid X receptor-mediated regulation was preserved. A diet containing 2% cholesterol increased expression of the mouse gene in wild-type mice, but it did not affect expression of the human gene in mCYP7A1 ؊/؊ /hCYP7A1 mice. None of the diets altered the serum cholesterol or triglyceride levels in these mice; 1% cholic acid caused a redistribution of cholesterol from the high density lipoprotein to the low density lipoprotein density in the humanized mice but not in wild-type mice. A diet containing 30% saturated fat and 2% cholesterol caused a decrease in CYP7A1 levels in mCYP7A1 ؊/؊ /hCYP7A1 mice. The serum cholesterol levels rose in all mice fed this diet. The increase was greater in the mCYP7A1 ؊/؊ /hCYP7A1 mice. Together, these data suggest that the lack of an LXR element in the region from ؊56 to ؊49 of the human CYP7A1 promoter may account for some of the differences in response to diets between humans and rodents.Cholesterol is a lipid molecule that plays unique and specific roles in cellular membrane function and embryonic development. It also serves as a precursor for the synthesis of steroid hormones and bile acids. Accordingly, a sophisticated system has evolved to ensure its availability to cells. The liver plays a central role in coordinating many of the components of this process. The accumulation of excess cholesterol in blood vessels leads to atherosclerosis and its accumulation in the bile leads to gallstones. Humans, in contrast to rodents, are highly susceptible to these conditions. Hepatic cholesterol homeostasis is controlled by the rate of cholesterol entry to the liver from dietary and endogenous lipoproteins, as well as by the rate of synthesis of new cholesterol relative to the rate of hepatic lipoprotein secretion, the rate of cholesterol degradation to bile acids, and the rate of excretion of the intact molecule into the bile. These various processes are modulated by the levels of the enzymes catalyzing the rate-limiting steps of each process. An important determinant of the level of these proteins is the rate of transcripti...

Section: Cyp7a1supporting

confidence: 92%

Mice Expressing the Human CYP7A1 Gene in the Mouse CYP7A1 Knock-out Background Lack Induction of CYP7A1 Expression by Cholesterol Feeding and Have Increased Hypercholesterolemia When Fed a High Fat Diet

Chen

Levy-Wilson

Goodart

et al. 2002

“…1 and 6). Sexually dimorphic expression patterns of the CYP7B1 and CYP39A1 oxysterol 7␣-hydroxylases, together with their substrate preferences, may thus underlie differences in bile acid metabolism that exist between male and female mice (26,27).…”

Section: Discussionmentioning

confidence: 99%

Expression Cloning of an Oxysterol 7α-Hydroxylase Selective for 24-Hydroxycholesterol

Li-Hawkins

Lund

Bronson

et al. 2000

168

131

The synthesis of 7␣-hydroxylated bile acids from oxysterols requires an oxysterol 7␣-hydroxylase encoded by the Cyp7b1 locus. As expected, mice deficient in this enzyme have elevated plasma and tissue levels of 25-and 27-hydroxycholesterol; however, levels of another major oxysterol, 24-hydroxycholesterol, are not increased in these mice, suggesting the presence of another oxysterol 7␣-hydroxylase. Here, we describe the cloning and characterization of murine and human cDNAs and genes that encode a second oxysterol 7␣-hydroxylase. The genes contain 12 exons and are located on chromosome 6 in the human (CYP39A1 locus) and in a syntenic position on chromosome 17 in the mouse (Cyp39a1 locus). CYP39A1 is a microsomal cytochrome P450 enzyme that has preference for 24-hydroxycholesterol and is expressed in the liver. The levels of hepatic CYP39A1 mRNA do not change in response to dietary cholesterol, bile acids, or a bile acid-binding resin, unlike those encoding other sterol 7␣-hydroxylases. Hepatic CYP39A1 expression is sexually dimorphic (female > male), which is opposite that of CYP7B1 (male > female). We conclude that oxysterol 7␣-hydroxylases with different substrate specificities exist in mice and humans and that sexually dimorphic expression patterns of these enzymes in the mouse may underlie differences in bile acid metabolism between the sexes.Two metabolic pathways that differ in their initial steps produce 7␣-hydroxylated bile acids (1). In one pathway, cholesterol (5-cholesten-3␤-ol) is first converted into 7␣-hydroxycholesterol (cholest-5-ene-3␤,7␣-diol) by the enzyme cholesterol 7␣-hydroxylase, which is encoded by the Cyp7a1 gene in mice. In the other pathway, cholesterol is first converted into one of several oxysterols prior to being 7␣-hydroxylated by oxysterol 7␣-hydroxylase, which is encoded by the Cyp7b1 gene. The 7␣-hydroxylated intermediates produced by these different initiating steps are subsequently converted into primary bile acids by a series of shared enzymes in the liver (2).Cholesterol 7␣-hydroxylase shows a marked preference for cholesterol as a substrate and is only weakly active against other sterols (3), whereas oxysterol 7␣-hydroxylase prefers 25-hydroxycholesterol (cholest-5-ene-3␤,25-diol) and 27-hydroxycholesterol (cholest-5-ene-3␤,27-diol) (4, 5). In agreement with the latter preference, Cyp7b1 knockout mice accumulate these two oxysterols in their plasma and tissues (6). The levels of the other major oxysterol, 24-hydroxycholesterol (cholest-5-ene-3␤,24-diol), are near normal in these animals (6). In contrast, a human with a complete absence of oxysterol 7␣-hydroxylase activity accumulated 24-hydroxycholesterol as well as 25-and 27-hydroxycholesterol in his plasma (7). These observations suggest that the human enzyme, unlike the mouse enzyme, may act on all three oxysterol substrates.The observed differences in the oxysterol accumulation patterns in mice and humans that express no oxysterol 7␣-hydroxylase are not due to differences in the biosynthesis of oxysterols, as cholester...

“…Pool size was determined as the total bile acid content of small intestine, gallbladder, and the liver, combined as described (25). These organs were homogenized in 20 ml of ethanol (at 60°C), the extract was filtered and a 1-ml aliquot dried with a centrifuge concentrator at room temperature.…”

Section: Methodsmentioning

confidence: 99%

Cross-talk between Thyroid Hormone Receptor and Liver X Receptor Regulatory Pathways Is Revealed in a Thyroid Hormone Resistance Mouse Model

Hashimoto

Cohen

Yamada

et al. 2006

Hypercholesterolemia is found in patients with hypothyroidism and resistance to thyroid hormone. In this study, we examined cholesterol metabolism in a thyroid hormone receptor ␤ (TR-␤) mutant mouse model of resistance to thyroid hormone. Whereas studies of cholesterol metabolism have been reported in TR-␤ knock-out mice, generalized expression of a non-ligand binding TR-␤ protein in this knock-in model more fully recapitulates the hypothyroid state, because the hypothyroid effect of TRs is mediated by the unliganded receptor. In the hypothyroid state, a high cholesterol diet increased serum cholesterol levels in wild-type animals (WT) but either did not change or reduced levels in mutant (MUT) mice relative to hypothyroidism alone. 7␣-Hydroxylase (CYP7A1) is the rate-limiting enzyme in cholesterol metabolism and mRNA levels were undetectable in the hypothyroid state in all animals. triiodothyronine replacement restored CYP7A1 mRNA levels in WT mice but had minimal effect in MUT mice. In contrast, a high cholesterol diet markedly induced CYP7A1 levels in MUT but not WT mice in the hypothyroid state. Elevation of CYP7A1 mRNA levels and reduced hepatic cholesterol content in MUT animals are likely because of cross-talk between TR-␤ and liver X receptor ␣ (LXR-␣), which both bind to a direct repeat ؉ 4 (DR؉4) element in the CYP7A1 promoter. In transfection studies, WT but not MUT TR-␤ antagonized induction of this promoter by LXR-␣. Electromobility shift analysis revealed that LXR/RXR heterodimers bound to the DR؉4 element in the presence of MUT but not WT TR-␤. A mechanism for cross-talk, and potential antagonism, between TR-␤ and LXR-␣ is proposed.