The origin of cholesterol in the mesenteric lymph of the rat

These studies were performed to quantitate the amounts of newly synthesized cholesterol secreted in the mesenteric lymph of the rat and to define the origin of this cholesterol. In control animals receiving no dietary fat, the amount of newly synthesized sterol entering the lymph increased linearly with respect to time over 24 hr. When a continuous intravenous infusion of chylomicrons was given or when the animals were prefed a diet containing 2.0% cholesterol to inhibit hepatic, but not intestinal or peripheral, cholesterol synthesis, the secretion of newly synthesized sterol in lymph was markedly suppressed, suggesting that the liver was its ultimate site of origin. When the animals were subjected to either blockade of intestinal cholesterol absorption or biliary diversion, there was a decrease in both the newly synthesized and total mass of cholesterol in lymph by approximately 60%, indicating that the majority was normally derived from the absorption of luminal (primarily biliary) sterol. In the absence of dietary cholesterol, the remainder was probably derived from plasma lipoproteins that were filtered through the intestinal capillaries into the lymph. In contrast, when lymph was collected during active fat absorption, the intestine was found to secrete sterol newly synthesized by the epithelium. Such newly synthesized cholesterol was found predominantly in the unesterified fraction and accounted for approximately 27% of the total sterol found in lymph at the end of the experiment. From these studies it was concluded that in the absence of fat absorption, sterol synthesized in the intestinal mucosa was incorporated predominantly into cell membranes and did not enter intestinal lymph to any significant degree. However, during fat absorption, a fraction of this newly synthesized sterol pool was incorporated into lipoproteins and so was delivered through the intestinal lymph to the body pools of cholesterol.     

Synthesis and coenzyme A-dependent esterification of cholesterol in rat intestinal epithelium. Differences in cellular localization and mechanisms of regulation

The current studies were undertaken to characterize the localization and regulation of cholesterol synthesis and acyl-CoA:cholesterol acyltransferase activity in rat intestinal crypt and villus cells. Both parameters were determined in groups of animals with widely varying sterol fluxes across the intestinal mucosa. In animals on control diet the rates of cholesterol synthesis, measured by the incorporation of [3H]water per mg of protein, were similar along the villus/crypt axis in the jejunum, whereas in the ileum, villus cells were significantly more active than crypt cells. In both areas, however, the majority of total synthetic activity was found in cells from the crypts and lower villi. In contrast, the highest specific and total acyl-CoA:cholesterol acyltransferase activity was recovered in the villus cells of the jejunum and ileum. Dietary cholesterol did not affect sterol synthesis in any of the cell fractions but increased acyl-CoA:cholesterol acyltransferase activity approximately 2-fold in jejunal cell fractions. Inhibition of cholesterol absorption or sequestration of intestinal bile acids stimulated sterol synthetic activity up to 7-fold, and this occurred mainly in the lower villus and crypt cells in both jejunum and ileum. An increased demand for lipoprotein cholesterol, generated by triglyceride feeding, similarly was associated with enhanced synthetic rates. However, unlike cholesterol feeding, these manipulations did not increase acyl-CoA:cholesterol acyltransferase activity in any of the villus cell fractions. These studies suggest, therefore, that the intracellular pools of cholesterol that regulate the rate of cholesterol synthesis and the rate of cholesterol esterification are functionally distinct.     

Mechanisms for the intestinal absorption of bile acids

In this review experimental data are summarized which indicate that at least four different transport mechanisms account for net movement of bile acids across the gastrointestinal tract. These are active transport and the passive mechanisms of ionic, nonionic, and micellar diffusion. Of these four, active transport and passive nonionic diffusion are quantitatively of the greatest importance. Active transport is confined to the ileum and probably plays a dominant role in the absorption of conjugated bile acids. Passive nonionic diffusion may occur at any level of the gastrointestinal tract and probably is the major mechanism for the absorption of unconjugated bile acids.     

Knockout of the cholesterol 24-hydroxylase gene in mice reveals a brain-specific mechanism of cholesterol turnover

Most cholesterol turnover takes place in the liver and involves the conversion of cholesterol into soluble and readily excreted bile acids. The synthesis of bile acids is limited to the liver, but several enzymes in the bile acid biosynthetic pathway are expressed in extra-hepatic tissues and there also may contribute to cholesterol turnover. An example of the latter type of enzyme is cholesterol 24-hydroxylase, a cytochrome P450 (CYP46A1) that is expressed at 100-fold higher levels in the brain than in the liver. Cholesterol 24-hydroxylase catalyzes the synthesis of the oxysterol 24(S)-hydroxycholesterol. To assess the relative contribution of the 24-hydroxylation pathway to cholesterol turnover, we performed balance studies in mice lacking the cholesterol 24-hydroxylase gene (Cyp46a1-/- mice). Parameters of hepatic cholesterol and bile acid metabolism in the mutant mice remained unchanged relative to wild type controls. In contrast to the liver, the synthesis of new cholesterol was reduced by approximately 40% in the brain, despite steady-state levels of cholesterol being similar in the knockout mice. These data suggest that the synthesis of new cholesterol and the secretion of 24(S)-hydroxycholesterol are closely coupled and that at least 40% of cholesterol turnover in the brain is dependent on the action of cholesterol 24-hydroxylase. We conclude that cholesterol 24-hydroxylase constitutes a major tissue-specific pathway for cholesterol turnover in the brain.     

Age-related decreases in tissue sterol acquisition are mediated by changes in cholesterol synthesis and not low density lipoprotein uptake in the rat

The present investigation compared plasma cholesterol levels and lipoprotein profiles, and absolute rates of sterol synthesis and low density lipoprotein (LDL) uptake in various organs of immature (4 weeks old) and mature (15 weeks) rats. The plasma cholesterol level and its distribution among the major lipoprotein density fractions were similar in both groups. Using [3H]water as a substrate for measuring sterol synthesis in vivo, the content of newly synthesized cholesterol (3H-labeled digitonin-precipitable sterols; [3H]DPS) was several fold higher in all tissues of the young, compared to the old, rats when normalized per g of tissue. In contrast, whole-body [3H]DPS content was identical at 29.5 and 29.3 mumol/hr in young and old rats, respectively, despite a 4.4-fold difference in body weight (102 vs. 453 g). The importance of different organs to total-body sterol synthesis remained similar with increasing age although the skin (11 vs. 24% of total) rather than the small bowel (15 vs. 8%) became the second most important organ after the liver (49 vs. 45%) in the older animals. When LDL uptake was determined in these same organs, using constant infusion technique, the rates of clearance were higher only in the adrenal glands, adipose tissue, and skin of the young animals; whereas these rates were essentially the same in the liver and gastrointestinal tract, the two organs that are quantitatively most important for LDL catabolism. Even when these clearance rates were normalized to the whole organ or to 100 g of body weight, the differences in LDL uptake in the two age groups were minor compared to the major decrease in rates of cholesterol synthesis that were observed with aging. Finally, calculation of absolute rates of tissue cholesterol acquisition from both sources indicated that, in most organs, the majority of tissue cholesterol was derived from local synthesis rather than from LDL uptake in both age groups and that, with increasing age, total cholesterol acquisition decreased several-fold primarily as a consequence of the diminished rate of sterol synthesis. These studies demonstrate that with growth and aging in the rat there is a dramatic decrease in the rate of tissue cholesterol synthesis while the uptake of LDL-cholesterol remains essentially unchanged.