Acute effects of pentobarbital-anaesthesia on bile secretion

Cyclosporin a and enterohepatic circulation of bile salts in rats: decreased cholate synthesis but increased intestinal reabsorption

Cyclosporin A (CsA) has been shown to inhibit synthesis and hepatobiliary transport of bile salts. However, effects of CsA on the enterohepatic circulation of bile salts in vivo are largely unknown. We characterized the effects of CsA on the enterohepatic circulation of cholate, with respect to synthesis rate, pool size, cycling time, intestinal absorption, and the expression of relevant transporters in liver and intestine in rats. CsA (1 mg. 100 g(-1). day(-1) s.c.) or its solvent was administered daily to male rats for 10 days. Cholate synthesis rate and pool size were determined by a 2H4-cholate dilution technique. Bile and feces were collected for determination of cholate and total bile salts, respectively. Cycling time and intestinal absorption of cholate were calculated. The mRNA levels and corresponding transporter protein levels in liver and intestine were assessed by real-time polymerase chain reaction and Western analysis, respectively. CsA treatment decreased cholate synthesis rate by 71%, but did not affect pool size or cycling time. CsA reduced the amount of cholate lost per enterohepatic cycle by approximately 70%. Protein levels of the apical sodium-dependent bile salt transporter (Asbt) were 2-fold increased in distal ileum of CsA-treated rats, due to post-transcriptional events. In conclusion, chronic CsA treatment markedly reduces cholate synthesis rate in rats, but does not affect cholate pool size or cycling time. Our results strongly suggest that CsA enhances efficacy of intestinal cholate reabsorption through increased Asbt protein expression in the distal ileum, which contributes to maintenance of cholate pool size in CsA-treated rats.

Entry of [(1,2-13C2)acetyl]-L-carnitine in liver tricarboxylic acid cycle and lipogenesis: a study by 13C NMR spectroscopy in conscious, freely moving rats

The biochemical pathways involved in acetyl-L-carnitine utilization were investigated in conscious, freely moving rats by 13C NMR spectroscopy. Following 4-h [(1,2-13C2)acetyl]-L-carnitine infusion in fasted animals, the free carnitine levels in serum were increased, and an efflux of unlabelled acetyl-L-carnitine from tissues was observed. [(1,2-13C2)Acetyl]-L-carnitine was found to enter biosynthetic pathways in liver, and the acetyl moiety was incorporated into both cholesterol and 3-hydroxybutyrate carbon skeleton. In accord with the entry of [(1,2-13C2)acetyl]-L-carnitine in the mitochondrial acetylCoA pool associated with tricarboxylic acid cycle, the 13C label was also found in liver glutamate, glutamine, and glutathione. The analysis of the 13C-labelling pattern in 3-hydroxybutyrate and cholesterol carbon skeleton provided evidence that the acetyl-L-carnitine-derived acetylCoA pool used for ketone bodies synthesis in mitochondria was homogeneous, whereas cholesterol was synthesized from two different acetylCoA pools located in the extra- and intramitochondrial compartment, respectively. Furthermore, cholesterol molecules were shown to be preferentially synthesized by the metabolic route involving the direct channelling of CoA-activated mitochondria-derived ketone bodies into 3-hydroxy-3-methylglutarylCoA pathway, prior to equilibration of their acyl groups with extramitochondrial acetylCoA pool via acetoacetylCoA thiolase.

Contribution of newly synthesized cholesterol to rat plasma and bile determined by mass isotopomer distribution analysis: bile-salt flux promotes secretion of newly synthesized cholesterol into bile

To quantify the contribution of newly synthesized cholesterol to total plasma and biliary cholesterol under physiological conditions, unrestrained rats were infused intravenously with [1-13C]acetate (0. 6mmol/h per kg) from 12:00 to 24:00 h, and fractional and absolute cholesterol-synthesis rates were determined by mass isotopomer distribution analysis (MIDA). As bile diversion leads to changes in cholesterol metabolism, rats were equipped with permanent catheters in the bile duct and duodenum, allowing sampling of small amounts of bile from an intact enterohepatic circulation. For comparison, rats with chronic bile diversion were also studied. Fractional synthesis of plasma cholesterol was 10.8+/-1.7% (mean+/-S.D.) after 12 h in rats with intact circulation. Fractional synthesis of biliary cholesterol was significantly higher than that of plasma cholesterol, i.e. 16.5+/-2.0% (P<0.05) after 12 h. In contrast, no differences between fractional synthesis of cholesterol in plasma and bile were found in bile-diverted animals (31.8+/-2.1 and 33.1+/-3.3% respectively after 12 h). The calculated absolute rate of cholesterol biosynthesis increased from 53+/-10 to 221+/-19 micromol/day per kg after bile diversion. A comparison of MIDA results with those obtained from balance studies indicated that MIDA does not assess total body synthesis in rats, presumably because of incomplete equilibration of newly synthesized molecules with cholesterol in the plasma compartment. These studies demonstrate that the contribution of newly synthesized cholesterol to biliary cholesterol is higher than to plasma cholesterol under physiological conditions, probably reflecting bile-salt-induced secretion of newly formed cholesterol by the periportal hepatocytes.

Metabolite profiles of two [14C]-labelled catechol O-methyltransferase inhibitors, nitecapone and entacapone, in rat and mouse urine and rat bile

The metabolites of two inhibitors of catechol O-methyltransferase, nitecapone [3-(3,4-dihydroxy-5-nitrobenzylidene)2,4-pentanedione] and entacapone [(E)-2-cyano-N,N-diethyl-3-(3,4-dihydroxy-5-nitrophenyl)propenamide++ +], excreted in urine and bile by rats and in urine by mice, were compared and quantified by using HPLC with radiochemical detection after administration of [14C]-labelled compounds. With the exception of 3-O-methylated nitecapone, no major metabolites were found in rat bile that were not found in rat urine. For both compounds the major biotransformations were the same in the mouse and the rat. However, a bisulfite adduct of nitecapone was found in rat urine only, and reduction of the C = C and C = O groups of the nitecapone side chain was more extensive in the mouse. After entacapone administration, the products of amide N-dealkylation were more abundant in rat urine than in mouse urine. Most of the dose was excreted in urine and bile as O-conjugates. Most abundant were the O-glucuronides, while smaller amounts of O-sulfates and O-methylated metabolites were found in both species. One non-glucuronide glycoside of entacapone was found in urine of both rats and mice.

Assessment of hepatobiliary function in vivo and ex vivo in the rat

Many xenobiotics cause hepatobiliary toxicity and cholestasis in the rat. Initial assessment of hepatobiliary damage in rats can be accomplished by measuring serum concentrations of bile acids and bilirubin, serum activities of liver-associated enzymes such as 5'-nucleotidase, alkaline phosphatase, gamma-glutamyltranspeptidase, and plasma clearances of dyes [e.g., bromosulfophthalein (BSP)] excreted primarily through the bile. More detailed evaluation of hepatobiliary disturbances involves cannulation of the bile duct of anesthetized rats and subsequent measurement of rates of bile flow, bile acid excretion, and bile composition. Canalicular bile flow can be estimated from clearances of nonmetabolized sugars (i.e., erythritol) which enter bile via paracellular transport. Tight junction permeability also can be assessed by either biliary excretion of such a marker as horseradish peroxidase or sucrose following portal vein infusion or via retrograde biliary infusion. Subsequent morphologic evaluation of the liver provides information on damage to cells which may contribute to hepatobiliary dysfunction (i.e., bile duct obstruction). Isolated perfused livers offer the ability to measure all of the above mentioned parameters as well as to make a more accurate determination of the effects of xenobiotics on bile acid-dependent and -independent bile flow. A good example of the advantage of combining techniques as well as following complete time courses of changes in hepatobiliary function is provided by using studies of alpha-naphthylisothiocyanate-induced hepatotoxicity.

The effect of felodipine on bile flow in pentobarbital anaesthetized rats and conscious rats receiving bile salt supplementation

Felodipine, a vasoselective dihydropyridine calcium antagonist, has been given i.v. (0.2 mumol/kg) to anaesthetized and conscious male rats. There was no effect of pentobarbital anaesthesia on bile flow over a 6 h observation period. Felodipine increased the 6 h recovery of bile by approximately 25% in the conscious rat but in the anaesthetized rat there was a 20% decrease in bile flow following i.v. felodipine. A positive effect of Na-taurocholate infusion (1 mumol/min/100 g body weight) on bile flow in conscious rats was reinforced by concomitant felodipine dosing. Accumulated 6 h recoveries were 2.32 +/- 0.80 g/100 g body weight (control), 3.09 +/- 0.91 g/100 g body weight (taurocholate) and 5.00 +/- 0.80 g/100 g body weight. (taurocholate plus felodipine). The excretion of felodipine in the bile was significantly reduced during anaesthesia and during infusion of 2% bovine serum albumin (0.01 ml/min/100 g body weight) to conscious rats.

Dietary fish oil-induced changes in intrahepatic cholesterol transport and bile acid synthesis in rats

Hepatic cholesterol metabolism was studied in rats fed purified diets supplemented (9% wt/wt) with either fish oil (FO) (n-3 fatty acids) or corn oil (CO) (n-6 fatty acids) for 4 wk. Rats were equipped with permanent catheters in heart, bile duct, and duodenum to allow studies under normal feeding conditions. [3H]-cholesteryl oleate-labeled small unilamellar liposomes, which are rapidly endocytosed by hepatocytes, were intravenously injected to label intrahepatic cholesterol pools, and plasma and bile were collected. FO as compared to CO induced a lowering of plasma cholesterol levels by 38% and of triglyceride levels by 69%. This reduction in plasma lipids in FO rats was accompanied by: (a) an increased bile acid pool size (28%); (b) a fourfold increase in the ratio cholic acid/chenodeoxycholic acid in bile; (c) increased biliary excretion of cholesterol (51%); (d) accelerated excretion of endocytosed free cholesterol into bile; (e) accelerated incorporation of endocytosed cholesterol in bile acids; (f) a significant increase in the bile acid-independent fraction of bile flow; and (g) a threefold increase in hepatic alkaline phosphatase activity. The results show that FO induces changes in transport and metabolic pathways of cholesterol in the rat liver, which result in a more rapid disposition of plasma-derived cholesterol into the bile.

Short- and long-term effects of biliary drainage on hepatic cholesterol metabolism in the rat

The present study concerns short- and long-term effects of interruption of the enterohepatic circulation (EHC) on hepatic cholesterol metabolism and biliary secretion in rats. For this purpose, we employed a technique that allows reversible interruption of the EHC, during normal feeding conditions, and excludes effects of anaesthesia and surgical trauma. [3H]Cholesteryl oleate-labelled human low-density lipoprotein (LDL) was injected intravenously in rats with (1) chronically (8 days) interrupted EHC, (2) interrupted EHC at the time of LDL injection and (3) intact EHC. During the first 3 h after interruption of the EHC, bile flow decreased to 50% and biliary bile acid, phospholipid and cholesterol secretion to 5%, 11% and 19% of their initial values respectively. After 8 days of bile diversion, biliary cholesterol output and bile flow were at that same level, but bile acid output was increased 2-3-fold and phospholipid output was about 2 times lower. The total amount of cholesterol in the liver decreased after interruption of the EHC, which was mainly due to a decrease in the amount of cholesteryl ester. Plasma disappearance of LDL was not affected by interruption of the EHC. Biliary secretion of LDL-derived radioactivity occurred 2-4 times faster in chronically interrupted rats as compared with the excretion immediately after interruption of the EHC. Radioactivity was mainly in the form of bile acids under both conditions. This study demonstrates the very rapid changes that occur in cholesterol metabolism and biliary lipid composition after interruption of the EHC. These changes must be taken into account in studies concerning hepatic metabolism of lipoprotein cholesterol and subsequent secretion into bile.

The effect of diethyl ether, pentobarbitone and urethane anaesthesia on diflunisal conjugation and disposition in rats

1. The disposition of diflunisal (DF) at 10 mg/kg i.v. was investigated over 4 h in bile-exteriorized male rats continuously anaesthetized with (a) diethyl ether inhalation (as required), (b) pentobarbitone sodium i.p. (55 mg/kg initially), (c) urethane i.p. (1500 mg/kg initially) or (d) urethane i.v. (750 mg/kg initially), and compared to that obtained in conscious rats. 2. Diethyl ether decreased the plasma clearance of DF to about 30% of control values, by inhibition of both glucuronidation and sulphation of DF. 3. Pentobarbitone anaesthesia caused only modest inhibition of DF elimination, with plasma clearance decreased to about 80% of control values. 4. Plasma profiles and biliary recovery of DF and its conjugates were little altered by urethane i.p. anaesthesia, but urinary recovery was low and variable because of the nearanuria produced by urethane via this administration route. 5. Urinary recovery of DF and its conjugates was satisfactory in rats given urethane i.v., but tissue distribution of DF was substantially decreased. 6. Pentobarbitone was considered to interfere least with DF disposition at the 10 mg/kg dose, and was selected as the most suitable anaesthetic agent for ongoing studies of disposition of DF and its conjugates in anaesthetized rats.

Effect of adrenaline on biliary excretion of triiodothyronines in rats mediated by alpha 1-adrenoceptors and related to the inhibition of 5'-monodeiodination in liver

Biliary excretion of thyroxine (T4),3,5,3'-triiodothyronine (T3),3,3,5'-triiodothyronine (rT3) and diiodothyronines (3,3'-T2,3,5-T2 and 3',5'-T2) was estimated with the aid of radioimmunoassay in 3-4 subsequent 2-h samples of bile obtained from pentobarbital anesthetized rats through the tubing inserted in bile duct. The excretion of T3 was significantly decreased during 4-h infusion of 2400 ng/kg/min adrenaline in normal rats or during 6-h infusion of the latter dose in the animals preinjected with 2 micrograms T4. Moreover, the excretion of rT3 was significantly increased after the infusion of 1200 and 2400 ng/kg/min adrenaline. Such increase after 1200 and 2400 ng/kg/min adrenaline was prevented by a single dose of 10 mg/kg phentolamine (alpha 1-2-antagonist) and that after 2400 ng/kg/min adrenaline also by 2.5 mg/kg prazosin (alpha 1-antagonist) injected at the beginning of the infusion, but not by 6 mg/kg yohimbine (alpha 2-antagonist) injected every 60 min during 4-h infusion. In addition, increased rT3 excretion was found during the infusion of alpha 1-agonist methoxamine (1.5 mg/kg/4 h), while no such effect of the infusion of alpha 2-agonist azepexol (10 mg/kg/4 h) was observed. It may be suggested that the effect of adrenaline was mediated predominantly by alpha 1-adrenoceptors and that the observed changes in biliary excretion of T3 and rT3 were related to the inhibition of 5'-monodeiodination in the liver.