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Changes in hepatic metabolic enzyme activities and biliary excretion of 4-nitrophenol in streptozotocin induced diabetic rats

Abstract

Activity of hepatic metabolic enzymes of glucuronidation and sulfation of 4-nitrophenol (PNP) and biliary excretion of its glucuronide (PNP-G) and sulfate (PNP-S) conjugates have been investigated in control and streptozotocin (STZ)-induced diabetic rats. 500 μM PNP solution was luminally perfused in a cannulated jejunal loop for 90 minutes. It was found that biliary excretion of PNP-G was significantly decreased in the diabetic rats. This effect of STZ could be completely reversed by administration of rapid-acting insulin. Activity of hepatic UDP-glucuronyltransferase and β-glucuronidase was also depressed by the STZ pretreatment. Administration of insulin antagonized the inhibitory action of STZ on UDP-glucuronyltransferase, but the reduced activity of β-glucuronidase was not reversed. Biliary excretion of PNP-S was also depressed in the diabetic rats. Whereas, different effects of insulin administration were observed. Namely, the lower biliary excretion rate of PNP-S was not changed after administration of insulin. Activity of the sulfotransferase and the arylsulfatase enzymes was not altered either by STZ pretreatment or by insulin administration. Biliary excretion of PNP was also significantly depressed by STZ and this depression was not changed after insulin administration. The results call attention to hepatobiliary circulation of low molecular weight xenobiotics and their glucuronide and sulfate conjugates.

Keywords:
4-Nitrophenol; Hepatic excretion; Glucuronide conjugate; Sulfate conjugate; Experimental diabetes.

INTRODUCTION

Orally administered drugs, before they reach the systemic blood circulation, can be metabolized in the intestinal tract and the liver. Biotransformation of drugs before entering the systemic circulation is referred to as first pass metabolism. Numerous (Phase I. and Phase II.) reactions are involved in biotransformation of xenobiotics in the liver and small intestine (Linn, Chiba, Baillie, 1999Linn LH, Chiba M, Baillie TA. Is the role of the small intestine in first-pass metabolism overemphasized? Pharm Rev. 1999;51(2):135-151.; Parkinson et al., 2013Parkinson A, Ogilvie BW; Buckley DB, Kazmi F, Czerwinski M, Parkinson O. Biotransformation of Xenobiotics. In: Casarett and Doull's toxicology: the basic science of poisons, 8th Ed. (Klaassen CD, Ed.). New York: McGraw-Hill Education; 2013; Chap. 6; p. 185-366.). Phenolic compounds are generally metabolized by Phase II reactions. In the present experiments 4-nitrophenol (PNP) was used as a model substance, because it is known to be metabolized almost exclusively by glucuronidation and sulfation (Kuhn, Rost, Müller, 2001Kuhn MD, Rost M, Müller D. Para-nitrophenol glucuronidation and sulphatation in rat and human slices. Exp Toxic Pathol. 2001;53(1):81-87.) producing 4-nitrophenol-glucuronide (PNP-G) and 4-nitrophenol-sulfate (PNP-S). These reactions are catalyzed by UDP- glucuronyltransferases (Tukey, Strassburg, 2000Tukey RH, Strassburg CP. Human UDP-glucuronosyltransferases: metabolism, expression and disease. Ann Rev Pharmacol Toxicol. 2000;40:581-616.; Parkinson et al., 2013) and sulfotransferases (Capiello et al., 1989Capiello M, Franchi M, Giuliani L, Pacifici GM. Distribution of 2-naphthol sulfotransferase and its substrate adenosine 3-phosphate 5-phosphosulfate in human tissues. Eur J Clin Pharmacol. 1989;37(3):317-320.; Maiti et al., 2004Maiti S, Grant S, Baker SM, Karanth S, Pope CN, Chen G. Stress regulation of sulfotransferases in male rat liver. Biochem Biophys Res Commun. 2004;323(1):235-241.; Parkinson et al., 2013) in the liver and the small intestine. Esterases (β-glucuronidase and arylsulfatase) play also an important role in biotransformation of drugs, because these enzymes can hydrolyze the glucuronide and the sulfate conjugates (Danovitch, Laster, 1969Danovitch SH, Laster R. The development of arylsulfatase in the small intestine of the rat. Biochem J. 1969;114(2):343-350.; Parkinson et al., 2013).

Several factors, e.g. drug interactions, nutrient deficiencies, pathological alterations, diseases including diabetes can influence metabolism of drugs (Liu et al., 2012Liu H, Wu B, Pan G, He I, Li Z, Fan M, Jian L, Chen M, Wang K, Huang C. Metabolism and pharmacokinetics of mangiferin in conventional rats, pseudo-germ free rats, and streptozotocin-induced diabetic rats. Drug Metab Dispos. 2012;40(11):2109-2118.; Tormo et al., 1995Tormo MA, Gómez-Zubeldia MA, Roppero F, Muñoz-Casillas M, Moreno JC, Campillo JE. Experimental streptozotocin-reduced diabetes and intestinal glucose metabolism in the rat, in vivo and in vitro. Acta Diabetol. 1995;32(3):182-186.; Watkins, Dykstra, 1987Watkins JBIII, Dykstra TP. Alterations in biliary excretory function by streptozotocin-induced diabetes. Drug Metab Dispos. 1987;15(2):177-183.). Experimental diabetes is generally produced by i.v. administration of streptozotocin (STZ) in a dose of 65 mg/kg in rats, which causes a destruction of pancreatic β-cells. Diabetes can provoke several effects on carbohydrate and lipid metabolism, intermediary processes as well as on drug metabolism and hepatic and intestinal transport of drugs, (Fischer, Lauterbach, 1984Fischer E, Lauterbach F. Effect of hyperglycaemia on sugar transport in the isolated mucosa of guinea-pig small intestine. J Physiol. 1984;355:367-386.; Tomkin, Owens, 2015Tomkin GH, Owens D. Dyslipidaemia of diabetes and the intestine. World J Diabetes. 2015;6(7):970-977.). Little definitive data are available, however, concerning the effects of diabetes on the excretory function of the liver, the metabolic enzyme activities and the role of insulin in these processes and alterations.

In our previous experiments effect of diabetes on the excretory function of the small intestine and the activities of the related enzymes were investigated (Fischer et al., 2015Fischer E, Almási A, Bojcsev S, Fischer T, Kovács NP, Perjési P. Effect of experimental diabetes and insulin replacement on intestinal metabolism and excretion of 4-nitrophenol in rats. Can J Physiol Pharmacol. 2015;93(6):459-464.). The results indicated that experimental diabetes increased intestinal glucuronidation of PNP but did not influence sulfate conjugation.

The present experiments were designed to study the effects of STZ-induced experimental diabetes on the hepatic elimination of PNP during its luminal perfusion in a jejunal loop of rats. For this purpose, biliary excretion of PNP-G and PNP-S as well as activities of hepatic UDP-glucuronyltransferase, β-glucuronidase, sulfotransferase and arylsulfatase enzymes were determined to get information about the relationship between the biliary excretion rates and the respective enzyme activities. The prompt effect of the insulin was also studied on biliary excretion of the PNP metabolites and the enzyme activities in the diabetic rats.

MATERIAL AND METHODS

Chemicals

4-nitrophenol (PNP), 4-nitrophenol-ß-glucuronide (PNP-G), 4-nitrophenol-sulfate (PNP-S), 4-ethylphenol (ETP), streptozotocin (STZ), tetrabutyl ammonium bromide (TBAB), phenolphthalein-ß-glucuronide, uridine 5’-diphosphoglucuronic acid (UDPGA), 3’-phosphoadenosine-5-phosphosulphate (PAPS), nitrocatechol (NC)-sulfate, 4-naftol, Brij56®, HEPES, DL-dithiothreithol were obtained from Sigma Aldrich Company (Budapest, Hungary). All other chemicals and reagents were analytical or HPLC grade. The standard isotonic perfusion medium had the following composition (mmol/l): NaCl 96.4, KCl 7.0, CaCl2 3.0, MgSO4 1.0, sodium phosphate buffer (pH 7.4) 0.9, TRIS buffer (pH 7.4) 29.5, glucose 14.0, mannitol 14.0.

Animals and experimental procedure

Male Wistar rats (weighing 220-250 g) were randomly separated into three groups of seven rats each. In group I and II experimental diabetes was induced by i.v. administration of STZ (65 mg/kg bw). Control animals (group III) were treated with saline. Experimental procedure was performed after one week of the STZ-treatment. Rats of group II were treated with rapid-acting insulin (Actrapid) (1 IU/kg bw, i.v.) just before the anesthesia. Liver and bile samples were obtained from the same rats of the three different groups of rats (control, STZ-pretreated with or without insulin).

The animals were anesthetized with urethane (1.2 g/kg bw, i.p.). The abdomen was opened by a mid-line incision and a jejunal loop (length about 10 cm) was isolated and cannulated in vivo. Body temperature was maintained at 37 °C with a heat lamp. The lumen of the jejunal loop was gently flushed with warmed isotonic solution to remove digesta and food residues and then blown empty with 4-5 mL of air. Perfusion through the lumen of the jejunal loop with isotonic medium containing 500 µM PNP was carried out at a rate of 13 ml/min in a recirculation mode for 90 minutes. The initial volume was 15 mL. The temperature of perfusion medium was maintained constant at 37 °C. Bile was collected in 15 minute-periods into tared Eppendorf tubes placed in ice. The collected samples were stored in refrigerator (-20 oC) until analysis. Bile flow was measured gravimetrically assuming a specific gravity of 1.0. Biliary excretion was calculated as the product of the concentration in bile and bile flow.

Analytical conditions, instrumentation

Bile samples were analyzed by a UV-Vis RP-HPLC method, as it was developed and published earlier (Almási et al., 2011Almási A, Fischer E, Perjési P. Isocratic ion-pair HPLC method for quantitation of 4-nitrophenol and it's conjugated metabolites from bile. Sci Pharm. 2011;79(4):837-847.). Briefly, 50 µL of bile samples was mixed and vortexed with cold methanol in a total volume of containing 2.5 mM ETP as internal standard. A mixture of 0.01 M citrate buffer (pH 6.2) and methanol (47:53 v/v%) containing 0.03 M tetrabutyl ammonium bromide was used as a mobile phase. The flow rate of the mobile phase was 1.0 mL.min-1.

The HPLC system consisted of a Varian 2010 pump, a Rheodyne 7724i injection valve and a UV-Detector 308 (Labor MIM, Budapest, Hungary). Data were recorded and evaluated by a PowerChrom 280 data module and software (ADInstruments, Sydney, Australia). Separation of compounds was performed on a Nucleosyl 100 C18 reversed phase analytical column (250 mm x 4.6 mm I.D., 10 µm particle size) with a TR-C-160K1 ODS guard column. UV measurements were performed on a Pye Unicam (Philips) PU 8800 UV-Vis spectrophotometer (Philips, Cambridge, UK) at ambient temperature. Injection volume was 20 μL.

A Mettler Toledo MP 220 pH meter and a Mettler Toledo Inlab 413 electrode (Mettler Toledo, Budapest, Hungary) were used to adjust the pH of the electrolyte solutions.

Enzyme assays

UDP-glucuronyltransferase and ß-glucuronidase assays

UDP-glucuronytransferase assay

Liver obtained from control (isotonic medium) and perfused (500 μM PNP) rats were gently dissected and immediately frozen and stored at - 80 °C temperature. 250 - 500 mg liver samples were dissected and placed into 2.5-5 mL of cold (4 °C) homogenization buffer (250 mM sucrose, 1 mM DL-dithiothreithol, 10 mM Hepes-Tris buffer pH 8.0) and disrupted using an Ultra-Turrax and Potter-Elvehjem homogenizers.

After disruption, the homogenate was diluted with the homogenization buffer to have a protein concentration of 1 mg/ml. Quantification of protein was performed in each enzyme assay by the biuret method (van Norman, 1909).

UGT enzyme activity assays were carried out in an incubation mixture of 100 μL of liver homogenate (1 mg/ml protein) and 100 μL of incubation buffer (200 mM Tris-HCl, 10 mM MgCl2, 0.1 % Brij56® pH 7.4) containing 2 mM PNP. Half of the incubates contained 5 mM UDPGA in the total volume. After 30 min incubation at 37 °C, the reaction was quenched by adding 3.8 ml of 0.1 M ice cold NaOH and the absorbance of the unconjugated PNP was measured at 405 nm. Specific UGT activity was calculated on the base of metabolized PNP and expressed in μmol PNP/mg/min (Capiello, Giuliani, Pacifici, 1991Capiello M, Giuliani L, Pacifici GM. Distribution of UDP-glucuronyltransferase and its endogenous substrate uridine 5-diphosphoglucuronic acid in human tissues. Eur J Pharmacol. 1991;41(4):345-350.).

β-Glucuronidase assay

Dissection, storage and homogenization of liver samples were the same as described for the UDP-glucuronyltransferase assay. ß-Glucuronidase activity assays were carried out in an incubation mixture of 100 μL of liver homogenate (1 mg/mL protein) and 150 μL of 70 mM pH 5.0 acetate buffer. Half of the incubates contained 1 mM phenolphthalein-β-glucuronide in the total volume. After 60 min incubation at 37 °C the reaction was quenched by adding 250 μL of ice cold 5% trichloroacetic acid. Samples were neutralized by adding 0.22 M glycine solution of pH 12.9. The absorbance was measured at 540 nm. β-Glucuronidase activity was calculated on the base of the metabolized phenolphthalein and it is expressed in the amount of the formed free phenolphthalein: µmol/mg/min. The mixture of the acetate buffer, the glycine solution and distilled water was used as a reference (Fishman, 1974Fishman WH. ß-Glucuronidase. In: Bergmeyer HU (Ed). Methods of Enzymatic Analysis New York: Academic Press; 1974; p. 929-943.).

Sulfotransferase and arylsulfatase assays

Sulfotransferase assay

Dissection, storage and homogenization of liver samples were the same as described for the UDP-glucuronyltransferase assay. Liver was quickly dissected and immediately frozen and stored at -80 °C until analysis. Homogenization was performed in cold (4 °C) homogenization buffer (250 mM sucrose, 1 mM DL-dithiothreithol, 10 mM Hepes-Tris buffer pH 8.0).

Determination of sulfotransferase activity was carried out with incubation of 100 μL of liver homogenate and 400 μl of incubation buffer (62.5 mM Tris buffer, pH 6.2) containing 25 μM PAPS, 125 μM 2-naftol, and 6.25 mM 4-nitrophenol sulfate. The reaction was started by addition of the homogenate to the incubation buffer.

After 30 min incubation at 37 °C the reaction was quenched by adding 500 μL of 0.25 M Tris buffer, pH 8.7. Absorption of the formed 4-nitrophenol was measured at 401 nm. Reference solution contained homogenization buffer without organ homogenate (Maiti et al., 2004Maiti S, Grant S, Baker SM, Karanth S, Pope CN, Chen G. Stress regulation of sulfotransferases in male rat liver. Biochem Biophys Res Commun. 2004;323(1):235-241.). The advantage of this assay is that the sulfotransferases also catalyze the sulfuryl group transfer from PNP-S to regenerate PAP-S and the forming PNP can be easily detected by UV-Vis spectrophotometry.

• Arylsulfatase assay

Dissection, storage and homogenization of liver samples were the same as described for the UDP-glucuronyltransferase assay.

Determination of arylsulfatase activity was carried out with incubation of 50 μL of liver homogenate and 400 μL of incubation buffer (in a concentration of 0.25 M sodium-acetate buffer pH 5.5) containing 0.01 M nitrocatechol sulfate. The reaction was started by adding the homogenate to the incubation buffer. After 30 min incubation at 37 °C the reaction was quenched by adding 500 uL of 5 m/v% trichloroacetic acid. Thereafter the mixture was centrifuged at 1600 x g for 10 minutes. Then 500 μL of supernatant was added to 500 μL of 5 M NaOH solution and absorption of the formed nitrocatechol was measured at 520 nm. Reference solution contained homogenization buffer instead of the homogenate (Danovitch, Laster, 1969Danovitch SH, Laster R. The development of arylsulfatase in the small intestine of the rat. Biochem J. 1969;114(2):343-350.).

Calculations, statistical analysis

Enzyme activities are expressed in the amounts of substrates or metabolites (µmol glucuronide and nmol sulfate) calculated for 1 mg protein and 1 minute (details in “Enzyme assays” and “Results”).

The biliary excretion rate of PNP and the metabolites were calculated on the base of their concentration in the bile and the volume of the biliary flow. Data show the mean ± S.E. of seven experiments.

Data were analyzed by one-way ANOVA, the difference among groups was determined by post hoc Tukey test and (p<0.05) was significant.

Ethical approval

All procedures were carried out on animals according to the Hungarian Animal Protection Act (Hungarian Act XXVIII, 1998). The study was approved by the Ethics Committee on Animal Research of the University of Pécs.

RESULTS

The blood glucose level of the experimental animals was 8.61 ± 1.59 mmol/L in the control, 27.1 ± 4.04 mmol/L in the diabetic, and 9.49 ± 3.88 mmol/L in the diabetic rats with insulin treatment.

The bile flow was determined for each 15 minute-period. The obtained data are summarized in Table I. As it shown STZ treatment statistically did not change the bile flow rate. On the contrary, insulin treatment resulted in statistically significant increase of the bile flow rate in comparison to both the STZ-nontreated and the STZ-treated groups.

TABLE I
The 15-minute period bile flows (µL/kg/min) in the various experimental groups

Figure 1 shows the cumulative biliary excretion (sum of the excreted amounts in 90 minutes) of PNP-G at the luminal perfusion of 500 μM PNP. Significantly lower amount of PNP-G was excreted into the bile in diabetic rats than in the controls. Depression of biliary excretion of PNP-G was compensated by rapid-acting insulin administration.

FIGURE 1
Cumulative biliary excretion of PNP-G after the 90-min luminal perfusion of 500 µM PNP in control and diabetic rats without or with insulin administration. Data represent the mean of ± S.E. of seven rats. Significant difference from the control value: ** p<0.01. Significant difference from the value of STZ-diabetic rats without insulin administration: ## p<0.01.

Figure 2 and Figure 3 summarize activities of the enzymes which play important role in synthesis (UDP-glucuronyltransferase) and hydrolysis (β-glucuronidase) of PNP-G in the liver. As Figure 2 shows, activity of UDP-glucuronyltransferase was significantly decreased in the diabetic rats. The depression was antagonized by insulin administration. The results show parallelism with alterations of biliary excretion of PNP-G in the respective groups.

FIGURE 2
Activity of UDP-glucuronyltransferase of the liver in control and diabetic rats without or with insulin administration. Values represent the mean ± S.E. of seven rats. Significant difference from the control value: ** p<0.01. Significant difference from the value of STZ-diabetic rats without insulin administration: ## p<0.01. The enzyme activity is expressed in μmol PNP/mg/min, which was conjugated in 1 minute calculated for 1 mg protein of the liver.

FIGURE 3
Activity of β-glucuronidase of the liver in control and diabetic rats without or with insulin administration. Values represent the mean ± S.E. of seven rats. Significant difference from the control value: ** p<0.01. Significant difference from the value of STZ-diabetic rats without insulin administration: ## p<0.01. The columns show the amount of phenolphthalein formed from its glucuronide in 1 minute calculated for 1 mg liver protein.

Similarly to UDP-glucuronyltransferase, a decreased activity of β-glucuronidase was observed in the diabetic rats (Figure 3). This decrease, however, was less pronounced than that measured for the corresponding transferase. The depressed activity was not reversed by insulin administration.

The cumulative biliary excretion of PNP-S is shown in Figure 4. STZ-pretreatment significantly decreased biliary excretion of PNP-S in comparison to the control values. These results indicate that alteration in the biliary excretion of PNP-S shows the same tendency observed for PNP-G. Insulin administration, however, could not reverse the depressed biliary excretion rate of PNP-S in the diabetic rats. No significant difference was found between the values of the STZ-pretreated rats with or without insulin administration.

FIGURE 4
Cumulative biliary excretion of PNP-S after the 90-min luminal perfusion of 500 µM PNP in control and diabetic rats without or with insulin administration. Data represent the mean of ± S.E. of seven rats. Significant difference from the control value: ** p<0.01. No significant difference was found between the values of STZ-diabetic rats without or with insulin administration.

Sulfotransferase activity of the liver was not changed either by STZ or insulin treatment (Figure 5). No significant difference was observed between the values of the control and the diabetic rats without or with insulin treatment.

FIGURE 5
Activity of sulfotransferase of the liver in control and diabetic rats without or with insulin administration. Values represent the mean ± S.E. of seven rats. The sulfotransferase activity is expressed in nmol PNP-S, which was produced in 1 minute calculated for 1 mg liver protein.

Figure 6 illustrates hepatic activity of arylsulfatase. No significant difference was observed between the values of control and STZ-pretreated rats without or with insulin. These finding shows similarity to that of the corresponding change of sulfotransferase activity.

FIGURE 6
Activity of arylsulfatase of the liver in control and diabetic rats without or with insulin administration. Values represent the mean ± S.E. of seven rats. Data expressed in nmol of 4-nitrocatechol (4-NC), which was produced from 4-NC sulfate in 1 minute calculated for 1 mg liver protein.

Data of Figure 7 shows that experimental diabetes produced by STZ significantly decreased biliary excretion of the unconjugated PNP. It can also be seen that insulin was unable to antagonize the decreasing effect of STZ pretreatment on the biliary excretion rate of PNP.

FIGURE 7
Cumulative biliary excretion of PNP after the 90-min luminal perfusion of 500 µM PNP in control and diabetic rats without or with insulin administration. Data represent the mean of ± S.E. of seven rats. Significant difference from the control value: ** p<0.01. No significant differences were found between the values of STZ-diabetic rats without or with insulin administration.

DISCUSSION

The effect of STZ-induced experimental diabetes has been investigated on biliary excretion of PNP and its conjugated metabolites (PNP-G, PNP-S) as well as on activity of the respective metabolic enzymes, while PNP was luminally perfused in the jejunal loop of anesthetized rats. The pathological state induced by STZ administration, due to its specific B-cell cytotoxicity, is considered to closely resemble that of insulin-dependent diabetes mellitus (Agarwal, 1980Agarwal MK. Streptozotocin: mechanisms of action. FEBS Lett. 1980;120(1):1-3.). STZ-doses of 50-65 mg/kg bw lead to hyperglycemia (20-30 mmol/L) but severe ketosis does not develop even if insulin is not administered (Wei et al, 2003Wei M, Ong L, Smith MT, Ross FB, Schmid K, Hoey AJ, Burstow D, Brown L. The streptozotocin-diabetic rat as a model of the chronic complications of human diabetes. Heart Lung Circulation. 2003;12(1):44-50.). Such a treatment is also useful as a model of phrenic nerve neuropathy in the rats (Rodrigues Filho, Fazan, 2006Rodrigues Filho OA, Fazan VPS. Streptozotocin induced diabetes as a model of phrenic nerve neuropathy in rats. J Neurosci Meth. 2006;151(2):131-138.). The experiments were performed 1 week after the STZ treatment. By that time the expected hyperglycemia (27 mmol/L) has been developed.

Earlier results showed that bile flow rate in STZ-treated rats is a function of time after administration of STZ: bile flow is diminished immediately for several days after STZ injection, whereas the flow is normal one month after STZ (Stone et al., 1997Stone JL, Braunstein JB, Beaty TM, Sanders RA, Watkins JB III. Hepatobiliary excretion of bile acids and rose bengal in streptozotocin-induced and genetic diabetic rats. J Pharmacol Exp Ther. 1997;281(1):412-419.; Boyer, 2013Boyer JL. Bile formation and secretion. Compr Physiol. 2013;3(3):1035-1078.). This might be the reason why some authors have reported decreased (Andrews, Griffiths, 1984Andrews SM, Griffiths LA. The metabolism and disposition of [2-14C]diazepam in the streptozotocin-diabetic rat. Xenobiotica. 1984;14(10):751-760.; Carnovale, Rodriguez-Garay, 1984Carnovale CE, Rodriguez-Garay EA. Reversible impairment of hepatobiliary function induced by streptozotocin in the rat. Experientia 1984;40(3):248-250.) whereas others have reported normal bile flow or even choleresis (Watkins, Dyktsra, 1987Watkins JBIII, Dykstra TP. Alterations in biliary excretory function by streptozotocin-induced diabetes. Drug Metab Dispos. 1987;15(2):177-183.; Watkins, Sherman, 1992). In long term diabetes, however, several other factors - change in steady state volume of distribution and in some pharmacokinetic parameters (transport proteins, bile duct contractility) - may also influence hepatic disposition of xenobiotics (Tormo et al., 1995Tormo MA, Gómez-Zubeldia MA, Roppero F, Muñoz-Casillas M, Moreno JC, Campillo JE. Experimental streptozotocin-reduced diabetes and intestinal glucose metabolism in the rat, in vivo and in vitro. Acta Diabetol. 1995;32(3):182-186.; Liu et al., 2010Liu C, Su H, Wang Y, Tung T, Chou P, Chou Y, Liu J, Chen J. Reduced bile duct contractile function in rats with chronic hyperglycemia. Health. 2010;2(9):1072-1077.; Zhang et al., 2011Zhang L, Liang L, Jin S, Jing X, Yao D, Hu N, Liu L, Duan R, Liu X, Wang G, Xie L. Tissue specific alterations in expression and function of P-gp in STZ induced diabetic rats. Acta Pharmacol Sin. 2011;32(7):956-966.). In the present experiments bile flow rate was not affected by the 7-day STZ-treatment (Table I). The bile flow rate values are in accord with the expected normal choleretic values (Boyer, 2013).

It was found that STZ treatment depressed biliary excretion of PNP-G, which could be compensated by short-acting insulin administered prior to the experiment (Figure 1). Activity of both liver UDP-glucuronyltransferase and β-glucuronidase was also lower in the diabetic rats than those in the controls (Figures 2 and 3). Insulin antagonized the depression of UDP-glucuronyltransferase, whereas the decreased activity of β-glucuronidase was not influenced by administration of rapid-acting insulin.

There have been several studies demonstrating that conjugation reactions, including conjugation of PNP, are sensitive to the level of carbohydrate reserves and cofactor supply (Reinke et al., 1979Reinke LA, Kauffman FC, Evans RK, Belinsky SA and Thurman RG. p-Nitrophenol conjugation in perfused livers from normal and phenobarbital-treated rats: Influence of nutritional state. Res Commun Chem Pathol Pharmacol. 1979;23(1):185-193.;Thurman et al., 1981Thurman RG, Reinke LA, Belinsky S, Evans RK, Kauffman FC. Co-regulation of the mixed-function oxidation of nitroanisole and glucuronidation of p-nitrophenol in the perfused rat liver by carbohydrate reserves. Arch Biochem Biophys. 1981;209(1):137-142.; Qu, Kauffman, Thurman, 1995Qu W, Kauffman FC, Thurman RG. Food restriction stimulates conjugation of p-nitrophenol ion perfused rat liver. Arch Biochem Biophys. 1995; 319(2):451-456.). Increased production of UDP-GA can augment the capacity of liver to form glucuronide even without a detectable increase of glucuronyltransferase activity (Miettinen, Leskinen, 1970Miettinen TA, Leskinen E. Glucuronic acid pathway. In: Fishman WH (Ed.) Metabolic conjugation and metabolic hydrolysis. New York: Academic Press; 1970; p.157-238.). The background of the increased production of UDP-GA is that the flux of glucose in tissues of diabetic rats is shunted to insulin insensitive pathways when flow through insulin-sensitive routes is inhibited (Watkins, Dyktsra, 1987Watkins JBIII, Dykstra TP. Alterations in biliary excretory function by streptozotocin-induced diabetes. Drug Metab Dispos. 1987;15(2):177-183.).

Diabetes is known to be a major disorder in which oxidative stress and free radical production have been implicated through several lines of evidence (Hinokio et al., 1999Hinokio Y, Suzuki S, Hirai M, Chiba M, Hirai A, Toyota T. Oxidative DNA damage in diabetes mellitus: its association with diabetic complications. Diabetol. 1999;42(8):995-998.; Suzuki et al., 1999; Brownlee, 2001Brownlee M. Biochemistry and molecular cell biology of diabetic complications. Nature. 2001;414(6865):813-820.) In the liver, involvement of reactive oxygen radicals has been suggested in apoptotic cell death of hepatocytes and endothelial cells (Jaeschke, 2000Jaeschke H. Reactive oxygen and mechanisms of inflammatory liver injury. J Gastroenterol Hepatol. 2000;15(7):718-724.). It was demonstrating that insulin treatment impairs the increase of hydroxyl radical (. OH) production generated by the STZ-induced diabetic state in the rat liver (Frances et al., 2010Frances DE, Ronco MT, Monti JA, Ingaramo PI, Pisani GB, Parody JP, Pellegrino JM, Sanz PM, Carrillo MC, Carnovale CE. Hyperglycemia induces apoptosis in rat liver through the increase of hydroxyl radical: new insights into the insulin effect. J Endocrinol. 2010;205(2):187-200.). According to these earlier observations, the enhanced glucuronide excretion caused by insulin administration is supposed to be the consequence of relief of the oxidative stress resulting in increased availability of UDP-GA and regenerated enzyme activity.

Biliary excretion of PNP-S was decreased in diabetic rats similarly to that of PNP-G, whereas, insulin was unable to compensate the depressed biliary excretion of PNP-S (Figures 4-6). No change was found, however, either in sulfotransferase or in arylsulfatase activities in diabetic rats regardless they were treated with insulin or not. Sulfate conjugation in hepatocytes of insulin-treated diabetic rats was also found to be less intense than that of in the control rats (Eacho, Sweeny, Weiner, 1981Eacho PI, Sweeny D, Weiner M. Conjugation of p-nitroanisole and p-nitrophenol in hepatocytes isolated from streptozotocin diabetic rats. J Pharmacol Exp Ther. 1981;218(1):34-40.). Decrease in sulfation of PNP and in biliary excretion of PNP-S can be explained by depletion of ATP, because it is required in synthesis of PAPS. Hyperglycemia induced oxidative stress depletes ATP, which is subsequently utilized for synthesis of PAPS, the cofactor required for sulfation. Similar mechanism is considered for reduced availability of UDP-GA (Li et al., 2015Li S, Tan H-Y, Wang N, Zhang Z-J, Lao L, Wong C-W, Feng Y. The role of oxidative stress and antioxidants in liver diseases. Int J Mol Sci. 2015;16(11):26087-26124.).

STZ-induced diabetes significantly decreased biliary excretion of the unconjugated PNP (Figure 7). Administration of insulin doesn’t antagonize the decreasing effect. In intact rats anions with molecular weight lower than 350 mainly excreted by the kidney (Lehman-McKeeman, 2013Lehman-McKeeman LD. Absorption, distribution and excretion of toxicants. In: Casarett and Doull's toxicology: the basic science of poisons. 8th Ed. (Klaassen CD, Ed.). New York: McGraw-Hill Education; 2013; Chap. 5; p. 153-184.). Our experiment shows that some PNP can be excreted into the bile, which - in intact rats - can be reabsorbed from the small intestine. These experimental findings call attention to hepatobiliary circulation of law molecular weight xenobiotics as well as their sulfate and glucuronide conjugates. Further mechanistic studies are needed to identify the molecular mechanism of hyperglycemia-induced decrease of the three (PNP, PNP-G and PNP-S) ionizable compounds into the bile.

Comparison the above results with those obtained in our previous work shows different patterns of change in enzyme activities and the amount of the respective metabolites. Thus, the STZ-initiated diabetes raised the luminal appearance of PNP-G and the increase could be completely reversed by rapid-acting insulin. The changes were in parallel with alterations in the respective enzyme activities (Fischer et al., 2015Fischer E, Almási A, Bojcsev S, Fischer T, Kovács NP, Perjési P. Effect of experimental diabetes and insulin replacement on intestinal metabolism and excretion of 4-nitrophenol in rats. Can J Physiol Pharmacol. 2015;93(6):459-464.). The differences can be explained by the different effects determining the amount of the excreted metabolites in the two organs. Whereas, glucuronidation in the small intestine is directly related to the actual blood glucose level, in the hepatic processes direct action of insulin has also to be taken into considerations. Insulin has been reported to increase the bile flow and biliary excretion of drugs in experimental animals (Garberoglio et al., 1983Garberoglio CA, Richter HM3rd, Henarejos A, Moossa AR, Baker AL. Pharmacological and physiological doses of insulin and determinants of bile flow in dogs. Am J Physiol. 1983;245(1):G157-173.; Thomsen, Larsen, 1982Thomsen OO, Larsen JA. Interaction of insulin, glucagon, and DBcAMP on bile acid-independent bile production in the rat. Scand J Gastroenterol. 1982;17(5):687-693.). Neither the luminal appearances of PNP-S nor the related intestinal enzyme activities, however, were significantly influenced by the experimental hyperglycemia (Fischer et al., 2015).

CONCLUSION

These experiments show importance of hyperglycemia in hepatic excretion of PNP as well as its glucuronic acid and sulfate conjugates in the rats. The changes in the biliary excretion can be partly explained by the altered activities of the metabolic enzymes involved in synthesis of the two conjugates. No direct correlation was found between alterations of the enzyme activities and appearance of the respective metabolites in the bile. Accordingly, other factors (e.g. transport processes, availability of cofactors, bile acid production) should also be important in the effects of experimental diabetes on hepatic elimination of drugs.

ACKNOWLEDGEMENT

The present scientific contribution is dedicated to the 650th anniversary of the foundation of the University of Pécs, Hungary. This study was supported by the University of Pécs, Faculty of Medicine Research Fund (AOK-KA-34039/10/01 and AOK-KA-2013/20). The authors express their special thanks to Reiszné Horváth Mária for her excellent technical assistance.

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Publication Dates

  • Publication in this collection
    2018

History

  • Received
    11 June 2017
  • Accepted
    23 Sept 2017
Universidade de São Paulo, Faculdade de Ciências Farmacêuticas Av. Prof. Lineu Prestes, n. 580, 05508-000 S. Paulo/SP Brasil, Tel.: (55 11) 3091-3824 - São Paulo - SP - Brazil
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