Stimulation of mixed-function oxidation of 7-ethoxycoumarin in periportal and pericentral regions of the perfused rat liver by xylitol

Increased oxidation and decreased conjugation of drugs in the liver caused by starvation. Altered metabolism of certain aromatic compounds and acetone

Starvation causes several changes in the various processes of biotransformation. The focus of this review is on biotransformation of various aromatic and other compounds whose metabolism is catalyzed in phase I by isozymes belonging to the CYP2E1 gene subfamily, while in phase II phenol-UDPGT or conjugation with GSH play a dominant role. The other ways of conjugation are beyond the scope of this review. The reason why this aspect has been chosen is that the capacity of these reactions is profoundly altered by nutritional conditions. There is a balance between the two phases of biotransformation. Therefore, under standard circumstances in a well-fed state the intermediate formed in the course of phase I is converted to a conjugated compound rapidly, as a result of phase II. However, in starvation the pattern of drug metabolism is altered and the balance between the two phases is changed. This alteration of drug metabolism upon starvation is partly connected to the changes of cofactor supplies due to the metabolic state.

Analysis of enzyme reactions in situ

Estimations of metabolic rates in cells and tissues and their regulation on the basis of kinetic properties of enzymes in diluted solutions may not be applicable to intact living cells or tissues. Enzymes often behave differently in living cells because of the high cellular protein content that can lead to homologous and heterologous associations of protein molecules. These associations often change the kinetics of enzymes as part of post-translational regulation mechanisms. An overview is given of these interactions between enzyme molecules or between enzyme molecules and structural elements in the cell, such as the cytoskeleton. Biochemical and histochemical methods are discussed that have been developed for in vivo and in situ analyses of enzyme reactions, particularly for the study of effects of molecular interactions. Quantitative (histochemical) analysis of local enzyme reactions or fluxes of metabolites has become increasingly important. At present, it is possible to calculate local concentrations of substrates in cells or tissue compartments and to express local kinetic parameters in units that are directly comparable with those obtained by biochemical assays of enzymes in suspensions. In situ analysis of the activities of a number of enzymes have revealed variations in their kinetic properties (Km and Vmax) in different tissue compartments. This stresses the importance of in vivo or in situ analyses of cellular metabolism. Finally, histochemical determinations of enzyme activity in parallel with immunohistochemistry for the detection of the total number of enzyme molecules and in situ hybridization of its messenger RNA allow the analysis of regulation mechanisms at all levels between transcription of the gene and post-translational activity modulation.

Dealkylation of 7-methoxycoumarin as assay for measuring constitutive and phenobarbital-inducible cytochrome P450s

Six alkyl ethers of 7-hydroxycoumarin, ranging from methoxy- to hexoxycoumarin, were studied for their NADPH-dependent metabolism by liver microsomes of male rats treated with phenobarbital (PB) or 3-methyl-cholanthrene (MC). The six alkyl ethers were metabolized by both types of microsomes, forming 7-hydroxycoumarin as the major product. Among the test compounds, 7-methoxycoumarin was unusual in that its dealkylation was inducible only by PB and not by MC. PB increased 7-methoxycoumarin-O-demethylase (MOCD) activity about four- to eightfold. Metyrapone strongly inhibited MOCD in PB-treated microsomes but not in MC-treated microsomes. Similarly, monoclonal antibodies directed toward PB-induced cytochrome P450s selectively suppressed MOCD in PB-treated microsomes. MOCD activity was observed in preparations of SD1 cells containing only cytochrome P450IIB1, while it was not found in preparations of XEM1 cells containing only cytochrome P450IA1. Demethylation of 7-methoxycoumarin was also mediated by the constitutive cytochrome P450 form(s) of liver, lung, small intestine, and kidney (in decreasing order). PB increased MOCD activity of small intestine by 40% but was without effect on the dealkylation activity of lung and kidney. MOCD activity was also detectable in differentiated rat hepatoma lines H4IIEC3 and 2sFou. The studies indicate that dealkylation of 7-methoxycoumarin is a highly sensitive, simple, and practical assay for estimating constitutive and PB-inducible cytochrome P450-dependent monooxygenase activities.

Increased catalytic activity of cytochrome P-450IIE1 in pericentral hepatocytes compared to periportal hepatocytes isolated from pyrazole-treated rats

Cytochrome P-450IIE1 is induced by a variety of agents, including acetone, ethanol and pyrazole. Recent studies employing immunohistochemical methods have shown that P-450IIE1 was expressed primarily in the pericentral zone of the liver. In order to evaluate whether catalytic activity of P-450IIE1 is preferentially localized in the pericentral zone of the liver acinus, the oxidation of aniline and p-nitrophenol, two effective substrates for P-450IIE1, by periportal and pericentral hepatocytes isolated from pyrazole-treated rats was determined. Periportal and pericentral hepatocytes were prepared by a digitonin-collagenase procedure; the marker enzymes glutamine synthetase and gamma-glutamyl transpeptidase indicated reasonable separation of the two cell populations. Viability, yield and total cytochrome P-450 content were similar for the periportal and pericentral hepatocytes. Pericentral hepatocytes oxidized aniline and p-nitrophenol at rates that were 2-4-fold greater than periportal hepatocytes under a variety of conditions. Carbon monoxide inhibited the oxidation of the substrates with both preparations and abolished the increased oxidation found with the pericentral hepatocytes. Pyrazole or 4-methylpyrazole, added in vitro, effectively inhibited the oxidation of aniline and p-nitrophenol and prevented the augmented rate of oxidation by the pericentral hepatocytes. Western blots carried out using isolated microsomes revealed a more than 2-fold increase in immunochemical staining with microsomes isolated from the pericentral hepatocytes, which correlated to the 2-4-fold increase in the rate of oxidation of aniline or p-nitrophenol by the pericentral hepatocytes. These results suggest that functional catalytic activity of cytochrome P-450IIE1 is preferentially localized in the pericentral zone of the liver acinus, and that most of the induction by pyrazole of P-450IIE1 appears to occur within the pericentral zone.

Disease-causing effects of environmental chemicals

Both toxicologic studies and studies in environmental chemistry are important in assessing the potential adverse health effects of human exposures to hazardous environmental agents. This article discusses the toxic effects of chemical concentration at the target organ or site and how the concentration is related to the level of external exposure.

Methods for the study of liver cell heterogeneity

A large number of histological, histochemical and biochemical techniques are available for studying liver cell heterogeneity. Structural differences are recognized by morphometric analyses of electron micrographs. The zonal heterogeneity of enzyme activities can be demonstrated by histochemistry and more precisely by ultramicrobiochemical assays in microdissected periportal and perivenous tissue. Immunohistochemistry is useful for quantifying and localizing proteins, especially isoenzymes, without depending on their biological activity. The zonal quantification of specific mRNA can be achieved by in situ hybridization. The different structural and enzymic equipment of periportal and perivenous tissue found by these techniques has led to the concept of metabolic zonation. This hypothesis can be confirmed by determination of metabolic rates in perfused liver after selective zonal damage, in separated periportal and perivenous hepatocytes as well as in periportal and perivenous tissue of perfused liver by non-invasive techniques.

New micro-optical methods to study metabolism in periportal and pericentral regions of the liver lobule

New techniques employing microlight guides allow metabolic events to be studied noninvasively in tiny volumes of liver tissue located in defined regions within the liver lobule. These events include oxygen utilization, carbohydrate metabolism, ethanol oxidation, monooxygenation, glucaronidation, and sulfation. Two-fiber microlight guides are constructed from 80-microns optical fibers and are placed on periportal or pencentral regions of the liver lobule based on the pattern of liver pigmentation. Light of selected wavelengths is transmitted to the liver surface by one fiber, and the resultant fluorescence or reflectance is delivered to a photomultiplier by the second fiber. The experimental strategy is to monitor native fluors which are metabolically linked (e.g., NADH) or to infuse nonfluorescent substrates which are converted to fluorescent products by specific enzyme systems (e.g., 7-ethoxycoumarin for monooxygenation). Alternatively, disappearance of fluorescence can also be employed (e.g., 7-hydroxycoumarin for sulfation or glucuronidation). With these methods, rate-limiting steps in situ (e.g., substrate uptake, enzyme activity, cofactor supply) have been studied for several metabolic systems in periportal and pericentral regions of the liver lobule.

Quantitation of ketogenesis in periportal and pericentral regions of the liver lobule

A method has been devised to quantitate rates of ketogenesis (acetoacetate + beta-hydroxybutyrate production) in discrete regions of the liver lobule based on changes in NADH fluorescence. In perfused livers from fasted rats, ketogenesis was inhibited nearly completely with either 2-bromoctanoate (600 microM) or 2-tetradecylglycidic acid (25 microM). During inhibition of ketogenesis, a linear relationship (r = 0.90) was observed between decreases in NADH fluorescence detected from the liver surface and decreases in ketone body production. NADH fluorescence was monitored subsequently from individual regions of the liver lobule by placing microlight guides on periportal and pericentral regions of the liver lobule visible on the liver surface. Rates of ketogenesis in sublobular regions were calculated from regional decreases in NADH fluorescence and changes in the rate of ketone body formation by the whole liver during infusion of inhibitors. In the presence of bromoctanoate, ketogenesis was reduced 80% and local rates of ketogenesis were decreased 31 +/- 4 mumol/g/h in periportal areas and 28 +/- 3 mumol/g/h in pericentral regions. Similar results were observed with tetradecylglycidic acid. Therefore, it was concluded that submaximal rates of ketogenesis from endogenous, mainly long-chain fatty acids are nearly equal in periportal and pericentral regions of the liver lobule in liver from fasted rats. Rates of ketogenesis and NADH fluorescence were strongly correlated during fatty acid infusion. Infusion of 250 microM oleate increased NADH fluorescence maximally by 8 +/- 1% over basal values in periportal regions and 17 +/- 4% in pericentral areas. Local rates of ketogenesis, calculated from these changes in fluorescence, increased 35 +/- 6 mumol/g/h in periportal areas and 55 +/- 5 mumol/g/h in pericentral regions. Thus, oleate stimulated ketogenesis nearly 60% more in pericentral than in periportal regions of the liver lobule.

Early biochemical and morphological changes of the rat adrenal medulla induced by xylitol

Long-term administration of high doses of xylitol and other polyols in rats has been associated with an increase in adrenal medullary hyperplasia and neoplasia. In order to exclude age-related factors and to differentiate between unspecific stress reactions and direct effects of the compound administered, a model was developed for quantifying early adrenomedullary responses. Male SD rats were fed xylitol (10% or 20% in the diet) for 2 and 8 weeks, and early biochemical changes were correlated with a stereological analysis of the adrenal medulla. At first, the in vivo rate of catecholamine (CA) biosynthesis was slightly decreased (at 2 weeks). This was followed by an increase in dopamine-beta-hydroxylase (DBH) activity (at 8 weeks). By that time, the total chromaffin cell volume had increased and the number of chromaffin cells per reference volume had decreased in a dose-dependent way. The total number of chromaffin cells per adrenal gland showed a distinct tendency towards an increase. Adrenal epinephrine and norepinephrine contents were not altered, and both tyrosine hydroxylase and phenylethanolamine-N-methyltransferase activities remained unchanged. These data suggest that continued xylitol administration evoked an inhibitory effect on CA synthesis that, together with stimulation of the adrenal medulla brought about by the compound, resulted in compensatory medullary hypertrophy and hyperplasia.

Contribution of non-ADH pathways to ethanol oxidation in hepatocytes from fed and hyperthyroid rats. Effect of fructose and xylitol

The metabolism of (1R)[1-3H]ethanol, [2-3H]lactate or [2-3H]xylitol was studied in hepatocytes from fed or T3-treated rats in the presence or absence of fructose or xylitol. The yields of tritium in ethanol, lactate, water, glycerol and glucose were determined. A simple model, describing the metabolic fate of tritium from these substrates is presented. The model allows estimation of the ethanol oxidation rate by the non-alcohol dehydrogenase pathways from the relative yield of tritium in water and glucose. The calculations are based on a comparison of the fate of the 1-proR-hydrogen of ethanol and the hydrogen bound to carbon 2 of lactate (or xylitol) under identical condition. In our calculations we have taken into account that the reactions catalyzed by lactate dehydrogenase and alcohol dehydrogenase are reversible and that lactate or ethanol labelled during the metabolism of the other tritiated substrates will contribute to the tritium found in water. The contribution of non-ADH pathways to ethanol oxidation varied from 10 to 50% and was correlated to changes in the lactate/pyruvate ratio from 80 to 500. In T3-treated rats the activity of non-ADH pathways were greater than in fed rats for the same lactate/pyruvate ratio.