Tamás Garzó

Accumulation of S-D-lactoylglutathione and transient decrease of glutathione level caused by methylglyoxal load in isolated hepatocytes.

Methylglyoxal is converted to D-lactic acid through a conjugation with glutathione and S-D-lactoylglutathione is an intermediate of this pathway. In isolated hepatocytes prepared from fed mice incubated without nutrients (glucose, pyruvate and amino acids) the formation and release of S-D-lactoylglutathione and also a continuous lowering of cellular glutathione were demonstrated upon addition of methylglyoxal (20 mM). Under these incubation conditions, the glutathione content of the cells decreased in the controls. On the other hand, in hepatocytes incubated in a medium supplemented with the above-mentioned compounds an accumulation of S-D-lactoylglutathione and a transient decrease of glutathione were shown after addition of methylglyoxal. Under these experimental circumstances the glutathione content of the cells was preserved. Buthionine sulfoximine--an inhibitor of glutathione synthesis--prevented the restoration of glutathione level in hepatocytes observed in the presence of methylglyoxal; emetine--an inhibitor of protein synthesis--was ineffective. It is suggested that increased methylglyoxal formation may have a role in alterations of glutathione metabolism under conditions when serum acetone is increased and methylglyoxal production from acetone is elevated.

Ascorbate synthesis‐dependent glutathione consumption in mouse liver

Ascorbate synthesis causes glutathione consumption in the liver. Addition of gulonolactone resulted in an increase of ascorbate production in isolated murine hepatocytes. At the same time, a decrease in reduced glutathione (GSH) level was observed. In hepatic microsomal membranes, ascorbate synthesis stimulated by gulonolactone caused an almost equimolar consumption of GSH. This effect could be counteracted by the addition of catalase or mercaptosuccinate, indicating the role of hydrogen peroxide formed during ascorbate synthesis in the depletion of GSH. The observed phenomenon may be one of the reasons why the evolutionary loss of ascorbate synthesis could be advantageous.

Glycogenolysis - and not gluconeogenesis - is the source of UDP-glucuronic acid for glucuronidation

Differences in cofactor (NADPH and UDP-glucuronic acid) supply for various processes of biotransformation were studied by investigating the interrelations between glucose production (gluconeogenesis and glycogenolysis) and drug (p-nitrophenol, aminopyrine, phenolphthalein) biotransformation (hydroxylation and conjugation) in isolated murine hepatocytes. In glycogen-depleted hepatocytes prepared from animals fasted for 48 h (i) p-nitrophenol conjugation was decreased by 80% compared to the fed control, while aminopyrine oxidation was unaltered, (ii) addition of glucose or gluconeogenic substrates failed to increase the rate of p-nitrophenol conjugation, while the rate of p-nitrophenol and also aminopyrine oxidation was increased and (iii) gluconeogenesis was inhibited by 80% by aminopyrine oxidation: it was moderately decreased by p-nitrophenol oxidation and conjugation and remained unchanged by phenolphthalein conjugation. In hepatocytes prepared from fed mice (i) p-nitrophenol conjugation was independent of the extracellular glucose concentration, (ii) it was linked to the consumption of glycogen--addition of fructose inhibited p-nitrophenol glucuronidation only, while sulfation was unaltered and (iii) p-nitrophenol oxidation was not detectable: aminopyrine oxidation was not affected by fructose addition. It is suggested that UDP-glucuronic acid for glucuronidation derives predominantly from glycogen, while the NADPH generation for mixed function oxidation is linked to glucose uptake and/or gluconeogenesis in the liver.

Epinephrine and glucagon counteract inhibition of protein synthesis induced by D-galactosamine in isolated mouse hepatocytes.

10 mM D-galactosamine enhibited protein synthesis (1 h incubation time) by 67% in isolated mouse liver cells. Counteracting uridylate deficiency induced by D-galactosamine by preventive administration of 20 mM uridine did not decrease the extent of protein synthesis inhibition. 20 mM D-galactose reverted the inhibition of protein synthesis by D-galactosamine. 10(-5) M epinephrine and 10(-7) M glucagon decreased the incorporation of D-galactosamine into glycogen to 38% and 26% of the control value, respectively, after a 35 min incubation and reduced the inhibition of protein synthesis by D-galactosamine effectively. Experimental evidence supports the view that aminoglycogen formed after D-galactosamine treatment is responsible for the inhibition of protein synthesis.

Glutathione depletion induces glycogenolysis dependent ascorbate synthesis in isolated murine hepatocytes

The relationship between glutathione deficiency, glycogen metabolism and ascorbate synthesis was investigated in isolated murine hepatocytes. Glutathione deficiency caused by various agents increased ascorbate synthesis with a stimulation of glycogen breakdown. Increased ascorbate synthesis from UDP‐glucose or gulonolactone could not be further affected by glutathione depletion. Fructose prevented the stimulated glycogenolysis and ascorbate synthesis caused by glutathione consumption. Reduction of oxidised glutathione by dithiothreitol decreased the elevated glycogenolysis and ascorbate synthesis in diamide or menadione treated hepatocytes. Our results suggest that a change in GSH/GSSG ratio seems to be a sufficient precondition of altering glycogenolysis and a consequent ascorbate synthesis.

Ascorbic acid synthesis is stimulated by enhanced glycogenolysis in murine liver

Ascorbic acid synthesis was stimulated by glucagon, dibutyryl cyclic AMP, as well as phenylephrine, vasopressin or okadaic acid, in hepatocytes prepared from fed mice. However, no such effect was observed in glycogen‐depleted cells from starved animals, either in the presence or absence of glucose. The rate of ascorbate synthesis showed close correlation with the glucose release by hepatocytes. In mice the injection of glucagon increased plasma ascorbate concentration fifteenfold, and caused a sixfold elevation of the ascorbate content of the liver. These results show that hepatic ascorbate synthesis is dependent on glycogenolysis, and indicate a regulatory role of ascorbate released by the liver.

Latency is the major determinant of UDP‐glucuronosyltransferase activity in isolated hepatocytes

The glucuronidation of p‐nitrophenol was measured in intact, saponin‐ and alamethicin‐treated isolated mouse hepatocytes. In saponin‐permeabilized cells the elevation of extrareticular UDP‐glucuronic acid concentration enhanced the rate of glucuronidation threefold. When intracellular membranes were also permeabilized by alamethicin, a further tenfold increase in the glucuronidation of p‐nitrophenol was present. Parallel measurements of the ER mannose 6‐phosphatase activity revealed that saponin selectively permeabilized the plasma membrane, whereas alamethicin permeabilized both plasma membrane and ER membranes. The inhibition of p‐nitrophenol glucuronidation by dbcAMP in intact hepatocytes was still present in saponin‐treated cells and disappeared in alamethicin‐permeabilized hepatocytes. It is suggested that the permeability of the endoplasmic reticulum membrane is a major determinant of glucuronidation not only in microsomes but in isolated hepatocytes as well.

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.

EFFECT OF METHYLGLYOXAL ON GLUCOSE FORMATION, DRUG OXIDATION AND GLUTATHIONE CONTENT IN ISOLATED MURINE HEPATOCYTES

The first stage in the formation of glucose from acetone involves two oxidation steps catalyzed by isozymes of the cytochrome P-450 II E1 gene subfamily; methylglyoxal formed this way is further converted to pyruvate by a reversible conjugation with reduced glutathione. The effect of methylglyoxal on glucose formation, oxidation of aminopyrine, aniline and on reduced glutathione content was investigated in isolated hepatocytes prepared from (i) fasted or (ii) fasted and acetone (known to induce isozymes of P-450 II E1 gene subfamily) pretreated mice. Glucose formation and drug oxidation were increased by methylglyoxal at concentrations below 1 mM, but were severely decreased above 1 mM. Methylglyoxal also decreased protein synthesis at concentrations above 1 mM. If the addition of methylglyoxal was combined with that of other gluconeogenic precursors and glucose the initial increasing effect on drug oxidation was moderated or diminished and the decreasing effect (at high concentrations) was enhanced. The glutathione content of the cells was decreased by methylglyoxal in a concentration dependent manner. Acetone pretreatment of mice also resulted in a decreased glutathione content of the liver. Based on these observations it is assumed that methylglyoxal has contrasting effects in hepatocytes, and can contribute to the disturbed metabolism under circumstances when the acetone production is elevated.

Accumulation of phenols in isolated hepatocytes after pretreatment with methylglyoxal

The effects of a single intraperitoneal injection of methylglyoxal (50-800 mg/kg body wt.) in mice were investigated in the liver after 24 h. The administration of methylglyoxal (400 mg/kg body wt.) resulted in an increase in aniline hydroxylase activity in liver microsomes. At the same time an accumulation of p-amino-phenol, the hydroxylated product of aniline, was observed in isolated hepatocytes upon addition of aniline similarly to conditions (starvation, diabetes mellitus, pyrazole pretreatment) when aniline hydroxylase was induced. Methylglyoxal also decreased the reduced glutathione content in the liver, while the activity of serum glutamate pyruvate transaminase was increased, suggesting the onset of liver injuries. It is assumed that the increased oxidation of aniline hydroxylase combined with decreased glutathione levels after methylglyoxal treatment favours the formation of potentially hazardous phenol derivatives in the liver.