The subcellular distribution and properties of aldehyde dehydrogenases in rat liver

Effect of tolbutamide and chlorpropamide on acetaldehyde metabolism in two inbred strains of mice

The mechanisms by which chlorpropamide and tolbutamide disrupt acetaldehyde metabolism were studied in C57BL and DBA mice. Acute po administration of varying doses of tolbutamide or chlorpropamide 2.5 hr before a 3.0 g/kg ip dose of ethanol to C57BL and DBA mice resulted in significant elevations of blood acetaldehyde when measured 2.5 hr after ethanol dosing. Dose-response analysis revealed a significant (p less than .05) difference in ED50 values for the elevated blood acetaldehyde response to tolbutamide in DBA (60 mg/kg) and C57BL (100 mg/kg) mice. The ED50 value for potentiation by chlorpropamide of blood acetaldehyde concentration was similar (23 to 32 mg/kg) in both inbred strains. At higher doses of chlorpropamide, DBA mice displayed elevations of blood acetaldehyde nearly threefold greater than those measured in C57BL mice treated identically. Measurements of aldehyde dehydrogenase (ALDH) in hepatic subcellular fractions, obtained from both inbred strains treated with 100 mg/kg tolbutamide or chlorpropamide prior to a 3.0 g/kg dose of ethanol, revealed a 50 to 80% inhibition of the low-Km ALDH present in mitochondria. Chlorpropamide and tolbutamide did not inhibit ALDH in vitro, suggesting that metabolites of these hypoglycemic agents may be responsible for the genotypic-dependent alterations in in vivo acetaldehyde oxidation.

Biogenic aldehydes in brain: characteristics of a reaction between rat brain tissue and indole-3-acetaldehyde

When indole-3-acetaldehyde was incubated with rat brain tissue, an aldehyde dehydrogenase-independent irreversible disappearance of the aldehyde was found. This was accompanied by an increase in absorbance at 240-400 nm, with a peak at 310 nm. The results suggested that this change in absorbance was caused by a membrane-bound nonenzymatic reaction between indole-3-acetaldehyde and phospholipids. A similar reaction occurred between indole-3-acetaldehyde and pure preparations of phosphatidylethanolamine and phosphatidylserine, but not phosphatidylcholine. Indole-3-acetaldehyde levels also decreased slightly when incubated with albumin but absorbance at 310 nm was unaltered. It is suggested that nonenzymatic reactions between indole-3-acetaldehyde (or other biogenic aldehydes) and membrane components might occur in vivo, and could be involved in the effects of drugs such as ethanol and barbiturates.

Effect of triiodothyronine on alcohol dehydrogenase and aldehyde dehydrogenase activities in rat liver. Implications for the control of ethanol metabolism

Treatment of rats with 20 micrograms of 3,3',5-triiodo-L-thyronine (T3) per 100 g body wt for a period of 6 days led to a 45% decrease in total liver alcohol dehydrogenase and a 36% decrease in total liver aldehyde dehydrogenase. Most of the latter decrease was directly attributable to a 57% fall in the level of the physiologically-important low Km mitochondrial isoenzyme. The high Km isoenzyme of the postmitochondrial and soluble fractions was much less affected by T3-treatment. T3, at concentrations up to 0.1 mM, did not inhibit the activity of aldehyde dehydrogenase in vitro. Despite these large losses of the two enzymes most intimately involved in ethanol metabolism, the rate of ethanol elimination in vivo was the same in T3-treated and control animals. Moreover, there was no difference between the two groups in the susceptibility of ethanol elimination to inhibition by 4-methylpyrazole, making it unlikely that an alternative route of ethanol metabolism had been significantly induced by treatment with T3. As it had been suggested that T3 might create a "hypermetabolic state" in which constraints normally imposed on alcohol dehydrogenase and aldehyde dehydrogenase are removed thereby compensating for any loss in total enzymic activity, 2,4-dinitrophenol (0.1 mmoles/kg body wt) was administered to rats in order to raise the general metabolic rate. However, the uncoupler proved to be lethal to T3-treated animals and did not stimulate ethanol elimination in controls. The results do not support the notion that ethanol elimination in vivo is normally governed either by the level of alcohol dehydrogenase or by that of hepatic aldehyde dehydrogenase. However, the mode of control remains unclear.

Inducible aldehyde dehydrogenases from rat liver cytosol

Two rat hepatic cytoplasmic isozymes of aldehyde dehydrogenase, phi, induced by phenobarbital treatment, and tau, induced by TCDD treatment, have been purified from rat hepatic cytosol by ammonium sulfate fractionation, followed by ion-exchange and affinity chromatography. The specific activities of the two isozymes at pH 9.6 with propionaldehyde as substrate and NAD as cofactor were 2850 and 5250 nmol of NADH/min/mg protein for phi and tau isozymes, respectively. Estimates of molecular weights from gel filtration chromatography gave values of 118,000 Da for phi and 106,000 Da for tau. An isoelectric point for the tau enzyme of 6.5 was determined in an electrofocusing column, and approximately 7.2 for phi by immunoelectrophoresis. Both enzymes can oxidize a wide variety of aldehyde substrates, with Km values ranging from millimolar to micromolar. Long-chain aliphatic and aromatic aldehydes using NAD as cofactor tend to be the best utilized substrates. Only the tau enzyme is able to use NADP as cofactor. The measured Km for phi at pH 7.2 for acetaldehyde was 1.97 mM and for tau, 12.1 mM. Both enzymes showed similar inhibition characteristics with sodium arsenite and disulfiram, although the phi enzyme tended to be slightly more sensitive to all inhibitors.

Intraparticulate localization and some properties of a clofibrate-induced peroxisomal aldehyde dehydrogenase from rat liver

A study was made of the effect of chronic administration of the hypolipidemic drug clofibrate on the activity and intracellular localization of rat liver aldehyde dehydrogenase. The enzyme was assayed using several aliphatic and aromatic aldehydes. Clofibrate treatment caused a 1.5 to 2.3-fold increase in the liver specific aldehyde dehydrogenase activity. The induced enzyme has a high Km for acetaldehyde and was found to be located in peroxisomes and microsomes. Clofibrate did not alter the enzyme activity in the cytoplasmic fraction. The total peroxisomal aldehyde dehydrogenase activity increased 3 to 4-fold under the action of clofibrate. Disruption of the purified peroxisomes by the hypotonic treatment or in the alkaline conditions resulted in the release of catalase from the broken organelles, while aldehyde dehydrogenase as well as nucleoid-bound urate oxidase and the peroxisomal membrane marker NADH:cytochrome c reductase remained in the peroxisomal 'ghosts'. At the same time, treatment by Triton X-100 led to solubilization of the membrane-bound NADH:cytochrome c reductase and aldehyde dehydrogenase from intact peroxisomes and their 'ghosts'. These results indicate that aldehyde dehydrogenase is located in the peroxisomal membrane. The peroxisomal aldehyde dehydrogenase is active with different aliphatic and aromatic aldehydes, except for formaldehyde and glyceraldehyde. The enzyme Km values lie in the millimolar range for acetaldehyde, propionaldehyde, benzaldehyde and phenylacetaldehyde and in the micromolar range for nonanal. Both NAD and NADP serve as coenzymes for the enzyme. Aldehyde dehydrogenase was inhibited by disulfiram, N-ethylmaleimide and 5,5'-dithiobis(2-nitrobenzoic)acid. According to its basic kinetic properties peroxisomal aldehyde dehydrogenase seems to be similar to a clofibrate-induced microsomal enzyme. The functional role of both enzymes in the liver cells is discussed.

Aldehyde dehydrogenase content and composition of human liver

Human liver contains only four proteins which catalyze dehydrogenation of acetaldehyde; two of these are tetrameric with MW of 220,000 and are structurally related. These enzymes were purified previously to homogeneity and are now known as the cytoplasmic E1 and mitochondrial E2. The other two proteins do not appear to be structurally related to E1 and E2. The recently isolated E4 enzyme is a dimer of MW of ca. 175,000; the E3 may be a polymorphic enzyme. The Enzyme Commission classification for E1 and E2 is EC 1.2.1.3, that for E4 is at present uncertain since its Michaelis constants for short chain aldehydes are high, making it unlikely that these would be its natural substrates. The relationship between E3 and E4 is also uncertain. Employing a suitably designed assay, E1 and E2 are assayed as "low Km" enzymes while E3 and E4 are assayed as "high Km" enzymes. Therefore by employing such an assay, combined with electrofocusing procedure, an assessment of enzyme content and composition of aldehyde dehydrogenase in human liver can be made.

Lowering of blood acetaldehyde but not ethanol concentrations by pantethine following alcohol ingestion: different effects in flushing and nonflushing subjects

A rise in blood acetaldehyde concentrations following alcohol ingestion was significantly inhibited when healthy nonflushing subjects were administered a clinical dose of pantethine orally. However, similar findings were not observed in flushing (alcohol-sensitive) subjects lacking hepatic low Km aldehyde dehydrogenase (ALDH). The blood ethanol concentrations were not altered by this treatment in either flushing or nonflushing subjects. Acetaldehyde (45 microM) added in vitro to whole blood and plasma obtained 1 hr after pantethine administration disappeared as the incubation continued similarly as with blood and plasma obtained prior to pantethine treatment. Pantethine-related metabolites, such as taurine, pantetheine, coenzyme A, and pantothenate, activated ALDH in vitro. Hepatic acetaldehyde levels following ethanol loading of rats treated with pantethine were much lower than in untreated rats. The pantethine action observed only in nonflushing subjects might be due to an accelerated oxidation of acetaldehyde by the activation of low Km ALDH by pantethine-related metabolites formed in the liver.

Effects of disulfiram on the oxidation of benzaldehyde and acetaldehyde in rat liver

The in vitro oxidation of benzaldehyde and acetaldehyde was studied in liver samples from disulfiram-treated and control rats. With 25 microM substrate, both cytosol and mitochondria appeared to make a nearly equal contribution to the oxidation of benzaldehyde, whereas ca. 90% of acetaldehyde oxidation occurred in mitochondria. When the Km values for benzaldehyde with aldehyde dehydrogenase (ALDH) were determined, two Km values (3 and 120 microM) were obtained with mitochondria, but only a single Km value (25 microM) was obtained with the cytosolic fraction. The relatively high Km (2.9 mM) found with microsomes makes it unlikely that microsomes are important in the oxidation of benzaldehyde. In intact mitochondria, with 200 microM acetaldehyde or benzaldehyde the matrix space enzyme accounted for 77 and 62%, respectively, of the total ALDH activity. When the activity was determined in a mixture containing both substrates, the activity was found not to be additive, indicating that both substrates are oxidized by the same matrix space enzyme. With subcellular fractions, from livers of disulfiram-treated and control rats, a greater degree of inhibition of ALDH was obtained when acetaldehyde was a substrate compared to that with benzaldehyde in cytosol and mitochondria. Microsomal ALDH was not inhibited by disulfiram. In liver slices from rats given disulfiram, a statistically significant inhibition was found when either 25 or 250 microM acetaldehyde was used (46 and 33%). With benzaldehyde, a significant inhibition (24%) was observed only with the lower substrate concentration. Finding that both mitochondrial fractions and slices were less inhibited at the higher substrate concentration implies that the high Km enzyme is not inhibited. It can be concluded that, in rat, disulfiram inhibiting liver ALDH not only affects oxidation of acetaldehyde, but also that of benzaldehyde.

Canine liver aldehyde dehydrogenases: distribution, isolation, and partial characterization

Canine liver aldehyde dehydrogenases (ALDH) (aldehyde:NAD oxidoreductase; EC 1.2.1.3) are analogous to enzymes identified in human and other mammalian liver tissue in regard to subcellular localization, affinity for substrates, inhibition by disulfiram, and effects of magnesium ions on enzyme activity. Aldehyde dehydrogenase activity is distributed in the mitochondrial, microsomal, and cytosolic fractions of the cell. Four isoenzymes designated ALDH IA, IB, IIA, and IIB have been isolated from canine liver via ammonium sulfate fractionation, ion-exchange chromatography, and affinity chromatography. Based on cell fractionation followed by enzyme isolation, ALDH IA and IB appear to be extramitochondrial whereas ALDH IIA and IIB appear to be mitochondrial in origin. ALDH IA has a high Km for acetaldehyde (3 mM) and propionaldehyde (4 mM). ALDH IB and IIA have Km values for acetaldehyde and propionaldehyde in the range of 4-60 microM. ALDH IIB has the lowest Km of the four isoenzymes for acetaldehyde and propionaldehyde (1-3 microM). All four isoenzymes have Km values for NAD in the range of 4-70 microM. ALDH IB and IIA are sensitive to inhibition by disulfiram whereas ALDH IA and IIB are resistant. Magnesium ions inhibit ALDH IA, IB, and IIA whereas ALDH IIB activity is stimulated approximately 2-fold. Magnesium ions do not affect molecular weight estimates of the isoenzymes as determined by gel filtration chromatography.

Demonstration of a functional blood-testis barrier to acetaldehyde. Evidence for lack of acetaldehyde effect on ethanol-induced depression of testosterone in vivo

In vitro studies have shown that acetaldehyde is a more potent inhibitor of testicular steroidogenesis than ethanol. The present study examined the in vivo role of acetaldehyde in ethanol-induced reduction of testosterone by (1) determining the levels of acetaldehyde to which the testes were exposed subsequent to acute ethanol administration to mice; and (2) examining the effect of ethanol on testosterone in animals subsequent to drug pretreatment which decreased or increased ethanol-derived acetaldehyde. Ethanol-induced (3 g/kg) depression of testosterone was dependent upon gonadotropin stimulation. The increase in hCG-induced testosterone was suppressed (P less than 0.01) in ethanol- as compared to saline-treated animals [39.8 +/- 2.6 (S.E.M.) vs 28.1 +/- 2.3 ng/ml]. Pargyline (100 mg/kg) or cyanamide (8.4 mg/kg) increased (P less than 0.05) plasma and testicular acetaldehyde, while having no effect on the testosterone response to ethanol. Similarly, 4-methylpyrazole (25 mg/kg) reduced blood and testicular acetaldehyde to nondetectable levels, while having no effect on testosterone. Testicular acetaldehyde was lower (P less than 0.001) than plasma levels (14 +/- 2 vs 2.0 +/- 0.2 microM). This functional blood-testis barrier to acetaldehyde could be explained by testicular aldehyde dehydrogenases in the mitochondria (Km for acetaldehyde = 1.5 microM) and in the cytosol (Km = 123 microM) whose maximal activities totaled to more than 25-fold greater than that of testicular alcohol dehydrogenase (ADH). ADH was concentrated in the Leydig cells, while aldehyde dehydrogenase was evenly distributed in the testis. Ethanol prevented further hCG-induced rises in testosterone rather than inhibiting testosterone production to below pre-ethanol values. The above data argue against a significant role of acetaldehyde in the in vivo response of testosterone to ethanol. Ethanol appears to impair gonadotropin-testicular receptor interaction in vivo.

Blood acetaldehyde response to ethanol ingestion during the reproductive cycle of the female rat

Acetaldehyde could mediate a number of the toxic effects of alcohol both in females and their offspring. Thus, we assessed the blood acetaldehyde response to ethanol (3 g/kg) at various stages of the female reproductive cycle. Blood levels were low throughout the various phases of the estrous cycle and during most of pregnancy. By contrast, a 4-fold rise in maternal blood acetaldehyde occurred at the end of pregnancy (day 20), continued to increase during lactation (17-fold at day 14) and returned to non-pregnant values after weaning or after pup removal at birth. Both enhanced rate of ethanol oxidation and decreased activity of the low Km aldehyde dehydrogenase in liver mitochondria contributed to the increased acetaldehyde levels. Acetaldehyde was detectable in fetal blood, but only a small fraction of the high maternal values in pregnancy reached the fetus through the umbilical vein. Chronic alcohol administration resulted in decreased fetal size and striking enlargement of the placenta with possible implications for abnormal fetal development. Thus, the high maternal acetaldehyde levels at the end of pregnancy may exert deleterious effects on many maternal organs, including those (such as placenta) which are required for normal fetal development.

An in vitro model of acetaldehyde metabolism by rodent conceptuses

A culture model is described for the study of acetaldehyde (AcH) metabolism by explanted postimplantation rat and mouse conceptuses. The ability of 12-d rat and 10-d mouse embryos to metabolise AcH was demonstrated. The elimination rate for the 12-d rat conceptus using an initial AcH concentration of 1 mM in the medium was found to be 1.8 nmol/mg per minute. When the conceptus was divided into embryonic and extraembryonic tissue, the rates were 1.6 and 2.2 nmol/mg per minute, respectively. When the AcH concentration was reduced to 50 microM the rate was 0.095 nmol/mg per minute. The results provide further evidence for a functional barrier that prevents AcH entry to the embryo. A comparative experiment using CBA/beige mouse conceptuses showed that AcH elimination characteristics may be qualitatively similar to those in rat embryos, but that the estimated elimination rate of 0.8 nmol/mg per minute was less than half that of the rat. Thus the "metabolic barrier" may be less efficient in the mouse. This may be important in view of the greater sensitivity of the mouse to ethanol embryotoxicity.

Skeletal muscle and hormonal adaptation to physical training in the rat: role of the sympatho-adrenal system

The main purpose of the present study was to test the hypothesis that adrenergic stimulation of muscle fibres during exercise is a major stimulus for the training-induced enhancement of skeletal muscle respiratory capacity. Therefore, Sprague-Dawley rats either underwent bilateral surgical ablation of the adrenal medulla or were sham-operated. Furthermore, unilateral surgical extirpation of the lumbar sympathetic chain was performed. Half of the rats were then trained for 12 weeks by swimming (up to 5.5 h X day-1, 4 days X week-1) and the remaining rats were sedentary controls. In the gastrocnemius muscle, training significantly increased the mitochondrial enzymes citrate synthase, succinate dehydrogenase, cytochrome c oxidase, and 3-hydroxyacyl-CoA dehydrogenase. In sham-operated rats, the increases were 40%, 43%, 66%, and 25%, respectively, in legs with intact sympathetic innervation. The training-induced enzyme adaptation after adrenodemedullation and/or sympathectomy was not significantly lower than these control values. In sham-operated rats, training decreased resting plasma insulin and glucagon levels and increased liver glycogen content. Similar changes were induced by adrenodemedullation, but training did not augment these changes in adrenodemedullated rats. In conclusion, the data suggest that neither adrenomedullary hormones nor local sympathetic nerves are prerequisites for the training-induced increase in muscle mitochondrial enzymes. The training-induced decline in resting plasma insulin and glucagon levels in intact rats may be mediated by adrenomedullary hormones.

Ethanol potentiation of carbon tetrachloride hepatotoxicity: possible role for the in vivo inhibition of aldehyde dehydrogenase

A potentiation of CCl4-induced hepatotoxicity was observed in rats pretreated with ethanol 18 hr prior to CCl4 exposure. Hepatic microsomal aldehyde dehydrogenase (ALDH) was significantly inhibited in animals sacrificed 1 hr following the sequential exposure, however, no more so than in those animals receiving CCl4 alone. The animals receiving ethanol alone had ALDH activity similar to vehicle treated controls. Twenty-four hours following a potentiating dose of ethanol and CCl4 an 81 and 57% decline in NAD+-dependent microsomal and mitochondrial ALDH activity was observed, respectively. Similar results were observed for microsomal and mitochondrial NADP+-dependent ALDH activity. The decline in membrane-bound ALDH was greater in potentiated animals than in those receiving CCl4 alone. A relatively smaller decline in cytosolic ALDH activity was observed in CCl4 treated rats with or without ethanol pre-exposure. The data suggest that inhibition of membrane bound ALDH may be one of the major mechanisms of in vivo potentiation of CCl4-induced hepatotoxicity by ethanol.

Exaggerated acetaldehyde response after ethanol administration during pregnancy and lactation in rats

The exaggerated blood acetaldehyde response that has been reported after ethanol administration to pregnant rats was found to be the beginning of a much larger alteration occurring during lactation. Indeed, at the end of pregnancy, we confirmed a 4-fold increase in the acetaldehyde values above nonpregnant values after an intragastric dose of 3 g/kg ethanol. During gestational days 1 to 17, the levels did not differ. After delivery, the exaggerated acetaldehyde response to ethanol was increased, producing acetaldehyde concentrations 15-fold greater than in nonlactating controls. This response returned to nonpregnant levels with weaning and could be abolished by removing the pups at birth. The intensified response was associated with both an enhanced rate of ethanol oxidation and a decreased low Km aldehyde dehydrogenase activity in liver mitochondria. At the end of pregnancy, measurable concentrations of acetaldehyde were found in umbilical venous blood and fetal blood. However, they amounted to only one-quarter of maternal values whereas ethanol levels were similar. Thus, during late pregnancy and lactation, there is a marked increase in maternal blood acetaldehyde after ethanol intake. In the presence of a normal placenta, however, an acetaldehyde concentration gradient exists between the mother and the fetus.

Impaired acetaldehyde metabolism in partially hepatectomized rats

Two-thirds hepatectomy in rats resulted in elevated blood ethanol and acetaldehyde levels as compared to those of sham operated and CCl4-induced toxic injured rats. The acetaldehyde/ethanol ratio increased also. Although the liver mass regenerated within 3 days, ethanol metabolism remained disturbed. Mitochondrial aldehyde dehydrogenase activity was significantly diminished only following partial hepatectomy. The results suggest that abnormal ethanol and especially acetaldehyde metabolism in partially hepatectomized rats is not due simply to reduced liver tissue but to a diminished aldehyde dehydrogenase activity in the remaining tissue.

Inhibition of hepatic aldehyde dehydrogenase by carbon tetrachloride: an in vitro study

In vitro inhibition of rat liver mitochondrial and microsomal aldehyde dehydrogenase (ALDH) under conditions of active CCl4 metabolism was investigated. Incubation of microsomes or mitochondria in the presence of NADPH alone caused significant, time-dependent inhibition of mitochondrial and microsomal ALDH. EDTA partially protected ALDH from inhibition. Incubation of microsomes or microsomes plus mitochondria in the presence of NADPH and CCl4 resulted in marked inhibition of microsomal and mitochondrial ALDH activity. The inhibition was both dose- and time-dependent and was relatively less in the presence of EDTA. It is proposed that the inhibition of membrane-bound ALDH may be one of the early events responsible for the genesis of CCl4-hepatotoxicity.

Aldehyde dehydrogenase in Drosophila: developmental and functional aspects

Alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) activities were determined in adult flies from several Drosophila species endowed with widely different tolerance to ethanol (ETOH). Plotting ALDH against ADH activities resulted in a high correlation coefficient (r = 0.966). This finding was confirmed in developmental studies. From early larval stage up to late adult life, ADH and ALDH activities demonstrated almost parallel profiles. In the highly ETOH tolerant species D. melanogaster (D.m.), ADH and ALDH profiles were U-shaped: high activities in larvae, low activities in pupae and high activities in adults. In D. simulans (D.s.), a species less tolerant to ETOH, the profiles were L-shaped: high activities in larvae but low activities in both pupae and adults. Interestingly, similar activities (ADH and ALDH) were observed in the larvae of both species. Subcellular distribution studies of larval ALDH in both species revealed that the total ALDH activity is largely contributed by a mitochondrial high affinity enzyme. ALDH activity, clearly distinguishable from aldehyde oxidase (ALDOX), was visualized through analytical isoelectric focusing of the subcellular fractions. The estimated pIs for D.m. and D.s. were 4.9 and 5.2 respectively, thus different from those of ADH. The key biological role initially attributed to Drosophila ALDH is further supported by the present data. In addition the Drosophila developmental model opens new avenues for research on the study of genetic regulation of ADH and ALDH expression.

The effect of ethanol or sorbitol on glucose production from pyruvate in isolated hepatocytes from 48-hour fasted guinea-pigs

Hepatocytes isolated from 48-hour, fasted guinea-pigs were incubated with glucose precursors to compare relative rates of glucose production. Glucose production from lactate and pyruvate was similar (2.61 vs 3.18 mumol/hr per 100 mg wet weight). Glucose production from fructose was greater than that from sorbitol (4.68 vs 1.63 mumol/hr per 100 mg wet weight). When ethanol was added to pyruvate-containing buffer, the flux of pyruvate to glucose and lactate was synergistically enhanced (5.28 vs 3.76 and 7.51 vs 2.88 mumol/hr per 100 mg wet weight, respectively). When sorbitol was added to buffer containing pyruvate, glucose and lactate production were even greater than that seen with ethanol (8.32 vs 5.38 and 15.99 vs 7.51 mumol/hr per 100 mg wet weight, respectively).

Subcellular distribution of aldehyde dehydrogenase activities in human liver

The subcellular distributions of aldehyde dehydrogenase activities towards acetaldehyde have been determined in wedge-biopsy samples of human liver. A form with Km values of less than 1 microM and 285 microM towards acetaldehyde and NAD+ respectively was present in the mitochondrial fraction. This enzyme had no detectable activity towards N-tele-methylimidazole acetaldehyde, the aldehyde derived from the oxidation of N-tele-methylhistamine. The activity in the cytosol was more sensitive to inhibition by disulfiram and had Km values of 270 microM and 25 microM for acetaldehyde and NAD+, respectively. It was active towards N-tele-methylimidazole acetaldehyde with a Km value of 2.5 microM and a maximum velocity that was 40% of that determined with acetaldehyde. Both these cytosolic activities had alkaline pH optima.

Biochemical and genetic studies on mouse aldehyde dehydrogenases

Aldehyde dehydrogenase (AHD) exists as isozymes which are differentially distributed among tissues and subcellular fractions of mouse tissues. Genetic variants for liver mitochondrial (AHD-1) and cytoplasmic (AHD-2) isozymes have been used to map the responsible loci (Ahd-1 and Ahd-2) on chromosomes 4 and 19 respectively. Evidence for a regulatory locus (Ahd-3r) controlling the inducibility of the mouse liver microsomal isozyme (AHD-3) has also been obtained. More recent studies have described genetic and biochemical evidence for three additional AHD isozymes: a stomach isozyme (AHD-4); another liver mitochondrial enzyme (AHD-5); and a testis isozyme (AHD-6). Genetic analyses have indicated that AHD-4 and AHD-6 are encoded by distinct but closely linked loci on the mouse genome (Ahd-4 and Ahd-6), which segregate independently of Ahd-1 and Ahd-2. Liver mitochondrial isozymes, AHD-1 and AHD-5, have been purified to homogeneity using affinity chromatography. The very high affinity of AHD-5 for acetaldehyde suggests that this enzyme is predominantly responsible for acetaldehyde oxidation in mouse liver mitochondria.

Comparative subcellular distribution of aldehyde dehydrogenase in rat, mouse and rabbit liver

The subcellular distribution of hepatic aldehyde dehydrogenase (ALDH) activity was determined in Buffalo, Fischer 344, Long-Evans, Sprague-Dawley, Wistar and Purdue/Wistar rats. These subcellular distributions were compared to the distribution of mouse and rabbit liver ALDH. For the six rat strains, at millimolar propionaldehyde concentrations, NAD-dependent ALDH activity was associated primarily with mitochondria (51%) and microsomes (30%). At millimolar acetaldehyde concentrations, NAD-dependent ALDH was primarily mitochondrial (up to 80%). Less than 1% of total NAD-dependent aldehyde dehydrogenase was found in the cytosol. The highly inbred Purdue/Wistar line possessed significantly less acetaldehyde-NAD ALDH activity as well as less total NADP-dependent ALDH activity than the other strains. In CD-1 mouse liver, millimolar Km, NAD-dependent ALDH activity was found in mitochondria (60%), microsomes (23%) and cytosol (5%). In rabbit liver, millimolar Km, NAD-dependent ALDH was also distributed among mitochondria (36%), microsomes (19%) and cytosol (28%). At micromolar substrate concentrations, mitochondria possessed the majority of rat, mouse and rabbit liver ALDH activity. In all three species, NADP-dependent ALDH activity was found predominantly in the microsomal fraction (up to 65%). The cytosol possessed little NADP-dependent ALDH in any species. We conclude that there are significant species differences in the subcellular distribution of aldehyde dehydrogenase between rat, mouse and rabbit liver. In all three species, mitochondria and microsomes possessed the majority of hepatic aldehyde dehydrogenase activity. However, the cytosol of mouse and rabbit liver also made a significant contribution to total ALDH activity. For the six rat strains examined, liver cytosol possessed little or no ALDH activity.

Inhibition of the oxidation of acetaldehyde and formaldehyde by hepatocytes and mitochondria by crotonaldehyde

Crotonaldehyde was oxidized by disrupted rat liver mitochondrial fractions or by intact mitochondria at rates that were only 10 to 15% that of acetaldehyde. Although a poor substrate for oxidation, crotonaldehyde is an effective inhibitor of the oxidation of acetaldehyde by mitochondrial aldehyde dehydrogenase, by intact mitochondria, and by isolated hepatocytes. Inhibition by crotonaldehyde was competitive with respect to acetaldehyde, and the Ki for crotonaldehyde was about 5 to 20 microM. Crotonaldehyde had no effect on the oxidation of glutamate or succinate. Very low levels of acetaldehyde were detected during the metabolism of ethanol. Crotonaldehyde increased the accumulation of acetaldehyde more than 10-fold, indicating that crotonaldehyde, besides inhibiting the oxidation of added acetaldehyde, also inhibited the oxidation of acetaldehyde generated by the metabolism of ethanol. Formaldehyde was a substrate for the low-Km mitochondrial aldehyde dehydrogenase, as well as for a cytosolic, glutathione-dependent formaldehyde dehydrogenase. Crotonaldehyde was a potent inhibitor of mitochondrial oxidation of formaldehyde, but had no effect on the activity of formaldehyde dehydrogenase. In hepatocytes, crotonaldehyde produced about 30 to 40% inhibition of formaldehyde oxidation, which was similar to the inhibition produced by cyanamide. This suggested that part of the formaldehyde oxidation occurred via the mitochondrial aldehyde dehydrogenase, and part via formaldehyde dehydrogenase. The fact that inhibition by crotonaldehyde is competitive may be of value since other commonly used inhibitors of aldehyde dehydrogenase are irreversible inhibitors of the enzyme.

Sequential metabolic alterations in the myocardium during influenza and tularemia in mice

Mice with generalized influenza or tularemia of similar lethality were studied in an effort to compare biochemical responses of the myocardium during infections of viral and bacterial etiology. A progressive loss of body weight characterized the course of both infections. Accompanying this, the myocardial content of protein and the activities of lactate dehydrogenase, citrate synthase, and cytochrome c oxidase all decreased. However, myocardial protein degradation appeared earlier and was more pronounced in influenza, and the protein changes were accompanied by a rapid decline of myocardial RNA. Activation of acid hydrolases, such as cathepsin D and beta-glucuronidase, occurred in tularemia but not in influenza, whereas leakage of beta-glucuronidase into the plasma occurred in both infections. Conversely, there was a considerably greater activation of myocardial catalase in influenza. These findings suggested that different control mechanisms or metabolic pathways were operative in the degradation of myocardial constituents in influenza as compared with tularemia. The absence of histological signs of myocarditis in either infection appeared to exclude any direct local effects of an inflammatory process on myocardial cells. Since the infections were of comparable lethality (based upon the inoculated dose of organisms), the observed differences in pattern and extent of metabolic responses of the myocardium to these infections may be attributed to different pathophysiological mechanisms evoked by the different microorganisms.

Modifying effects of exercise on clinical course and biochemical response of the myocardium in influenza and tularemia in mice

For a study of the interactions of strenuous physical exercise (daily swimming to exhaustion) and a viral as compared with a bacterial infection with regard to the clinical course and the biochemical response of the myocardium, influenza and tularemia of similar lethality were used in mice. In both infections, expected infection-induced catabolic alterations in the ventricular myocardium were evident 2 days before median lethality was achieved, with a more pronounced wasting in influenza than in tularemia. Exercise before inoculation (preconditioning) was beneficial in that the catabolic effects of both infections were limited and lethality in influenza was reduced. Thus, the myocardial protein-degrading effect of influenza did not occur with preconditioning, and oxidative tissue enzyme activities decreased less. In tularemia, cytochrome c oxidase activity was fully preserved with preconditioning, and activation of catalase was less pronounced. Exercise during ongoing infection counteracted the infection-induced decrease in the activities of glycolytic and oxidative enzymes in tularemia, but lethality and bacterial counts in the spleen were uninfluenced. Conversely, exhaustive exercise in influenza increased lethality and had no significant effect on cardiac enzymes. These exercise models caused no major alterations in activation of lysosomal enzymes (beta-glucuronidase and cathepsin D).

Ethanol effects on protein synthesis in nonparenchymal liver cells, hepatocytes, and density populations of hepatocytes

Rats were given ethanol chronically (20-30% of the energy) in a nutritionally sufficient diet regimen. Controls received lipid as an isoenergetic substitute for ethanol. Protein synthesis in hepatocytes isolated from ethanol-fed rats was decreased compared with controls, but not in isolated nonparenchymal liver cells. Ethanol added in vitro inhibited protein synthesis in hepatocytes by 30%, but not in nonparenchymal cells for both ethanol-fed and control rats. Protein export and protein degradation in isolated hepatocytes were not affected by long-term ethanol treatment. Isolated hepatocytes were separated according to their buoyant density in linear metrizamide gradients. They were distributed in a bell-shaped manner regardless of donor rat treatment. Cells of low density contained three times as much lipid as high density cells. They were probably enriched in periportal cells, since histologic examination indicated a predominantly periportal localization of cells containing lipid droplets. Distribution of the intra-acinar marker alanine aminotransferase supported this conclusion. Protein synthesis was similar in the low-density hepatocyte populations of the respective groups of rats, whereas it was inhibited in a high-density population of ethanol-treated rats compared to the controls. Inhibition of protein synthesis by 80 mM ethanol was lower in the low-density hepatocytes of ethanol-fed rats.

Effect of acetaldehyde and cyanamide on the metabolism of formaldehyde by hepatocytes, mitochondria, and soluble supernatant from rat liver

Formaldehyde can be metabolized primarily by two different pathways, one involving oxidation by the low-Km mitochondrial aldehyde dehydrogenase, the other involving a specific, glutathione-dependent, formaldehyde dehydrogenase. To estimate the roles played by each enzyme in formaldehyde metabolism by rat hepatocytes, experiments with acetaldehyde and cyanamide, a potent inhibitor of the low-Km aldehyde dehydrogenase were carried out. The glutathione-dependent oxidation of formaldehyde by 100,000g rat liver supernatant fractions was not affected by either acetaldehyde or by cyanamide. By contrast, the uptake of formaldehyde by intact mitochondria was inhibited 75 to 90% by cyanamide. Acetaldehyde inhibited the uptake of formaldehyde by mitochondria in a competitive fashion. Formaldehyde was a weak inhibitor of the oxidation of acetaldehyde by mitochondria, suggesting that, relative to formaldehyde, acetaldehyde was a preferred substrate. In isolated hepatocytes, cyanamide, which inhibited the oxidation of acetaldehyde by 75 to 90%, produced only 30 to 50% inhibition of formaldehyde uptake by cells as well as of the production of 14CO2 and of formate from [14C]formaldehyde. The extent of inhibition by cyanamide was the same as that produced by acetaldehyde (30-40%). In the presence of cyanamide, acetaldehyde was no longer inhibitory, suggesting that acetaldehyde and cyanamide may act at the same site(s) and inhibit the same formaldehyde-oxidizing enzyme system. These results suggest that, in rat hepatocytes, formaldehyde is oxidized by cyanamide- and acetaldehyde-sensitive (low-Km aldehyde dehydrogenase) and insensitive (formaldehyde dehydrogenase) reactions, and that both enzymes appear to contribute about equally toward the overall metabolism of formaldehyde.

Biochemical and morphological alterations of baboon hepatic mitochondria after chronic ethanol consumption

Baboons fed ethanol (50% of total calories) chronically develop ultrastructural alterations of hepatic mitochondria. To determine whether mitochondrial functions are also altered, mitochondria were isolated from nine baboons fed ethanol chronically and their pair-fed controls. At the fatty liver stage, ADP-stimulated respiration was depressed in ethanol-fed baboons by 59.4% with glutamate, 43.2% with acetaldehyde, 45.1% with succinate and 51.1% with ascorbate as substrates. A similar decrease was noted in the ADP/O ratio (14 to 28%) and respiratory control ratio (20 to 44%) with all substrates. Similar alterations of mitochondrial functions were observed in baboons with more advanced stages of liver disease, namely fibrosis. These changes after ethanol treatment were associated with decreases in the enzyme activities of mitochondrial respiratory chain: glutamate, NADH and succinate dehydrogenase (42, 24 and 28%, respectively), glutamate-, NADH- or succinate-cytochrome c reductase (42, 27 and 32%, respectively) and cytochrome oxidase (59.6%). The content of all cytochromes was also decreased in ethanol-fed baboons, especially aa3 (57%). Moreover, [14C]leucine incorporation into mitochondrial membranes was depressed by 21% after ethanol treatment. On the other hand, glutamate dehydrogenase activities of serum and cytosol in ethanol-fed baboons were significantly higher than those in pair-fed controls. Morphologically, mitochondria of ethanol-fed baboons were larger than those of pair-fed controls. However, the mitochondrial protein content per mitochondrial DNA was unchanged. From these results, we conclude that, morphologically and functionally, hepatic mitochondria in baboons are altered by chronic ethanol consumption; it is noteworthy that these changes are fully developed already at the fatty liver stage, and that morphological alteration appears to reflect the damage of mitochondrial membranes rather than an adaptive hypertrophy.

Activities of NAD+-dependent aldehyde dehydrogenase and alcohol dehydrogenase in the liver of spontaneously hypertensive rats in the process of development

The difference in the basal activities of NAD+-dependent aldehyde dehydrogenase (ALDH) and alcohol dehydrogenase (ADH) was investigated in the liver of age-matched spontaneously hypertensive (SH) and normotensive Wistar Kyoto (WK) rats. A significant difference between the SH and WK rats in the basal ALDH activity, ADH activity and the protein content of subcellular fractions was observed. The activities of mitochondrial low Km- and high Km-ALDH in the SH rats at 5-8 weeks of age were higher than those in the WK rats. The microsomal high Km-ALDH activity in the SH rats at 5 and 11 weeks of age was higher than that in the WK rats. The ADH activities in the SH rats at 5-14 weeks of age were lower than those in the WK rats. The mitochondrial protein content in the SH rats at 5-14 weeks of age was higher than those in the WK rats. At 14 weeks of age, an increase in the blood acetaldehyde level was observed after an intraperitoneal injection of 1.5 g/kg of ethanol in the SH rats. No difference in blood ethanol level was observed between the SH and WK rats.

Subcellular aldehyde dehydrogenase activity and acetaldehyde oxidation by isolated intact mitochondria of rat brain and liver after acetaldehyde treatment

The effect of treatment of rats with acetaldehyde on the subcellular NAD+-aldehyde dehydrogenase (EC 1.2.1.3, ALDH) activities and acetaldehyde oxidation by isolated intact mitochondria of the liver and the brain was studied. Inhalation of acetaldehyde caused a significant decrease in the liver mitochondrial low Km-ALDH activity, while brain mitochondrial ALDH activity remained unchanged. Acetaldehyde oxidation by isolated intact liver mitochondria decreased significantly but that by brain mitochondria remained unchanged after acetaldehyde inhalation. These findings raise the possibility that the brain enzyme may be exposed to lower concentration of acetaldehyde than the liver enzyme.

Effects of Streptococcus pneumoniae, Salmonella typhimurium and Francisella tularensis infections on oxidative, glycolytic and lysosomal enzyme activity in red and white skeletal muscle in the rat

Since opinions differ as to whether the oxidative and glycolytic capabilities of skeletal muscle are altered in acute infection, enzyme activities in oxidative, glycolytic and degradative (acid hydrolases) pathways and total protein and DNA were determined in skeletal muscle of rats infected with Streptococcus pneumoniae, Salmonella typhimurium or Francisella tularensis. Studies were performed separately in red (slow twitch) and white (fast twitch) muscle tissue because these fibers function during different types of exercise. In the salmonella- and tularemia-infected rats, the intramitochondrially located oxidative enzymes of muscle were decreased to 56-83% of controls whereas the glycolytic enzyme situated in the cytosol showed an earlier and more pronounced loss of activity, 30-75% of controls. In the pneumococcal infection, only reduced glycolytic activity was significant. DNA concentrations were unchanged in any infection. Reductions during tularemia were statistically correlated with whole-cell protein degradation, while that of the glycolytic enzyme was parallelled by activation of lysosomal enzymes. Red and white muscle tissues responded similarly, in contrast to several other pathologic states that involve a catabolic component of muscle with a predominant response (or damage) in one or the other fiber type.

Alcohol-induced mitochondrial changes in the liver

The chronic ingestion of ethanol results in liver-cell damage, and characteristic features of this injury are the marked alterations in both the functions and morphology of the mitochondria. Morphologically, the changes observed in human alcoholics and experimental animals appear similar. Bizarrely shaped mitochondria and megamitochondria are detected at the fatty liver stage and persist as the disease progresses. As yet, however, no correlation has been found between the severity of these morphological changes and the development of cirrhosis. Analysis of the mitochondrial membranes indicates that ethanol consumption produces changes in both the protein and lipid composition of the membrane. Profound decreases in the components of the respiratory chain have been detected, and these changes are associated with marked depressions in the activity of NAD+-linked dehydrogenases, cytochrome oxidase, and the ATP synthetase complex. On the other hand, no consistent pattern has emerged as to the effect of chronic ethanol consumption on the composition of the membrane phospholipids. Many of the changes appear to be dependent on the sex of the animal, the dietary status, and the duration of ethanol intake, and are suggestive of changes in fatty acid desaturase activity. Mitochondria isolated from ethanol-fed rats displayed impaired respiration and a lowered steady-state rate of ATP synthesis. Whether or not these functional changes are directly related to alterations in the physical properties of the membranes remains to be resolved. This marked depression of respiratory functions in isolated mitochondria was not reflected by a significant decrease in O2 consumption by the livers of ethanol-fed animals.

Effects of chronic ethanol feeding and acetaldehyde metabolism on calcium transport by rat liver mitochondria

The prolonged feeding of ethanol to rats alters in vitro mitochondrial transport of calcium. Hepatic mitochondria isolated from rats fed ethanol for 7 weeks exhibited decreased retention of calcium in the presence of 4mM-Pi. This defect was associated with enhanced efflux of calcium when mitochondria were incubated with EGTA. Acetaldehyde at low, "physiological" concentrations (100 microM) enhanced calcium retention by mitochondria but this response was blunted after chronic ethanol administration. The in vitro actions of acetaldehyde appear to be mediated, in part, by its metabolism in mitochondria since pretreatment of rats with cyanamide (an aldehyde dehydrogenase inhibitor) prevents this effect.

Metabolism of malondialdehyde by rat liver aldehyde dehydrogenase

Mammalian liver contains a group of pyridine nucleotide linked aldehyde dehydrogenases [E.C. 1.2.1.3] which are present in high specific activity and possess wide substrate specificities. Malondialdehyde (MDA), a difunctional three-carbon aldehyde thought to be toxic, is generated during membrane lipid peroxidation in hepatocytes. The role of aldehyde dehydrogenase (ALDH) in the metabolism of MDA was tested in vitro with subcellular fractions and semipurified cytosolic preparations from rat livers. The cytosolic fraction accounted for virtually all of the MDA (50 microM) metabolizing activity observed in the postnuclear supernatant fraction. The rate of MDA disappearance was relatively low in the mitochondrial fraction and was not detectable in reaction mixtures which contained microsomes. Rat liver cytosol contained two ALDHs with MDA metabolizing activity. These enzymes were separated by DEAE-cellulose ion exchange chromatography and had apparent Km values of 16 microM and 128 microM for malondialdehyde. Mitochondria contained an ALDH enzyme with lower affinity (Km of 7.3 mM with NAD+) for malondialdehyde. These data show that rat liver contains at least three ALDH enzymes which oxidize malondialdehyde.

A study of hepatic protein synthesis, three subcellular enzymes, and liver morphology in chronically ethanol fed rats

Male Wistar rats were given ethanol chronically (20-30% of the energy as ethanol) in a nutritionally sufficient regimen. Controls received lipid as isoenergetic substitute for ethanol. Treatment lasted for 2 or 8 weeks. Hepatic protein synthesis was measured in fasted rats during a 32 min. continuous infusion of 3H-valine. After 2 weeks of treatment accumulation of hepatic protein was observed in the ethanol group, but there was no change in hepatic protein synthesis or morphology. After 8 weeks the rate of hepatic protein synthesis was decreased by 35% in the ethanol group, but there was no accumulation of protein and a slight accumulation of intracellular lipid droplets. Neither the subcellular distribution of incorporated 3H-valine, nor the activities and distributions of alcohol dehydrogenase and NADPH cytochrome c reductase were changed. Mitochrondrial cytochrome c oxidase activity was decreased in the ethanol group, and cytosolic and microsomal fractions showed higher cytochrome c oxidase activity in this group. Chronic ethanol treatment for 8 weeks had an adverse effect on general protein synthesis as well as on a specific enzyme in the liver in the absence of serious morphologic abnormalities.

Studies in vitro on the inactivation of mitochondrial rat-liver aldehyde dehydrogenase by the alcohol-sensitizing compounds cyanamide, 1-aminocyclopropanol and disulfiram

The inhibition of the low-Km, rat-liver mitochondrial aldehyde dehydrogenase (ALDH) by the alcohol-sensitizing agents cyanamide, 1-aminocyclopropanol (ACP) and disulfiram was studied in vitro. All three compounds caused a progressive decline in the enzyme activity. Restoration of activity could not be achieved by gel-filtration, dilution or by the addition of excess thiol. High concentrations of acetaldehyde partly restored the activity of the cyanamide-inactivated enzyme but had no effects on the disulfiram- or ACP-inactivated enzyme. In the presence of saturating concentrations of the coenzyme (NAD+), the inactivation process followed first-order kinetics at fixed concentrations of the inhibitors. Plots of the apparent first-order rate constants against inhibitor concentration were curved, suggesting the formation of saturable, reversible holoenzyme-inhibitor complexes prior to the covalent reactions. In the absence of NAD+, the rate of inactivation by disulfiram was biphasic and considerably higher than that in the presence of NAD+. In contrast, no inactivation was obtained with cyanamide in the absence of NAD+. Likewise, the presence of NAD+ greatly promoted the inactivation by ACP. The esterase activity of the enzyme was also affected by the inhibitors, although to a lesser extent than was the dehydrogenase activity. The results obtained suggest that all three inhibitors inactivate the enzyme through covalent reactions with the thiol groups at the active site. It is proposed that binding of NAD+ limits access of disulfiram to the thiols at the active site but provides a situation that favours an electrophilic attack of cyanamide and ACP on the thiol groups.

Ethanol oxidation in systems containing soluble and mitochondrial fractions of rat liver. Regulation by acetaldehyde

Systems containing soluble fraction of rat liver, with or without mitochondrial fraction, oxidised [1-14C] ethanol to acetaldehyde, 14CO2 and non-volatile 14C-products of which acetate was the principal, and possibly the only, component. Ethanol oxidation was stimulated by pyruvate which served as an electron sink thereby allowing rapid regeneration of NAD. When no mitochondria were present acetaldehyde accumulated, rapidly at first but eventually reaching a plateau. The rate of ethanol oxidation in these systems was much lower than the measured maximum activity of alcohol dehydrogenase (ADH) and it was concluded that ADH was inhibited by the accumulated acetaldehyde. Mitochondria, because of their relatively high aldehyde dehydrogenase (ALDH) activity, prevented the accumulation of acetaldehyde, or quickly removed acetaldehyde already accumulated. This action was accompanied by a sharp increase in the rate of ethanol oxidation, presumably due to the deinhibition of ADH. Cyanamide, an inhibitor of mitochondrial ALDH, blocked the stimulatory effect of mitochondria on ethanol oxidation. It was concluded that, in the reconstituted systems, acetaldehyde played a dominant role in controlling the rate of ethanol oxidation. The possible importance of acetaldehyde in governing ethanol oxidation in vivo is discussed.

Subcellular localization of acetaldehyde dehydrogenase in human liver

The subcellular distribution of aldehyde dehydrogenase activity was determined in human liver biopsies by analytical sucrose density-gradient centrifugation. There was bimodal distribution of activity corresponding to mitochondrial and cytosolic localizations. At pH 9.6 cytosolic aldehyde dehydrogenase had a lower apparent Kappm for NAD (0.03 mmol l-1), than the mitochondrial enzyme (Kappm NAD = 1.1 mmol l-1). Also, the pH optimum for cytosolic aldehyde dehydrogenase activity (pH 7.5) was lower than that for the mitochondrial enzyme activity (pH 9.0), and the cytosolic enzyme activity was more sensitive to inhibition by disulfiram in vitro. Disulfiram (40 mumol l-1) caused a 70% reduction in cytosolic aldehyde dehydrogenase activity, but only a 30% reduction in mitochondrial enzyme activity after 10 min incubation. The liver cytosol may therefore be the major site of acetaldehyde oxidation in vivo in man.

Species differences in zearalenone-reducing activity in subcellular fractions of liver from female domestic animals

The subcellular distribution of the zearalenone-reducing activity in liver from female pig, goat, sheep, cow and hen was investigated. The distribution patterns for the reduction of zearalenone to alpha- or beta-zearalenol differed between species and was also dependent upon coenzyme. Pig and goat had the greatest ability to form both alpha- and beta-zearalenol in the microsomal fraction independently of coenzyme. Cow and hen formed alpha-zearalenol almost entirely in the microsomal fraction and beta-zearalenol only in the cytosol fraction and only with NADPH as coenzyme. The sheep was distinct from the pig and goat in having the highest alpha-zearalenol forming activity in the cytosol fraction when NADPH was used as coenzyme.

The subcellular distribution and properties of aldehyde dehydrogenase of hepatoma AH-130

Aldehyde dehydrogenase subcellular distribution and activity were studied in the Yoshida hepatoma AH-130 and rat liver. NAD+- and NADP+-dependent dehydrogenase activities were lower in all hepatoma subfractions (except the cytosol) than in liver subfractions. In the presence of 0.025 mM substrate 78-80% of the liver NAD+- or NADP+-dependent aldehyde dehydrogenase was found in the mitochondria. With 10 mM substrate the enzyme activity was primarily in the mitochondria and microsomes. In the hepatoma a sharp increase of the soluble aldehyde dehydrogenase (either NAD+- or NADP+ dependent) was observed at all substrate concentrations. The Km of the different isoenzymes (either identified by their localization or coenzyme dependency) were of the same order for liver and hepatoma. However, a high Km enzyme was present in liver mitochondria outer membranes but not in hepatoma. Hepatoma acetaldehyde dehydrogenase was inhibited, as was the liver enzyme, by diethyldithiocarbamate. The return of activity was slower for the hepatoma and neonatal liver than for the adult liver enzyme.

Relationship between muscle morphology and metabolism in obese women: the effects of long-term physical training

To evaluate the relationships between changes in muscle morphology and metabolic adaptation to physical training in obesity, twenty obese women were subjected to a physical training programme with three sessions a week for 3 months. Physical training resulted in lowering of plasma insulin and improved glucose tolerance. Neither body weight nor body fat changed. With physical training the percentage distribution of fast twitch oxidative (FTa) muscle fibres (m vastus lateralis) increased (from 30.3 +/- 5.1% to 35.2 +/- 4.8%, P less than 0.05) and that of fast twitch glycolytic fibres decreased (from 18.3 +/- 6.6 to 5.8 +/- 4.8%, P less than 0.05). The number of capillaries increased, mainly around slow twitch (ST) fibres (from 4.5 +/- 0.6 to 5.8 +/- 0.8, P less than 0.01) and fast twitch oxidative (FTa) fibres (from 3.9 +/- 0.7 to 4.7 +/- 0.8, P less than 0.01). The activities of oxidative enzymes (cytochrome-c-oxidase and citrate synthase) increased (P less than 0.05) while those of glycolytic enzymes (phosphofructokinase and hexokinase) decreased after physical training (P less than 0.01). Significant negative correlations between plasma insulin and number of capillaries in contact with ST fibres (r = 0.80, P less than 0.001) and FTa fibres (r = 0.62, P less than 0.001) were found before training. The capillary density around those fibres could predict 80% of the explained variance of plasma insulin levels (P less than 0.001). The changes of glucose concentration after training could be predicted by observed changes in enzyme activities. The strong associations between muscle morphology and capillarization and enzyme activities and glucose and insulin concentrations and their changes after training suggest an important regulatory role of muscle which warrants further studies.

Dissociation of training effects on skeletal muscle mitochondrial enzymes and myoglobin in man

The effect of endurance training on skeletal muscle myoglobin concentration in man was investigated. 8 healthy sedentary males (20-31 yrs) trained on cycle ergometers 40 min/day, 4 days a week for 8 weeks. The work consisted of continuous exercise at a work load that during the last 5 weeks corresponded to 75% of the pretraining maximal oxygen uptake (VO2 max). The training program resulted in a 7% increase in VO2 max (p less than 0.01). The activities of the mitochondrial enzymes citrate synthase (CS), succinate dehydrogenase (SDH) and cytochrome c oxidase (Cyt-c-ox) in the quadriceps femoris muscle, as indicators of muscle respiratory capacity, increased by 62-82% (p less than 0.01). The metabolic adaptation of skeletal muscle was further indicated by a 17% increase in the work load corresponding to a blood lactate concentration of 4 mmol/l, as determined by a progressive exercise test (p less than 0.05). There was, however, no change in the myoglobin concentration of the thigh muscle with training (-1%, NS). It is suggested that endurance exercise in man at 75% of the maximal oxygen uptake does not severely tax the functions of myoglobin in skeletal muscle.

Activities of key enzymes in relation to glucose flux in tumor-host livers

1. Isotope and non-isotope methods were used to study hepatic metabolism of glucose in tumor-host livers. 2. Glycogen synthase, phosphofructokinase activities (Vmax) were decreased, while glucose-6-phosphate dehydrogenase and lactate dehydrogenase activities were increased in tumor-host livers. 3. Glycogen phosphorylase, glucokinase and several mitochondrial enzymes, had normal maximum activity in tumor-host livers. Net flux of glucose was decreased in the Embden-Meyerhof and the pentose phosphate pathway in tumor animals. 4. The hepatic cycling of glucose-carbons in tumor animals was significantly decreased as shown by different [14C] [3H] ratios of radioactivity in RNA and lactate, determined from simultaneous incorporation of [U-14C]glucose and [2-3H]glucose. 5. This study demonstrates that previous reports of increased activities of rate limiting enzymes of glucose metabolism in tumor-host livers do not represent a general finding of high glucose metabolism in tumor-host livers.

The role of cytoplasmic aldehyde dehydrogenase in the metabolism of N-tele-methylhistamine

The subcellular distributions of aldehyde dehydrogenase activities towards acetaldehyde have been compared with those toward N-tele-methylimidazole acetaldehyde, the aldehyde derived from the oxidation of N-tele-methylhistamine. At high concentrations of acetaldehyde (3.0 mM), significant aldehyde dehydrogenase activity can be found in the mitochondrial, light mitochondrial, microsomal and cytoplasmic fractions whereas, when the activity is determined with 15 microM acetaldehyde, the enzyme activity is enriched only in the mitochondrial fraction suggesting that this organelle will be the dominant site for the metabolism of acetaldehyde derived from ingested ethanol. The activity towards N-tele-methylimidazole acetaldehyde was determined by generating this compound in the assay by the oxidation of N-tele-methylhistamine in the presence of beef plasma amine oxidase. At the low steady-state aldehyde concentrations that will be present in such an assay, only the cytoplasmic form of aldehyde dehydrogenase showed activity towards this substrate.