Biogenic aldehyde metabolism in rat brain. Differential sensitivity of aldehyde reductase isoenzymes to sodium valproate

The effects of inhibitors of aldehyde reductase (alcohol:NADP+ oxidoreductase, EC 1.1.1.2) on the formation of 3-methoxy-4-hydroxyphenethylene glycol from normetanephrine have been studied in rat brain homogenates. The reaction pathway was shown to be unaffected by several inhibitors of the major (high Km) form of aldehyde reductase such as sodium valproate. Two isoenzymes of aldehyde reductase have been separated and characterized from rat brain. The minor (low Km) isoenzyme is shown to be relatively insensitive to sodium valproate and exhibits a similar inhibitor-sensitivity profile to that obtained for methoxyhydroxyphenethylene glycol formation. The low Km isoenzyme is therefore implicated in catecholamine metabolism. The metabolism of succinic semialdehyde and xylose by rat brain cytosol has also been examined. Aldose metabolism may also be attributed to the action of the low Km reductase, but the existence of a separate succinic semialdehyde reductase is postulated. The possible roles of aldehyde reductases in brain metabolism and the relationship between these enzymes and aldose reductase (alditol:NADP+ 1-oxidoreductase, EC 1.1.1.21) are discussed.     

Characterization of microsomal NADPH-dependent aldehyde reductase from rat brain

An NADPH-dependent aldehyde reductase was purified from rat brain microsomes to electrophoretic homogeneity. The purified enzyme had a molecular weight of 75,000 and reduced long chain fatty aldehydes such as octanal and hexadecanal with higher affinity (Km values of 0.21 mM and 0.03 mM, respectively) than for various artificial carbonyl compounds such as p-nitrobenzaldehyde and p-nitroacetophenone (Km values of 0.31 mM and 1.4 mM, respectively). The purified microsomal aldehyde reductase also showed NADPH-cytochrome c reductase activity, and it could not be distinguished from NADPH-cytochrome c reductase in molecular weight (75,000), chromatographic behavior, electrophoretic mobility, or immunological properties. The solubilized microsomal fraction treated with steapsin lost the reductase activity for hexadecanal but not that for cytochrome c. These results suggest that the aldehyde reductase in brain microsomes is identical to NADPH-cytochrome c reductase and that a hydrophobic portion of the NADPH-cytochrome c reductase is required for the reduction of hexadecanal.     

Side-chain metabolism of propranolol: involvement of monoamine oxidase and aldehyde reductase in the metabolism of N-desisopropylpropranolol to propranolol glycol in rat liver

The further metabolism of N-desisopropylpropranolol (NDP), a side-chain metabolite of propranolol (PL), was investigated in isolated rat hepatocytes. Propranolol glycol (PGL) was generated from NDP as a major metabolite. Naphtetrazole (NTE), a potent inhibitor of monoamine oxidase (MAO), significantly retarded the disappearance of NDP from the incubation medium, suggesting the involvement of MAO in the deamination of NDP to an aldehyde intermediate. In a reaction mixture of rat liver mitochondria and cytosol with NADPH, phenobarbital, a specific inhibitor of aldehyde reductase, and 4-nitrobenzaldehyde (4-NBA), a substrate inhibitor of aldehyde reductase, decreased the formation of PGL from NDP. 4-NBA was a competitive inhibitor of the enzyme responsible for the PGL formation. The optimal pH for the formation of PGL from NDP in the reaction mixture was approximately 8.0. Based on these results, we propose the possibility that, in the rat liver, MAO catalyzes the oxidative deamination of NDP to an aldehyde intermediate and the formed aldehyde intermediate is subsequently reduced to PGL by aldehyde reductase. Furthermore, the enantioselective metabolism of NDP to PGL was examined. In isolated rat hepatocytes, the amount of PGL formed from S-NDP [S(-)-form of NDP] was larger than that of PGL formed from R-NDP [R(+)-form of NDP].     

Participation of microsomal aldehyde reductase in long-chain fatty alcohol synthesis in the rat brain

The participation of microsomal aldehyde reductase in long-chain fatty alcohol synthesis in the rat brain was examined. A reaction mixture of [1-14C]hexadecanoic acid with brain microsomes and NADPH formed two radioactive products having the same mobilities as pure hexadecanal (RF 0.61) and hexadecanol (RF 0.22), respectively, on TLC plates. The product of the RF 0.61 spot was further identified as hexadecanal using gas-liquid chromatography after methylation and TLC of its reduced product with LiAlH4 and semicarbazide. The ratio of hexadecanal to hexadecanol varied from 0.4 to 1.2 under the present experimental conditions. When solubilized rat brain microsomes were applied to a Sepharose 4B column coupled with the rabbit antibody raised against rat liver microsomal NADPH-cytochrome-c reductase, which reacts with aldehyde reductase from rat brain, the eluted fraction ceased to form [14C]hexadecanol but continued to form [14C]hexadecanal from [14C]hexadecanoic acid. These results strongly indicate that hexadecanal is the intermediate in the synthesis of hexadecanol from hexadecanoic acid in rat brain microsomes with the participation of microsomal aldehyde reductase.     

Characterization of aldose reductase and aldehyde reductase from rat testis

Aldose reductase (alditol:NAD(P)+ 1-oxidoreductase, EC 1.1.1.21) and aldehyde reductase (alcohol:NADP+ oxidoreductase, EC 1.1.1.2) were purified to a homogeneity from rat testis. The molecular weights of aldose reductase and aldehyde reductase were estimated to be 38,000 and 41,000 by SDS-polyacrylamide gel electrophoresis, and the pI values of these enzymes were found to be 5.3 and 6.1 by chromatofocusing, respectively. Aldose reductase had activity for aldo-sugars such as xylose, glucose and galactose, whereas aldehyde reductase was virtually inactive for these aldo-sugars. The Km values of aldose reductase for aldo-sugars were relatively high. When a correction was made for the fraction of aldo-sugar present as the aldehyde form, which is the real substrate of the enzyme, the Km values were much lower. Aldose reductase utilized both NADPH and NADH as coenzyme, whereas aldehyde reductase utilized only NADPH. Aldose reductase was activated significantly by sulfate ion, while aldehyde reductase was little affected. Both enzymes were inhibited strongly by the known aldose reductase inhibitors. However, aldehyde reductase was in general less susceptible to these inhibitors when compared to aldose reductase. Both aldose reductase and aldehyde reductase treated with pyridoxal 5-phosphate have lost the susceptibility to aldose reductase inhibitor, suggesting that in these two enzymes aldose reductase inhibitor interacts with a lysine residue.     

Purification of the high-Km aldehyde reductase from rat brain and liver and from ox brain.

A procedure is described that yields an apparently homogeneous preparation of the high-Km aldehyde reductase from rat brain. This procedure is also applicable to the purification of this enzyme from rat liver and ox brain. In the latter case, however, the purified preparation could be resolved into two protein bands, both of which had enzyme activity, by polyacrylamide-gel electrophoresis. Since a sample of the ox brain enzyme from an earlier step in the purification procedure only showed the presence of a single band of activity after electrophoresis, this apparent multiplicity probably results from modification of the enzyme, possibly by oxidation, during the final step of the purification. A number of properties of the rat brain enzyme were determined and these were compared with those of the enzyme from rat liver. The two preparations were similar in their stabilities, behaviour during purification, kinetic properties, electrophoretic mobilities and amino acid compositions. Antibodies to the rat liver enzyme cross-reacted with that from brain and the inhibition of both these preparations by the antiserum was similar, further supporting the view that the enzymes from these two sources were closely similar if not identical.     

Subcellular localization of aldehyde reductase activities in ox brain.

The distribution of the two principal isoenzymes of aldehyde reductase (EC 1.1.1.2) has been studied in ox brain. The more active of these, which has been termed the high-Km enzyme, has been shown to be located in the cytosol and the less abundant low-Km form has a similar localization. p-Nitrobenzaldehyde, which has been used as a substrate in previous studies, caused the reduction of NADH in the presence of the mitochondrial fraction, but mixed substrate experiments with 1,3-dinitrobenzene and the effects of pH on the activity indicate that this is due to the presence of a nitro reductase activity which has been recently described (Köchli, Wermuth & von Wartburg (1980) Biochim. Biophys. Acta 616, 133-142] rather than to the low-Km aldehyde reductase activity. Fractionation of the mitochondria indicated this activity to be largely confined to the mitochondrial inner membrane.     

Polyacrylamide gel electrophoresis of rat brain acetylcholinesterase: isoenzymes of normal rat brain

Abstract— Triton-solubilized acetylcholinesterase (EC 3.1.1.7) of rat brain was submitted to vertical flatbed polyacrylamide gel electrophoresis. Three anodally migrating isoenzyme zones with low relative mobilities could be resolved, each of which on quantitative densitometry appeared to consist of more than one subzone. More than 50 per cent of the total AChE activity was exhibited by the isoenzyme zone closest to the origin (isoenzyme zone 3). Regional differences in AChE isoenzyme activity were quantitative only with the caudate-putamen complex, midbrain, pons and medulla oblongata exhibiting relatively high content of the three isoenzymes and the cerebral cortex and olfactory bulb possessing weak isoenzyme activities. Intermediate levels of isoenzyme activities were observed in the cerebellum and hippocampus. In all areas examined, the relative percentage values for each isoenzyme remained constant. AChE isoenzymes from the forebrain, brain stem and cerebellum of 15- and 30-day-old rats appeared to have identical patterns. In brain stem, no quantitative differences could be detected in the isoenzyme activities between 15 and 30 days of age. At both ages, the isoenzymes of male and female rats did not show any qualitative differences. The single cholinesterase (EC 3.1.1.8) isoenzyme which could be identified in brain stem supernatants of 30-day-old rats was weakly reactive and appeared to have the same relative mobility as the major acetylcholinesterase zone, zone 3. Acetylcholinesterase isoenzymes failed to demonstrate any differential response toward varying concentrations of inhibitors and to changes in pH. While there were basic similarities in the acetylcholinesterase and cholinesterase isoenzyme patterns of brain, serum, liver, skeletal muscle and intestine, brain alone exhibited a marked preponderance of the acetylcholinesterase isoenzyme zone 3.     

Differential heat sensitivity of human creatine kinase isoenzymes.

Creatine kinase isoenzymes (MM, MB and BB) were isolated from human tissue by ion-exchange chromatography. The B subunit was found to be more heat sensitive than the M subunit. BB and MB isoenzymes respond similarly to heat inactivation. Our results are in contrast with the body temperature inactivation of the brain isoenzyme reported by Lindsey and Diamond.     

Studies on distribution and metabolism of valproate in rat brain,liver, and kidney

Time-course studies on the distribution and metabolism of valproate (VPA) in rat brain, liver, and kidney, after intraperitoneal injection of a mixture of [¹⁴C]VPA and [³H]VPA, showed that: (1) maximal amount of radioactivity in the various tissues was observed after 30 min from the time the drug was administered; (2) at 30 min the distribution of labeled VPA in brain, liver, and kidney was 17%, 64%, and 19% of the total radioactivity, respectively; (3) at 24 hr more than 97% of the total radioactivity was lost from the tissues and the¹⁴C/³H ratios increased significantly with time. Studies on the regional distribution of the drug showed that it is relatively homogeneously distributed. Studies on the subcellular distribution of the drug showed that it is associated mostly with the soluble and mitochondrial fractions, with little radioactivity in the myelin and synaptosomal fractions. Radiochromatography of VPA metabolites in perchloric acid extracts from brain, liver, and kidney revealed the presence of four metabolites. VPA was not incorporated into phospholipids of the neuronal membranes. Furthermore, it had no significant effects on Mg²⁺-ATPase and (Na⁺+K⁺)-ATPase in synaptosomes and microsomes obtained either from control or from rats injected with VPA. It was concluded that this antiepileptic drug does not appear to act through its incorporation into neuronal membrane or through its action on the Na⁺ pump.Contribution No. 0601 from the Department of Cell and Molecular Biology, the Medical College of Georgia, Augusta, Georgia 30912.     

Effects of alcohol consumption on mitochondrial aldehyde dehydrogenase isoenzymes in rat liver

The effects of long-term and short-term exposure of rats to ethanol on aldehyde dehydrogenase (ALDH) activity in the liver mitochondria were investigated. The specific activities of mitochondrial high Km ALDH and low Km ALDH after the prolonged administration of ethanol were both increased to levels about 2.5 times that of the control group. In contrast, high Km and low Km ALDH showed maximum activity 12 h after administration of a single large dose of ethanol, increasing 21 and 4.4 times, respectively, over the level in the control group. When ethanol was administered for a long time, the two ALDH isoenzyme levels showed approximately the same increase, while the high Km ALDH level was more significantly increased than the low Km ALDH level after a single large dose. These results suggest that the high Km ALDH level of the outer membrane was increased as a result of a transient increase in the level of acetaldehyde around the liver mitochondria after a single large dose of ethanol, and that high Km ALDH plays an important role in acetaldehyde metabolism. However, when ethanol was administered for a long time, the mitochondria were exposed to low concentrations of acetaldehyde over a long time, leading to an increase in levels of low and high Km ALDH in the matrix.     

Disulfiram inhibition of aldehyde reductase from the rat liver

Disulphiram (tetraethylthiuram disulphide teturam, antabus), the known antialcoholic preparation, is studied for its effect on the aldehyde reductase activity (EC 1.1.1.1) in the rats' liver. Apparent Km and V are calculated for acetylaldehyde and NADH as well as Ki of disulphiram relative to the substrate and cofactor of the enzyme. The obtained data permit considering disulphiram a high-specific inhibitor of aldehyde reductase in rats' liver.     

Differential localization of sulfotransferase isoenzymes in rat liver.

Liver sections prepared from male and female rats were immunohistochemically stained with the antisera against phenol sulfotransferase G (P-STG), an isoenzyme of phenol ST as well as androsterone-sulfating ST (AD-ST), an isoform of hydroxysteroid ST. Localization of these isoenzymes in liver is sex-dependent and is markedly different between the two. P-STG is preferentially localized in the hepatocytes proximal to the central vein in females, whereas it is present in all the hepatocytes throughout the liver in males. On the other hand, AD-ST is evident in the hepatocytes proximal to the portal triad in males, while in females it is synthesized and localized in all the hepatocytes. The polarized sex-related localization of these ST isoenzymes appears to correlate with differential hormonal regulation of the enzymes.     

Purification and properties of low-Km aldehyde reductase from ox brain

A low-Km aldehyde reductase (alcohol:NADP+ oxidoreductase, EC 1.1.1.2), which may be identical with aldose reductase (alditol:NADP+ 1-oxidoreductase, EC 1.1.1.21), has been purified from ox brain to homogeneity. It was shown to be a monomer with Mr values of 31 000 and 35 100 being obtained by gel filtration and polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate, respectively. The enzyme catalyses the NADPH-dependent reduction of a number of aromatic and sugar aldehydes. The activity of the enzyme with 133 microM NADH was about one-third of that with 120 microM NADPH. Activity with both these coenzymes was optimum at pH 6.2 and was inhibited by increasing the ionic strength with KCl, NaCl or NaNO3. In contrast, the activity was stimulated by sodium phosphate. The activity with NADH as the coenzyme was more sensitive to stimulation by phosphate and to inhibition by increasing ionic strength than that determined with NADPH.     

Evidence for a role of high Km aldehyde reductase in the degradation of endogenous gamma-hydroxybutyrate from rat brain

gamma-Hydroxybutyrate (GHB) is a putative neurotransmitter in brain. We have already demonstrated that it is transformed into gamma-aminobutyrate (GABA) by rat brain slices incubated under physiological conditions. This conversion occurs via a GABA-transaminase reaction. Therefore, succinic semialdehyde, the oxidative derivative of GHB, appears to be the primary catabolite of GHB degradation. Apparently, the kinetic characteristics and pH optimum of GHB dehydrogenase (high Km aldehyde reductase) in vitro do not favor a role for this enzyme in endogenous brain GHB oxidation. However, in the presence of glucuronate, glutamate, NADP and pyridoxal phosphate, pure GHB dehydrogenase, coupled to purified GABA-transaminase does produce GABA from GHB at an optimum pH close to the physiological value and with a low Km for GHB.     

Purification and characterization of an NADH-linked aldehyde reductase from bovine brain

Abstract— The presence of a nonspecific NADH-linked aldehyde reductase was demonstrated in various regions of bovine brain in vitro. With m-nitrobenzaldehyde as substrate, the rate of NADH oxidation was approximately 4 nmol.min^-1.(mg of protein)^-1 in the cerebellum, pons and medulla; but somewhat lower rates [2–3 nmol.min^-1.(mg of protein)-^l] were obtained in the other areas of the brain examined. The enzyme was localized primarily in the soluble, supernatant fraction of rat brain homogenates. The enzyme from the supernatant fluid fraction of bovine brain was purified approximately 350-fold by ammonium sulphate fractionation and chromatography on calcium phosphate-gel, DEAE-cellulose and Sephadex G200 columns. The partially purified enzyme catalysed the reduction of a number of aldehydes, including substituted benzaldehydes and aliphatic aldehydes of intermediate chain lengths. Short chain aliphatic aldehydes, such as acetaldehyde, were not reduced by the enzyme and butyraldehyde was a poor substrate. With m-nitrobenzaldehyde as substrate, NADH was oxidized at an approximately 10-fold faster rate than NADPH. The pH optimum for the enzyme was 6.75 for aldehyde reduction, whereas the rate of oxidation of m-nitrobenzylalcohol was optimal at pH 10.0 with NAD as the co-substrate. K_m and K₃ values ranged from 10 μM to 10 mM for various aldehydes and from 10 to 30 μM for the cofactors. Oxidation of NADH by the partially purified enzyme was not inhibited by 10m pyrazole or by 1 mM phenobarbital. However, the enzyme activity was inhibited by approximately 60 percent by 1 mM chlorpromazine or by 5 mM 1,10-orthophenanthroline. Our data demonstrate that the enzyme is not only separable from the NADPH-linked aldehyde reductase described previously by TABAKOFF and ERWIN, but also is quite different in substrate specificity and inhibitor sensitivity from the ‘classical’, pyrazole-sensitive, NAD- linked alcohol dehydrogenase (EC 1.1.1.1).     

Partial purification and characterization of NADPH-linked aldehyde reductase from monkey brain

Abstract— The activity of NADPH-linked aldehyde reductase (EC 1.1.1.2) in various regions of monkey brain was determined in vitro. The highest specific activity of the enzyme was found in areas of the brain stem; including the pons, medulla and midbrain. A greater than 500-fold purification of the monkey brain enzyme was obtained by a combination of ammonium sulphate fractionation and subsequent chromatography on calcium phosphate gel cellulose and DEAE-cellulose. The aldehyde metabolites of the biogenic amines, norepinephrine, serotonin, dopamine and octopamine, were readily reduced by the NADPH-linked aldehyde reductase. The K_m values for 3,4-dihydroxyphenylglycolaldehyde, 3,4-dihydroxyphenyl-acetaldehyde, and 5-hydroxyindoleacetaldehyde were 12.0 μm , 6.1 μm and 27 μm , respectively. The maximum velocity (V_max) for 3,4-dihydroxyphenylglycolaldehyde was, respectively, five-fold or three-fold greater than that determined for 3,4-dihydroxyphenylacetaldehyde or 5-hydroxyindoleacetaldehyde. The highly purified enzyme derived from monkey brain was markedly inhibited by barbiturates, diphenylhydantoin, and chlorpromazine, but not by pyrazole. From data obtained by sucrose density gradient centrifugation and Sephadex chromatography the molecular weight of aldehyde reductase was determined to be about 70,000 daltons.     

Differential protein S-thiolation of glyceraldehyde-3-phosphate dehydrogenase isoenzymes influences sensitivity to oxidative stress

The irreversible oxidation of cysteine residues can be prevented by protein S-thiolation, in which protein -SH groups form mixed disulfides with low-molecular-weight thiols such as glutathione. We report here the identification of glyceraldehyde-3-phosphate dehydrogenase as the major target of protein S-thiolation following treatment with hydrogen peroxide in the yeast Saccharomyces cerevisiae. Our studies reveal that this process is tightly regulated, since, surprisingly, despite a high degree of sequence homology (98% similarity and 96% identity), the Tdh3 but not the Tdh2 isoenzyme was S-thiolated. The glyceraldehyde-3-phosphate dehydrogenase enzyme activity of both the Tdh2 and Tdh3 isoenzymes was decreased following exposure to H2O2, but only Tdh3 activity was restored within a 2-h recovery period. This indicates that the inhibition of the S-thiolated Tdh3 polypeptide was readily reversible. Moreover, mutants lacking TDH3 were sensitive to a challenge with a lethal dose of H2O2, indicating that the S-thiolated Tdh3 polypeptide is required for survival during conditions of oxidative stress. In contrast, a requirement for the nonthiolated Tdh2 polypeptide was found during exposure to continuous low levels of oxidants, conditions where the Tdh3 polypeptide would be S-thiolated and hence inactivated. We propose a model in which both enzymes are required during conditions of oxidative stress but play complementary roles depending on their ability to undergo S-thiolation.     

Inactivation of carbonyl reductase from human brain by phenylglyoxal and 2,3-butanedione: a comparison with aldehyde reductase and aldose reductase

Aldehyde reductase (alcohol:NADP+ oxidoreductase, EC 1.1.1.2), aldose reductase (alditol:NAD(P)+ 1-oxidoreductase, EC 1.1.1.21) and carbonyl reductase (secondary-alcohol:NADP+ oxidoreductase, EC 1.1.1.184) constitute the enzyme family of the aldo-keto reductases, a classification based on similar physicochemical properties and substrate specificities. The present study was undertaken in order to obtain information about the structural relationships between the three enzymes. Treatment of human aldehyde and carbonyl reductase with phenylglyoxal and 2,3-butanedione caused a complete and irreversible loss of enzyme activity, the rate of loss being proportional to the concentration of the dicarbonyl reagents. The inactivation of aldehyde reductase followed pseudo-first-order kinetics, whereas carbonyl reductase showed a more complex behavior, consistent with protein modification cooperativity. NADP+ partially prevented the loss of activity of both enzymes, and an even better protection of aldehyde reductase was afforded by the combination of coenzyme and substrate. Aldose reductase was partially inactivated by phenylglyoxal, but insensitive to 2,3-butanedione. The degree of inactivation with respect to the phenylglyoxal concentration showed saturation behavior. NADP+ partially protected the enzyme at low phenylglyoxal concentrations (0.5 mM), but showed no effect at high concentrations (5 mM). These findings suggest the presence of an essential arginine residue in the substrate-binding domain of aldehyde reductase and the coenzyme-binding site of carbonyl reductase. The effect of phenylglyoxal on aldose reductase may be explained by the modification of a reactive thiol or lysine rather than an arginine residue.