Martti Koivusalo

Evidence for the identity of glutathione‐dependent formaldehyde dehydrogenase and class III alcohol dehydrogenase

Formaldehyde dehydrogenase; Alcohol dehydrogenase, class III; Sequence homology; Amino acid sequence

Different forms of rat liver aldehyde dehydrogenase and their subcellular distribution

1. The properties and distribution of the NAD-linked unspecific aldehyde dehydrogenase activity (aldehyde: NAD+ oxidoreductase EC 1.2.1.3) has been studied in isolated cytoplasmic, mitochondrial and microsomal fractions of rat liver. The various types of aldehyde dehydrogenase were separated by ion exchange chromatography and isoelectric focusing. 2. The cytoplasmic fraction contained 10-15, the mitochondrial fraction 45-50 and the microsomal fraction 35-40% of the total aldehyde dehydrogenase activity, when assayed with 6.0 mM propionaldehyde as substrate. 3. The cytoplasmic fraction contained two separable unspecific aldehyde dehydrogenases, one with high Km for aldehydes (in the millimolar range) and the other with low Km for aldehydes (in the micromolar range). The latter can, however, be due to leakage from mitochondria. The high-Km enzyme fraction contained also all D-glucuronolactone dehydrogenase activity of the cytoplasmic fraction. The specific formaldehyde and betaine aldehyde dehydrogenases present in the cytoplasmic fraction could be separated from the unspecific activities. 4. In the mitochondrial fraction there was one enzyme with a low Km for aldehydes and another with high Km for aldehydes, which was different from the cytoplasmic enzyme. 5. The microsomal aldehyde dehydrogenase had a high Km for aldehydes and had similar properties as the mitochondrial high-Km enzyme. Both enzymes have very little activity with formaldehyde and glycolaldehyde in contrast to the other aldehyde dehydrogenases. They are apparently membranebound.

Liver aldehyde and alcohol dehydrogenase activities in rat strains genetically selected for their ethanol preference

Abstract Rat strains raised by genetical selection for either high (AA strain) or low (ANA strain) voluntary ethanol consumption were compared with respect to their hepatic alcohol and aldehyde dehydrogenase activities. Liver alcohol dehydrogenase activity was lower in both sexes in the AA strain compared with the ANA strain. The NAD-dependent aldehyde dehydrogenase activity was higher in the mitochondrial and microsomal fractions and lower in the soluble fraction in the AA strain than in the ANA strain. These differences were more pronounced in females than in males. The NAD-dependent utilization of acetaldehyde in liver homogenates was higher in the AA strain in both sexes, when the initial acetaldehydehyde level was 0·40 mM, but there was no difference at 0¢13 mM acetaldehyde. It is concluded that the higher activities in the AA strain are due mainly to those aldehyde dehydrogenases of mitochondrial and microsomal fractions, which have K m -values for aldehydes in the millimolar range. The higher alcohol dehydrogenase and lower aldehyde dehydrogenase activity in livers of rats of the ethanol-avoiding ANA strain may contribute to the previously found higher acetaldehyde levels in blood and liver of rats of this strain after ethanol administration.

Purification of formaldehyde and formate dehydrogenases from pea seeds by affinity chromatography and S-formylglutathione as the intermediate of formaldehyde metabolism

Abstract Formaldehyde dehydrogenase (EC 1.2.1.1) and formate dehydrogenase (EC 1.2.1.2) have been isolated in pure form from pea seeds by a rapid procedure which employs column chromatographies on 5′-AMP-Sepharose, Sephacryl S-200, and DE32 cellulose. The apparent molecular weights of formaldehyde and formate dehydrogenases are, respectively, 82,300 and 80,300 by gel chromatography, and they both consist of two similar subunits. The isoelectric point of formaldehyde dehydrogenase is 5.8 and that of formate dehydrogenase is 6.2. The purified formate dehydrogenase gave three corresponding protein and activity bands in electrophoresis and isoelectric focusing on polyacrylamide gel whereas formaldehyde dehydrogenase gave only one band. Formaldehyde dehydrogenase catalyzes the formation of S-formylglutathione from formaldehyde, and glutathione. Formate dehydrogenase can, besides formate, also use S-formylglutathione and two other formate esters as substrates. S-Formylglutathione has a lower Km value (0.45 m m ) than formate (2.1 m m ) but the maximum velocity of S-formylglutathione is only 5.5% of that of formate. Pea extracts also contain a highly active S-formylglutathione hydrolase which has been separated from glyoxalase II (EC 3.1.2.6) and partially purified. S-Formylglutathione hydrolase is apparently needed between formaldehyde and formate dehydrogenases in the metabolism of formaldehyde in pea seeds, in contrast to what was recently reported for Hansenula polymorpha, a yeast grown on methanol.

Demonstration of glyoxalase II in rat liver mitochondria. Partial purification and occurrence in multiple forms.

Glyoxalase II (S-(2-hydroxyacyl)glutathione hydrolase, EC 3.1.2.6), which has been regarded as a cytosolic enzyme, was also found in rat liver mitochondria. The mitochondrial fraction contained about 10-15% of the total glyoxalase II activity in liver. The actual existence of the specific mitochondrial glyoxalase II was verified by showing that all of the activity of the crude mitochondrial pellet was still present in purified mitochondria prepared in a Ficoll gradient. Subfractionation of the mitochondria by digitonin treatment showed that 56% of the activity resided in the mitochondrial matrix and 19% in the intermembrane space. Partial purification of the enzyme (420-fold) was also achieved. Statistically significant differences were found in the substrate specificities of the mitochondrial and the cytosolic glyoxalase II. Electrophoresis and isoelectric focusing of either the crude mitochondrial extract or of the purified mitochondrial glyoxalase II resolved the enzyme activity into five forms with the respective pI values of 8.1, 7.5, 7.0, 6.85 and 6.6. Three of these forms (pI values 7.0-6.6) were exclusively mitochondrial, with no counterpart in the cytosol. The relative molecular mass of the partially purified enzyme, as estimated by Superose 12 gel chromatography, was 21,000. These results give evidence for the presence of mitochondrial glyoxalase II which is different from the cytosolic enzymes in several characteristics.

Expression of Formaldehyde Dehydrogenase and S-Formylglutathione Hydrolase Activities in Different Rat Tissues

Formaldehyde is oxidized in animal cells into formate in two consecutive reactions catalyzed by the specific enzymes formaldehyde dehydrogenase (EC 1.2.1.1) and S-formylglutathione hydrolase (EC 3.1.2.12) (Uotila and Koivusalo, 1974a; 1974b). Formaldehyde reacts nonenzymically with glutathione (GSH) to form the adduct S-hydroxymethylglutathione. Formaldehyde dehydrogenase catalyzes the NAD-dependent oxidation of this adduct to S-formylglutathione. S-Formylglutathione hydrolase catalyzes the hydrolysis of S-formylglutathione to formate and GSH.

Isolation of glyoxalase II from two different compartments of rat liver mitochondria. Kinetic and immunochemical characterization of the enzymes

Two separate pools of glyoxalase II were demonstrated in rat liver mitochondria, one in the intermembrane space and the other in the matrix. The enzyme was purified from both sources by affinity chromatography on S-(carbobenzoxy)glutathione-Affi-Gel 40. From both crude and purified preparations polyacrylamide gel-electrophoresis resolved multiple forms of glyoxalase II, two from the intermembrane space and five from the matrix. Among the thioesters of glutathione tested as substrates, S-D-lactoylglutathione was hydrolyzed most efficiently by the enzymes from both sources. Significant differences were observed in the specificities between the intermembrane space and matrix enzymes with S-acetoacetylglutathione, S-acetylglutathione, S-propionylglutathione and S-succinylglutathione as substrates. Pure glyoxalase II from rat liver cytosol was chemically polymerized and used as antigen. Antibodies were raised in rabbits and the antiserum was used for comparison of the two purified mitochondrial enzymes with cytosolic glyoxalase II by immunoblotting. The enzyme purified from the intermembrane space cross-reacted with the antiserum, but the matrix glyoxalase II did not. The results give evidence for the presence in rat liver mitochondria of two species of glyoxalase II with differing characteristics. Only the enzyme from the intermembrane space appears to resemble the cytosolic glyoxalase II forms.

Partial purification and properties of a phenobarbital-induced aldehyde dehydrogenase of rat liver.

Properties of the phenobarbital induced cytoplasmic aldehyde dehydrogenase (EC 1.2.1.3) have been studied in rat liver. 7-12-Fold higher levels were seen in the cytoplasmic activities after phenobarbital treatment in reactor compared to non-reactor animals with high concentrations of acetaldehyde (18 mM) and propionaldehyde (9 mM). No difference was found with 0.12 mM acetaldehyde, 2 mM glycolaldehyde, 6 mM formaldehyde or 0.5 mM betaine aldehyde. The reactor group also had slightly higher activity in the mitochondrial fraction with the high acetaldehyde and propionaldehyde concentrations. In the microsomal fraction, the activities showed no differences at any substrate concentration. An induced aldehyde dehydrogenase was purified 70-fold by chromatographic techniques. It had different molecular and enzymic properties than the main high-Km enzyme normally present in rat liver cytoplasm. The pI of the induced enzyme was about 7.0 as measured by isoelectric focusing. It was active with several aliphatic and aromatic aldehydes but not with formaldehyde, glycolaldehyde or D-glyceraldehyde. The Km-values for propionaldehyde and acetaldehyde were in the millimolar range. Millimolar concentrations of aromatic aldehydes caused a strong substrate inhibition. The enzyme was inhibited by submicromolar concentrations of disulfiram. Estrone, deoxycorticosterone, progesterone and diethylstilbestrol also affected the enzyme activity.

Aryl hydrocarbon receptor-associated genes in rat liver: Regional coinduction of aldehyde dehydrogenase 3 and glutathione transferase Ya

The tumor-associated aldehyde dehydrogenase 3 (ALDH3) and the glutathione transferase (GST)Ya form are coded by members of the Ah (aryl hydrocarbon) battery group of genes activated in the liver by polycyclic hydrocarbons such as 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD). The physiological role of the Ah receptor (AHR), its gene-activating mechanism and its endogenous ligands are still poorly clarified. We had previously observed that 3-methylcholanthrene (3MC) and beta-naphthoflavone (betaNF) induced the AHR-associated CYP1A1/1A2 pair in different liver regions, an effect not explained by the acinar distribution of the AHR protein. Here, we investigated AHR-associated regional induction by comparing the expression patterns of ALDH3 and GSTYa. Analysis of samples from periportal and perivenous cell lysates from 3MC-treated animals revealed that ALDH3 mRNA, protein and benzaldehyde-NADP associated activity were all confined to the perivenous region. In contrast, such regio-specific induction was not seen after beta-NF induction. Immunohistochemically, a peculiar mono- or oligocellular induction pattern of ALDH3 was seen, consistently surrounding terminal hepatic veins after 3MC but mainly in the midzonal region after betaNF. A ligand-specific difference in regional induction of GSTYa1 mRNA was also observed: The constitutive perivenous dominance was preserved after 3MC while induction by betaNF was mainly periportal. A 3MC-betaNF difference was also seen by immunohistochemistry and at the GSTYa protein level, in contrast to that of the AHR-unassociated GSTYb protein. However, experiments with hepatocytes isolated from the periportal or perivenous region to replicate these inducer-specific induction responses in vitro were unsuccessful. These data demonstrate that the different acinar induction patterns by 3MC and betaNF previously observed for CYP1A1 and CYP1A2 are seen also for two other Ah battery genes, GSTYa1 and ALDH3, but in a modified, gene-specific form. We hypothesize that unknown protein(s) operating in vivo and modifying the Ah-mediated response at the common XRE element located upstream of these genes is affected zonespecifically by 3MC and betaNF.

Comparison of phenobarbital- and carcinogen-induced aldehyde dehydrogenases in the rat.

Abstract There is a genetically determined variation in the inducibility of a high- K m cytoplasmic aldehyde dehydrogenase activity in the rat liver by treatment with phenobarbital. In the present experiments this activity increased after phenobarbital administration in the phenobarbital-responsive rats also in the intestinal postmitochondrial supernatant fraction. Phenobarbital-nonresponsive rats did not exhibit such an increase after drug treatment. Intraperitoneal administration of 2,3,7,8,-tetrachlorodibenzo- p dioxin, strongly enchanced the cytoplasmic enzyme activity in the liver of both responsive and nonresponsive rats. This effect was also seen in the serum but not in the intestinal or hte kidney. Intragastric administration of 3-methylcholanthrene, 3,4,-benzpyrene or chrysene induced the activity in liver and intestine but not in serum or kidney. The activity in liver was also induced by long-term feeding with 2-acetamido-fluorene. The activities induced by tetrachlorodibenzodioxin or the carcinogens had similar behaviour in isoelectric focusing in gel slabs and in gel chromatography, suggesting a possible common identity of these induced enzymes. The activity induced by these agents could be clearly differentiated both from the activity induced by phenobarbital and from the normal cytoplasmic activities.