Reiko Takenoshita scite author profile

Reiko Takenoshita

5Publications

43Citation Statements Received

16Citation Statements Given

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Affiliations

Fukuoka University, Queen's University

Publications

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Cloning, Sequencing, and Enzymatic Activity of an Inducible Aldo-Keto Reductase from Chinese Hamster Ovary Cells

Hyndman¹,

Takenoshita²,

Vera³

et al. 1997

Journal of Biological Chemistry

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Treatment of Chinese hamster ovary (CHO) cells by the aldehyde containing calpain inhibitor I resulted in the induction of a 35-kDa protein that was partially sequenced and shown to be a member of the aldo-keto reductase superfamily (Inoue, S., Sharma, R. C., Schimke, R. T., and Simoni, R. D. (1993) J. Biol. Chem. 268, 5894 -5898). Using rapid amplification of cDNA ends polymerase chain reaction, we have sequenced the cDNA for this protein (CHO reductase). This enzyme is a new member of the aldo-keto reductase superfamily and shows greatest amino acid sequence identity to mouse fibroblast growth factor-regulated protein and mouse vas deferens protein (92 and 80% sequence identity, respectively). The enzyme exhibits about 70% sequence identity with the aldose reductases (ALR2; EC 1.1.1.21) and about 47% with the aldehyde reductases (ALR1; EC 1.1.1.2). Northern analysis showed that it is induced in preference to either ALR1 or ALR2 and RNase protection assays showed gene expression in bladder, testis, jejunum, and ovary in descending order of expression. The cDNA for this inducible reductase was cloned into the pET16b vector and expressed in BL21(DE3) cells. Expressed CHO reductase showed kinetic properties distinct from either ALR1 or ALR2 including the ability to metabolize ketones. This protein joins a growing number of inducible aldo-keto reductases that may play a role in cellular regulation and protection.To characterize the calpain inhibitor I-sensitive protease(s) involved in the degradation of 3-hydroxy-3-methylglutaryl-CoA reductase, Simoni's group (1) attempted to isolate Chinese hamster ovary (CHO) 1 cells resistant to this peptide aldehyde (N-acetyl-leucyl-leucyl-norleucinal (ALLN)). Instead of inducing a protease, a 35-kDa protein was overexpressed which gave tryptic peptide fragments with a high degree of sequence identity to members of the aldo-keto reductase superfamily. 2 This superfamily is a rapidly growing group of monomeric oxidoreductases containing at least 40 members at present (2). This group includes the aldehyde and aldose reductases, a number of hydroxysteroid dehydrogenases, Shaker channels, and plant chalcone reductases. They are characterized by a TIM-barrel structure (3) and the preferential use of NADPH over NADH. Substrates include aliphatic and aromatic aldehydes, monosaccharides, steroids, prostaglandins, polycyclic aromatic hydrocarbons, and isoflavinoid phytoalexins.Several members of this family have been shown to be induced in response to hormonal or chemical factors. These include fibroblast growth factor-regulated protein (FR-1) (4), mouse vas deferens protein (MVDP) (5), aldose reductase (ALR2) (6 -8), and dihydrodiol dehydrogenase (9). To determine the relationship of this new reductase to the other members of the family we have used RACE PCR to isolate and sequence its mRNA from CHO cells. It shows highest sequence identity to FR-1 and MVDP at 92 and 80%, respectively. FR-1 and MVDP have not been extensively characterized kinetically but CHO reductase showed a greater ...

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New Aspects of Hexobarbital Metabolism: Stereoselective Metabolism, New Metabolic Pathway via GSH Conjugation, and 3‐Hydroxyhexobarbital Dehydrogenases

Takenoshita

Toki

2005

ChemInform

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New Aspects of Hexobarbital Metabolism: Stereoselective Metabolism, New Metabolic Pathway via GSH Conjugation, and 3-Hydroxyhexobarbital Dehydrogenases

Takenoshita

Toki

2004

YAKUGAKU ZASSHI

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Hexobarbital, a short-acting hypnotic, is metabolized to 3'-hydroxyhexobarbital by cytochrome P450, and then to 3'-oxohexobarbital by liver cytosolic dehydrogenase. New methods of separation for hexobarbital and its metabolites by TLC have been developed and applied to study the metabolism of hexobarbital enantiomers and stereoselective metabolism of hexobarbital. (+)-Hexobarbital preferentially was transformed into beta-3'-hydroxyhexobarbital and the (-)-enantiomer preferentially transformed into alpha-3'-hydroxyhexobarbital by rat liver microsomes. Glucuronidation and dehydrogenation of 3'-hydroxyhexobarbital were also stereoselective and the S-configuration at the 3'-position was preferred. Alpha-3'-hydroxyhexobarbital from (-)-hexobarbital and the beta-isomer from (+)-hexobarbital were shown to be preferentially conjugated with glucuronic acid in rabbit urine, and to be preferentially dehydrogenated to form 3'-oxohexobarbital by rabbit and guinea pig 3-hydroxyhexobarbital dehydrogenases. A new metabolic pathway of hexobarbital was found in which 3'-oxohexobarbital reacts with glutathione to form 1,5-dimethylbarbituric acid and a cyclohexenone-glutathione adduct, a novel metabolite. 1,5-dimethylbarbituric acid was excreted into the urine and the cyclohexenone-glutathione adduct into the bile of rats dosed with hexobarbital. 3-hydroxyhexobarbital dehydrogenases that dehydrogenate 3-hydroxyhexobarbital into 3'-oxohexobarbital were purified from the liver cytosol of rabbits, guinea pigs, goats, rats, mice, hamsters, and humans and characterized. These enzymes were monomeric proteins and had molecular weights of about 34500-42000, and used NAD(+) and NADP(+) as cofactors, except for the human enzyme that had a molecular weight of about 58000 and used NAD(+) alone. Each enzyme exhibited its own characteristics. Substrate specificity demonstrated that 3-hydroxyhexobarbital dehydrogenases dehydrogenate not only alpha,beta-unsaturated cyclic and acyclic secondary alcohols but also some 17 beta-, 3 alpha-hydroxysteroids or both, except for the human enzyme. The amino acid sequence of the hamster enzyme indicated that it belongs to the aldo-keto reductase superfamily and hydroxysteroid dehydrogenase subfamily.

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Dehydrogenation of Indanol by Rabbit Liver 3-Hydroxyhexobarbital Dehydrogenase

Takenoshita

Toki

1977

Xenobiotica

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1. Among the several enzyme activities in rabbit liver cytosol able to dehydrogenate 1-indanol, only the main activity was not separable from 3-hydroxyhexobarbital dehydrogenase during purification including polyacrylamide gel disc electrophoresis. 2. Results of mixed substrate method indicated that the same enzyme catalyses the dehydrogenation of 1-indanol and 3-hydroxyhexobarbital. The ratio between the two dehydrogenation activities was almost constant as the enzyme underwent thermal inactivation. The Ki values of p-chloromercuribenzoate, the Km values for NAD+, and the Km values for NADP+ were very similar for the two dehydrogenations. These results lead to the conclusion that the same enzyme catalyses the dehydrogenation of 3-hydroxyhexobarbital and 1-indanol. 3. 1-Tetralol, 1-acenaphthenol, 9-fluorenol, thiochroman-4-ol and 4-chromanol also served as substrate of the enzyme, but 2-indanol, 2-tetralol, and trans- and cis-indan-1,2-diol were not oxidized. 4. Reversibility of the reaction was also confirmed using 1-indanone as substrate.

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Hexobarbital metabolism: a new metabolic pathway to produce 1,5-dimethylbarbituric acid and cyclohexenone-glutathione adduct via 3′-oxohexobarbital

1993

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1. In the presence of glutathione under physiological conditions, 3'-oxohexobarbital was non-enzymically converted to 1,5-dimethylbarbituric acid and a cyclohexenone-glutathione adduct. 2. The two reaction products were characterized by mass spectrometry, 1H- and 13C-n.m.r. spectrometry, and UV spectral analyses. 3. 1,5-Dimethylbarbituric acid was excreted in urine of rat given hexobarbital, 3'-oxohexobarbital, or 1',2'-epoxyhexobarbital, and accounted for 13.4, 14.5 and 4.7% of dose, respectively. 4. The cyclohexenone-glutathione adduct, a novel metabolite of hexobarbital, was excreted in the bile of rat given hexobarbital. 5. The route of 1,5-dimethylbarbituric acid formation via 3'-oxohexobarbital in the metabolism of hexobarbital was discussed in comparison with the epoxide-diol pathway.

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