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6. Isolation of Wound-Specific cDNA Clones from a cDNA Library Prepared with mRNAs of Alkali-Burned Rabbit Corneas

Author

Haseba T, Kao Ww, Kao Cw, Mitsuru Nakazawa, and Murthy R

Subjects
Molecular Sequence Data, EcoRI, Alkalies, Nucleic acid thermodynamics, Complementary DNA, Burns, Chemical, Animals, RNA, Messenger, Northern blot, Cloning, Molecular, Wound Healing, Expressed sequence tag, Messenger RNA, Base Sequence, biology, cDNA library, Hybridization probe, Nucleic Acid Hybridization, DNA, Blotting, Northern, Molecular biology, Eye Burns, Ophthalmology, biology.protein, Rabbits, DNA Probes, Corneal Injuries
Abstract

Alkali burn is one of the most severe corneal injuries. In order to gain a better understanding of the healing of alkali-burned corneas, it is necessary to identify and characterize proteins that are specifically synthesized by the injured corneal tissues. In this study, we developed a useful procedure to identify and isolate cDNA clones that encode messenger ribonucleic acids (mRNAs) that are specific and/or abundant in alkali-burned rabbit corneas (ARCs), but absent in normal rabbit corneas (NRCs). At first, a cDNA library was prepared by cloning cDNA of mRNA isolated from ARCs into the lambda ORF-8 vector. A differential plaque hybridization was used to screen 2.5 x 10(4) plaque-forming units (pfu) from an ARC cDNA library using 32P-labeled cDNAs prepared from mRNA of ARCs and NRCs. Thirty-seven cDNA clones of mRNAs specific for ARCs were identified and isolated in their pureform. The cDNA inserts of these lambda ORF-8 phages were subcloned into the pSM216 vector by in vivo recombination. The cDNA inserts then were characterized by restriction enzyme digestion, i.e., BamHI, HindIII, and EcoRI. The size of the cDNA inserts ranged from 210 to 5,000 base pairs. Using Northern blot hybridization of total RNA prepared from polymorphonuclear neutrophils, mononuclear leukocytes, alkali-burned corneas, and normal corneas, the cDNA clones were divided into three groups. Five cDNA clones encoded mRNA of corneal cells in ARCs. Twenty-four cDNA clones derived from mRNA of inflammatory cells were present in alkali-burned corneas, but Northern blot hybridization failed to identify mRNA of discrete sizes.(ABSTRACT TRUNCATED AT 250 WORDS)

Published
1991

7. INTERNAL MEDICINE * P34 * THIAMINE DOSE FOR SUSPECTED WERNICKE ENCEPHALOPATHY?

Author

McDonough, M., primary, Pronko, P. S., additional, Khomich, T. I., additional, Satanovskaya, V. I., additional, Shlyahtun, A. H., additional, Lis, R. Y., additional, Gaishmanova, A. V., additional, Kondyba, N. I., additional, Lukivskaya, O. J., additional, Poplavskaya, E. A., additional, Quin, H., additional, Chavez, P. R. G., additional, Millonig, G., additional, Lian, F., additional, Mernitz, H., additional, Liu, C., additional, Mueller, S., additional, Wang, X. D., additional, Seitz, H. K., additional, Buko, V., additional, Stickel, F., additional, Longerich, T., additional, Schirmacher, P., additional, Voronov, P. P., additional, Buko, V. U., additional, Samoilyk, A. A., additional, Lukivskaya, O. Y., additional, Belanovskaya, E. B., additional, Naruto, E. E., additional, Kirko, S. N., additional, Kaloshyna, N. V., additional, Attilia, M. L., additional, Rotondo, C., additional, Pizzelli, P., additional, Attilia, F., additional, Codazzo, C., additional, Tavoletti, R., additional, Romeo, M., additional, Ceccanti, M., additional, O'Brien, E. S., additional, Foglia, A., additional, Alaux-Cantin, S., additional, Naassila, M., additional, Vilpoux, C., additional, Oshima, S., additional, Masuda, C., additional, Kakimi, E., additional, Sami, M., additional, Kanda, T., additional, Haseba, T., additional, Ohno, Y., additional, Nummi, K. P., additional, Salaspuro, M., additional, Vakevainen, S., additional, Gyamfi, D., additional, Clemens, D., additional, Patel, V. B., additional, Shlyakhtun, A. G., additional, and Liakh, I. V., additional

Published
2011
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21. Class III Alcohol Dehydrogenase Plays a Key Role in the Onset of Alcohol-Related/-Associated Liver Disease as an S-Nitrosoglutathione Reductase in Mice.

Author

Haseba T, Maruyama M, Akimoto T, Yamamoto I, Katsuyama M, and Okuda T

Subjects
Animals, Mice, Alcohol Dehydrogenase genetics, Alcohol Dehydrogenase metabolism, Ethanol metabolism, Lipids, Liver metabolism, PPAR gamma metabolism, Liver Diseases, Alcoholic genetics, Liver Diseases, Alcoholic metabolism, Oxidoreductases metabolism
Abstract

Lipid accumulation in the liver due to chronic alcohol consumption (CAC) is crucial in the development of alcohol liver disease (ALD). It is promoted by the NADH/NAD ratio increase via alcohol dehydrogenase (ADH)-dependent alcohol metabolism and lipogenesis increase via peroxisome proliferator-activated receptor γ (PPARγ) in the liver. The transcriptional activity of PPARγ on lipogenic genes is inhibited by S-nitrosylation but activated by denitrosylation via S-nitrosoglutathione reductase (GSNOR), an enzyme identical to ADH3. Besides ADH1, ADH3 also participates in alcohol metabolism. Therefore, we investigated the specific contribution of ADH3 to ALD onset. ADH3-knockout ( Adh3-/- ) and wild-type (WT) mice were administered a 10% ethanol solution for 12 months. Adh3-/- exhibited no significant pathological changes in the liver, whereas WT exhibited marked hepatic lipid accumulation ( p < 0.005) with increased serum transaminase levels. Adh3-/- exhibited no death during CAC, whereas WT exhibited a 40% death. Liver ADH3 mRNA levels were elevated by CAC in WT ( p < 0.01). The alcohol elimination rate measured after injecting 4 g/kg ethanol was not significantly different between two strains, although the rate was increased in both strains by CAC. Thus, ADH3 plays a key role in the ALD onset, likely by acting as GSNOR.

Published
2023
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22. Roles of Two Major Alcohol Dehydrogenases, ADH1 (Class I) and ADH3 (Class III), in the Adaptive Enhancement of Alcohol Metabolism Induced by Chronic Alcohol Consumption in Mice.

Author

Haseba T, Okuda T, Maruyama M, Akimoto T, Duester G, and Ohno Y

Subjects
Alcohol Dehydrogenase genetics, Alcohol Drinking metabolism, Animals, Ethanol metabolism, Fomepizole pharmacology, Genotype, Male, Mice, Mice, Inbred Strains, Renal Elimination drug effects, Alcohol Dehydrogenase physiology, Renal Elimination physiology
Abstract

Aims: It is still unclear which enzymes contribute to the adaptive enhancement of alcohol metabolism by chronic alcohol consumption (CAC). ADH1 (Class I) has the lowest Km for ethanol and the highest sensitivity for 4-methylpyrazole (4MP) among ADH isozymes, while ADH3 (Class III) has the highest Km and the lowest sensitivity. We investigated how these two major ADHs relate to the adaptive enhancement of alcohol metabolism., Methods: Male mice with different ADH genotypes (WT, Adh1-/- and Adh3-/-) were subjected to CAC experiment using a 10% ethanol solution for 1 month. Alcohol elimination rate (AER) was measured after ethanol injection at a 4.0 g/kg dose. 4MP-sensitive and -insensitive AERs were measured by the simultaneous administration of 4MP at a dose of 0.5 mmol/kg in order to estimate ADH1 and non-ADH1 pathways., Results: AER was enhanced by CAC in all ADH genotypes, especially more than twofold in Adh1-/- mice, with increasing ADH1 and/or ADH3 liver contents, but not CYP2E1 content. 4MP-sensitive AER was also increased by CAC in WT and Adh3-/- strains, which was greater in Adh3-/- than in WT mice. The sensitive AER was increased even in Adh1-/- mice probably due to the increase in ADH3, which is semi-sensitive for 4MP. 4MP-insensitive AER was also increased in WT and Adh1-/- by CAC, but not in Adh3-/- mice., Conclusion: ADH1 contributes to the enhancement of alcohol metabolism by CAC, particularly in the absence of ADH3. ADH3 also contributes to the enhancement as a non-ADH1 pathway, especially in the absence of ADH1., (© The Author(s) 2019. Medical Council on Alcohol and Oxford University Press. All rights reserved.)

Published
2020
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23. Metabolic pharmacokinetics of early chronic alcohol consumption mediated by liver alcohol dehydrogenases 1 and 3 in mice.

Author

Okuda T, Haseba T, Katsuyama M, Maruyama M, Akimoto T, Igarashi T, and Ohno Y

Subjects
Alcohol Dehydrogenase genetics, Animals, Ethanol blood, Genotype, Male, Mice, Inbred C57BL, Mice, Knockout, Time Factors, Alcohol Dehydrogenase metabolism, Alcohol Drinking genetics, Alcohol Drinking metabolism, Ethanol metabolism, Liver enzymology
Abstract

Background and Aim: Alcohol dehydrogenases (ADHs) 1 and 3 are responsible for systemic alcohol metabolism. The current study investigated the contribution of liver ADH1 and ADH3 to the metabolic pharmacokinetics of chronic alcohol consumption (CAC)., Methods: The 9-week-old male mice of different ADH genotypes (wild-type [WT], Adh1 -/- , and Adh3 -/- ) were administered with 10% ethanol solution for 1 month, followed by acute ethanol administration (4.0 g/kg). The alcohol elimination rate (AER), area under the blood alcohol concentration curve (AUC), and the maximum blood alcohol concentration (C max ) were calculated. The liver content, activity, and mRNA levels of ADH were evaluated., Results: Chronic alcohol consumption increased the AER and reduced the AUC in all ADH genotypes. The increased ADH1 content was correlated with AER in WT mice but not in the Adh3 -/- mice. Similarly, the increased ADH3 content was also correlated with AER in both WT and Adh1 -/- mice. The C max was significantly higher in Adh3 -/- control mice than in WT control mice. It decreased in the Adh1 -/- mice by CAC along with an increase in the ADH3 content., Conclusions: Alcohol dehydrogenases 1 and 3 would accomplish the pharmacokinetic adaptation to CAC in the early period. ADH1 contributes to the metabolic pharmacokinetics of CAC with a decrease in AUC in conjunction with an increase of AER by increasing the enzyme content in the presence of ADH3. ADH3 also contributes to a decrease in AUC in conjunction with not only an increase in AER but also a decrease in C max by increasing the enzyme content., (© 2018 Journal of Gastroenterology and Hepatology Foundation and John Wiley & Sons Australia, Ltd.)

Published
2018
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24. The Contribution of Alcohol Dehydrogenase 3 to the Development of Alcoholic Osteoporosis in Mice.

Author

Okuda T, Naruo M, Iijima O, Igarashi T, Katsuyama M, Maruyama M, Akimoto T, Ohno Y, and Haseba T

Subjects
Alcohol Dehydrogenase metabolism, Animals, Central Nervous System Depressants administration & dosage, Central Nervous System Depressants metabolism, Central Nervous System Depressants toxicity, Ethanol administration & dosage, Ethanol metabolism, Femur diagnostic imaging, Femur pathology, Gene Expression Regulation, Enzymologic drug effects, Genotype, Male, Mice, Inbred C57BL, Mice, Knockout, Osteoblasts metabolism, Osteoclasts metabolism, Osteoporosis chemically induced, Osteoporosis enzymology, Tomography, X-Ray Computed, Alcohol Dehydrogenase genetics, Ethanol toxicity, Femur drug effects, Osteoporosis genetics
Abstract

Background: Alcohol dehydrogenase 3 (ADH3) plays major roles not only in alcohol metabolism but also in nitric oxide metabolism as S-nitrosoglutathione reductase (GSNOR). ADH3/GSNOR regulates both adipogenesis and osteogenesis through the denitrosylation of peroxisome proliferator-activated receptor γ. The current study investigated the contribution of ADH3 to the development of alcoholic osteoporosis in chronic alcohol consumption (CAC)., Methods: Nine-week-old male mice of different ADH genotypes [wild-type (WT) and Adh3 -/- ] were administered a 10% ethanol solution for 12 months. The femurs were evaluated by histochemical staining and computed tomography-based bone densitometry. The mRNA levels of ADH3 were evaluated in the WT mice by reverse transcription-quantitative polymerase chain reaction., Results: The Adh3 -/- control mice exhibited increased activities of both osteoblasts and osteoclasts and lower bone masses than the WT control mice. CAC exhibited no remarkable change in osteoblastic and osteoclastic activities, but decreased bone masses were observed in WT mice despite an increase in the mRNA levels of ADH3. Conversely, bone masses in the Adh3 -/- control mice were not reduced after CAC., Conclusions: The Adh3 -/- control mice exhibited a high turnover of osteoporosis since osteoclastogenesis dominated osteoblastogenesis; however, bone resorption was not enhanced after CAC. In comparison, CAC lead to alcoholic osteoporosis in WT mice, accompanied by increased mRNA levels of ADH3. Hence, ADH3 can prevent osteoporosis development in normal ADH genotypes with no alcohol ingestion. However, ADH3 contributes to the development of alcoholic osteoporosis under CAC by participating in alcohol metabolism, increasing metabolic toxicity, and lowering GSNO reducing activity.

Published
2018
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25. Real-time PCR assay for the detection of picoplankton DNA distribution in the tissues of drowned rabbits.

Author

Uchigasaki S, Tie J, Haseba T, Cui F, Ohno Y, Isobe E, Isahai I, and Tsutsumi H

Subjects
Animals, Cyanobacteria chemistry, Polymerase Chain Reaction, Rabbits, DNA, Ribosomal analysis, Drowning diagnosis, Plankton chemistry
Abstract

The detection of plankton DNA is one of the important methods for the diagnosis of drowning from postmortem tissues. This study investigated the quantities of picoplankton (Cyanobacteria) DNA in the lung, liver, kidney tissues and blood of drowned and non-drowned rabbits, and the sensitivity of detection of picoplankton DNA by polymerase chain reaction (PCR) detect for the diagnosis of death from drowning. For this purpose, the DNA of the 16S ribosomal RNA gene of picoplankton was quantitatively assayed from the tissues of drowned and non-drowned rabbits immersed in water after death. Each of the liver, kidney and lung tissues and blood were obtained from drowned and non-drowned rabbits. Picoplankton DNA in the tissues was extracted using the DNeasy® Blood & Tissue kit to determine the yield of picoplankton DNA from each tissue. TaqMan real-time PCR was performed for quantitative analysis of picoplankton DNA. Target DNA was detected in the liver, kidney and lung samples obtained from the drowned rabbits, while no picoplankton DNA was detected in the non-drowned rabbit tissues (except in lung samples). The results verified that direct PCR for the detection of picoplankton DNA is useful for the diagnosis of drowning. Although we observed seasonal changes in the quantity of picoplankton in river water, we were able to detect DNA from various organs of drowned bodies during the season when picoplankton were not the most abundant., (Copyright © 2016 Elsevier Ireland Ltd. All rights reserved.)

Published
2016
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26. Alcohol dehydrogenase 3 contributes to the protection of liver from nonalcoholic steatohepatitis.

Author

Goto M, Kitamura H, Alam MM, Ota N, Haseba T, Akimoto T, Shimizu A, Takano-Yamamoto T, Yamamoto M, and Motohashi H

Subjects
Animals, Choline Deficiency, Diet, Disease Progression, Fatty Liver metabolism, Glutathione metabolism, Lipid Metabolism, Liver pathology, Methionine deficiency, Mice, Inbred C57BL, Mice, Knockout, NF-E2-Related Factor 2 metabolism, Alcohol Dehydrogenase genetics, Alcohol Dehydrogenase metabolism, Liver metabolism, Non-alcoholic Fatty Liver Disease prevention & control
Abstract

Nutritional steatohepatitis is closely associated with dysregulation of lipid metabolism and oxidative stress control. ADH3 is a highly conserved bifunctional enzyme involved in formaldehyde detoxification and termination of nitric oxide signaling. Formaldehyde and nitric oxide are nonenzymatically conjugated with glutathione, which is regenerated after ADH3 metabolizes the conjugates. To clarify roles of ADH3 in nutritional liver diseases, we placed Adh3-null mice on a methionine- and choline-deficient (MCD) diet. The Adh3-null mice developed steatohepatitis more rapidly than wild-type mice, indicating that ADH3 protects liver from nutritional steatohepatitis. NRF2, which is a key regulator of cytoprotective genes against oxidative stress, was activated in the Adh3-null mice with liver damage. In the absence of NRF2, the Adh3 disruption caused severe steatohepatitis by the MCD diet feeding accompanied by significant decrease in glutathione, suggesting cooperative function between ADH3 and NRF2 in the maintenance of cellular glutathione level for cytoprotection. Conversely, with enhanced NRF2 activity, the Adh3 disruption did not cause steatohepatitis but induced steatosis, suggesting that perturbation of lipid metabolism in ADH3-deficiency is not compensated by NRF2. Thus, ADH3 protects liver from steatosis by supporting normal lipid metabolism and prevents progression of steatosis into steatohepatitis by maintaining the cellular glutathione level., (© 2015 The Molecular Biology Society of Japan and Wiley Publishing Asia Pty Ltd.)

Published
2015
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27. Alcohol dehydrogenase III exacerbates liver fibrosis by enhancing stellate cell activation and suppressing natural killer cells in mice.

Author

Yi HS, Lee YS, Byun JS, Seo W, Jeong JM, Park O, Duester G, Haseba T, Kim SC, Park KG, Gao B, and Jeong WI

Subjects
Animals, Bone Marrow Transplantation, Interferon-gamma metabolism, Liver Cirrhosis immunology, Male, Mice, Mice, Inbred C57BL, Aldehyde Oxidoreductases metabolism, Hepatic Stellate Cells physiology, Killer Cells, Natural physiology, Liver Cirrhosis enzymology
Abstract

Unlabelled: The important roles of retinols and their metabolites have recently been emphasized in the interactions between hepatic stellate cells (HSCs) and natural killer (NK) cells. Nevertheless, the expression and role of retinol metabolizing enzyme in both cell types have yet to be clarified. Thus, we investigated the expression of retinol metabolizing enzyme and its role in liver fibrosis. Among several retinol metabolizing enzymes, only alcohol dehydrogenase (ADH) 3 expression was detected in isolated HSCs and NK cells, whereas hepatocytes express all of them. In vitro treatment with 4-methylpyrazole (4-MP), a broad ADH inhibitor, or depletion of the ADH3 gene down-regulated collagen and transforming growth factor-β1 (TGF-β1) gene expression, but did not affect α-smooth muscle actin gene expression in cultured HSCs. Additionally, in vitro, treatments with retinol suppressed NK cell activities, whereas inhibition of ADH3 enhanced interferon-γ (IFN-γ) production and cytotoxicity of NK cells against HSCs. In vivo, genetic depletion of the ADH3 gene ameliorated bile duct ligation- and carbon tetrachloride-induced liver fibrosis, in which a higher number of apoptotic HSCs and an enhanced activation of NK cells were detected. Freshly isolated HSCs from ADH3-deficient mice showed reduced expression of collagen and TGF-β1, but enhanced expression of IFN-γ was detected in NK cells from these mice compared with those of control mice. Using reciprocal bone marrow transplantation of wild-type and ADH3-deficient mice, we demonstrated that ADH3 deficiency in both HSCs and NK cells contributed to the suppressed liver fibrosis., Conclusion: ADH3 plays important roles in promoting liver fibrosis by enhancing HSC activation and inhibiting NK cell activity, and could be used as a potential therapeutic target for the treatment of liver fibrosis., (© 2014 by the American Association for the Study of Liver Diseases.)

Published
2014
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28. [Molecular evidences of non-ADH pathway in alcohol metabolism and Class III alcohol dehydrogenase (ADH3)].

Author

Haseba T

Subjects
Alcohol Dehydrogenase metabolism, Alcohol Dehydrogenase pharmacology, Alcohol Drinking metabolism, Alcohol Oxidoreductases physiology, Alcoholism etiology, Animals, Catalase physiology, Cytochrome P-450 Enzyme System physiology, Dose-Response Relationship, Drug, Humans, Alcohol Dehydrogenase classification, Alcohol Dehydrogenase physiology, Ethanol metabolism, Liver Diseases, Alcoholic enzymology, Liver Diseases, Alcoholic metabolism
Abstract

Class I alcohol dehydrogenase (ADH1), a key enzyme of alcohol metabolism, contributes around 70% to the systemic alcohol metabolism and also to the acceleration of the metabolism due to chronic alcohol consumption by increasing its liver content, if the liver damage or disease is not apparent. However, the contribution of ADH1 to alcohol metabolism decreases in case of acute alcohol poisoning or chronic alcohol consumption inducing liver damage or disease. On the contrary, non-ADH pathway, which is independent of ADH1, increases the contribution to alcohol metabolism in these cases, by complementing the reduced role of ADH1. The molecular substantiality of non-ADH pathway has been still unknown in spite of the long and hot controversy between two candidates of microsomal ethanol oxidizing system (MEOS) and catalase. This research history suggests the existence of other candidates. Among ADH isozymes, Class III (ADH3) has the highest Km for ethanol and the highest resistance to pyrazole reagents of specific ADH inhibitors. This ADH3 was demonstrated to increase the contribution to alcohol metabolism in vivo dose-dependently, therefore, is a potent candidate of non-ADH pathway. Moreover, ADH3 is considered to increase the contribution to alcohol metabolism in case of alcoholic liver diseases, because the enzyme content increases in damaged tissues with increased hydrophobicity or the activity of the liver correlates with the accumulated alcohol consumptions of patients with alcoholic liver diseases. Such adaptation of ADH3 to alcohol metabolism in these pathological conditions makes patients possible to keep drinking a lot in spite of decrease of ADH1 activity and develops alcoholism seriously.

Published
2014

29. [Dose effect of alcohol on sex differences in blood alcohol metabolism--cases where healthy subjects with ALDH2*1/1 genotype drunk beer with meal].

Author

Oshima S, Haseba T, Masuda C, Kakimi E, Kitagawa Y, and Ohno Y

Subjects
Adult, Aldehyde Dehydrogenase, Mitochondrial, Beer, Ethanol adverse effects, Female, Genotype, Humans, Male, Polymorphism, Genetic, Sex Characteristics, Young Adult, Alcohol Drinking blood, Aldehyde Dehydrogenase genetics, Ethanol metabolism, Meals
Abstract

It is said that blood alcohol concentrations (BAG) are higher in female than in male due to the smaller distribution volume of alcohol in female, whereas the rate of alcohol metabolism is faster in female than in males due to a higher activity of liver alcohol dehydrogenase (ADH) in female. However, it is also known that alcohol metabolism varies depending on drinking conditions. In this study, we evaluated the dose effect of alcohol on sex differences in alcohol metabolism in daily drinking conditions, where young adults (16 males, 15 females) with ALDH2*1/1 genotype drunk beer at a dose of 0.32g or 1.0g ethanol/kg body weight with a test meal (460kcal). This study was conducted using a randomized cross-over design. In the considerable drinking condition (1.0g/kg), BAG was significantly higher in females than in males, whereas the rate of alcohol metabolism (beta) was higher in female than in male. In the moderate drinking condition (0.32g/kg), however, no sex differences in alcohol metabolism including BAG were seen. These results suggest that an increased first pass metabolism through liver ADH in female, which may be caused by the reduction of gastric emptying rate due to the meal intake, contribute to the vanishing of sex difference in BAC in the moderate drinking condition.

Published
2013

30. Dose-Dependent Change in Elimination Kinetics of Ethanol due to Shift of Dominant Metabolizing Enzyme from ADH 1 (Class I) to ADH 3 (Class III) in Mouse.

Author

Haseba T, Kameyama K, Mashimo K, and Ohno Y

Abstract

ADH 1 and ADH 3 are major two ADH isozymes in the liver, which participate in systemic alcohol metabolism, mainly distributing in parenchymal and in sinusoidal endothelial cells of the liver, respectively. We investigated how these two ADHs contribute to the elimination kinetics of blood ethanol by administering ethanol to mice at various doses, and by measuring liver ADH activity and liver contents of both ADHs. The normalized AUC (AUC/dose) showed a concave increase with an increase in ethanol dose, inversely correlating with β. CL(T) (dose/AUC) linearly correlated with liver ADH activity and also with both the ADH-1 and -3 contents (mg/kg B.W.). When ADH-1 activity was calculated by multiplying ADH-1 content by its V(max⁡)/mg (4.0) and normalized by the ratio of liver ADH activity of each ethanol dose to that of the control, the theoretical ADH-1 activity decreased dose-dependently, correlating with β. On the other hand, the theoretical ADH-3 activity, which was calculated by subtracting ADH-1 activity from liver ADH activity and normalized, increased dose-dependently, correlating with the normalized AUC. These results suggested that the elimination kinetics of blood ethanol in mice was dose-dependently changed, accompanied by a shift of the dominant metabolizing enzyme from ADH 1 to ADH 3.

Published
2012
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31. [Alcohol metabolism at moderate drinking in healthy men. Comparison between differences of alcohol beverages, with and without meal, and genetic polymorphism].

Author

Oshima S, Haseba T, Masuda C, Abe Y, Sami M, Kanda T, and Ohno Y

Subjects
Acetaldehyde blood, Adult, Aldehyde Dehydrogenase, Mitochondrial, Beer, Cross-Over Studies, Humans, Male, Middle Aged, Alcoholic Beverages, Aldehyde Dehydrogenase genetics, Eating physiology, Ethanol blood, Polymorphism, Genetic
Abstract

Studies on metabolisms of alcohol and the metabolites (e.g.:acetaldehyde) after drinking give basic and important information to recognize the physiological influence of drinking to human bodies. The aims of these studies were to clarify the influences of ALDH2 genotype difference, kinds of alcohol beverages, and fasted or prandial state to alcohol metabolisms at moderate drinking. The studies were conducted by a randomized cross-over design. After overnight fast, fifteen of ALDH2*1/*1 (Experiment 1) and twenty of ALDH21/*2 (Experiment 2) in Japanese healthy men aged 40 to 59 years old drank beer or shochu at a dose of 0.32g ethanol / kg body weight with or without test meal (460 kcal). The peak of blood ethanol (C(max)) was higher with shochu than with beer in the fasted condition in both ALDH2 genotypes, however, the difference between two types of alcohol beverages went out in the prandial condition. Simultaneous ingestion of test meal with alcohol beverage significantly decreased blood ethanol concentrations and increased ethanol disappearance rate (EDR) in the both genotypes. EDR values were significantly higher in ALDH2*1/*1 type than in ALDH2*1/*2 type in the both beverages with and without meal, whereas beta values showed no significant difference between two genotypes. The concentrations of blood acetaldehyde in ALDH2*1/*2 type were higher in prandial condition than in fasted condition with shochu. These results indicate that meal modified the differences of alcohol metabolism between beer and shochu and also between ALDH2 genotypes. Thus, alcohol metabolism in daily drinking is shown to be regulated by various combinatorial drinking conditions.

Published
2011

32. Direct and rapid PCR amplification using digested tissues for the diagnosis of drowning.

Author

Tie J, Uchigasaki S, Haseba T, Ohno Y, Isahai I, and Oshida S

Subjects
Base Sequence, DNA, Bacterial genetics, DNA, Bacterial isolation & purification, Euglena gracilis genetics, Euglena gracilis isolation & purification, Humans, Kidney microbiology, Liver microbiology, Lung microbiology, Phytoplankton genetics, Polymerase Chain Reaction economics, Time Factors, Cyanobacteria genetics, DNA Primers genetics, Drowning diagnosis, Phytoplankton isolation & purification, Polymerase Chain Reaction methods, RNA, Ribosomal, 16S genetics
Abstract

We developed a direct and rapid method for the diagnosis of death by drowning by PCR amplification of phytoplankton DNA using human tissues. The primers were designed based on the DNA sequence of the 16S ribosomal RNA gene (16S rDNA) of Cyanobacterium. Samples of lung, liver and kidney tissues were collected from 53 autopsied individuals diagnosed as death by drowning. Without DNA extraction, the tissue fragments were incubated directly in a digest buffer developed in this study, for 20 min. Using 1 microL of the tissue digest solution in PCR, the 16S rDNA was successfully amplified. The specific 16S rDNA fragment was identified from the standard picoplankton Euglena gracilis, the tissues of bodies died from drowning and water samples from the drowning scenes. On the other hand, no PCR products were found in the tissues of individuals who died from causes other than drowning. Various quantities of tissue weighing 1, 5, 10, 20 and 30 mg were tested, and the PCR amplification detected the specific 16S rDNA fragment from all the quantities of tissue tested. This method was found to be more reliable, sensitive, specific and rapid when compared to the conventional diagnosis of death by drowning using the diatom test by acid digestion method.

Published
2010
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33. A new view of alcohol metabolism and alcoholism--role of the high-Km Class III alcohol dehydrogenase (ADH3).

Author

Haseba T and Ohno Y

Subjects
Aldehyde Oxidoreductases genetics, Animals, Dose-Response Relationship, Drug, Enzyme Activation, Ethanol administration & dosage, Ethanol blood, Humans, Mice, Mice, Knockout, Rats, Alcoholism enzymology, Aldehyde Oxidoreductases metabolism, Ethanol metabolism
Abstract

The conventional view is that alcohol metabolism is carried out by ADH1 (Class I) in the liver. However, it has been suggested that another pathway plays an important role in alcohol metabolism, especially when the level of blood ethanol is high or when drinking is chronic. Over the past three decades, vigorous attempts to identify the enzyme responsible for the non-ADH1 pathway have focused on the microsomal ethanol oxidizing system (MEOS) and catalase, but have failed to clarify their roles in systemic alcohol metabolism. Recently, using ADH3-null mutant mice, we demonstrated that ADH3 (Class III), which has a high K(m) and is a ubiquitous enzyme of ancient origin, contributes to systemic alcohol metabolism in a dose-dependent manner, thereby diminishing acute alcohol intoxication. Although the activity of ADH3 toward ethanol is usually low in vitro due to its very high K(m), the catalytic efficiency (k(cat)/K(m)) is markedly enhanced when the solution hydrophobicity of the reaction medium increases. Activation of ADH3 by increasing hydrophobicity should also occur in liver cells; a cytoplasmic solution of mouse liver cells was shown to be much more hydrophobic than a buffer solution when using Nile red as a hydrophobicity probe. When various doses of ethanol are administered to mice, liver ADH3 activity is dynamically regulated through induction or kinetic activation, while ADH1 activity is markedly lower at high doses (3-5 g/kg). These data suggest that ADH3 plays a dynamic role in alcohol metabolism, either collaborating with ADH1 or compensating for the reduced role of ADH1. A complex two-ADH model that ascribes total liver ADH activity to both ADH1 and ADH3 explains the dose-dependent changes in the pharmacokinetic parameters (beta, CL(T), AUC) of blood ethanol very well, suggesting that alcohol metabolism in mice is primarily governed by these two ADHs. In patients with alcoholic liver disease, liver ADH3 activity increases, while ADH1 activity decreases, as alcohol intake increases. Furthermore, ADH3 is induced in damaged cells that have greater hydrophobicity, whereas ADH1 activity is lower when there is severe liver disease. These data suggest that chronic binge drinking and the resulting liver disease shifts the key enzyme in alcohol metabolism from low-K(m) ADH1 to high-K(m) ADH3, thereby reducing the rate of alcohol metabolism. The interdependent increase in the ADH3/ADH1 activity ratio and AUC may be a factor in the development of alcoholic liver disease. However, the adaptive increase in ADH3 sustains alcohol metabolism, even in patients with alcoholic liver cirrhosis, which makes it possible for them to drink themselves to death. Thus, the regulation of ADH3 activity may be important in preventing alcoholism development.

Published
2010
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34. [A new sight on alcohol metabolism and alcoholism--role of high Km alcohol dehydrogenase ADH3 (Class III)].

Author

Haseba T

Subjects
Animals, Humans, Liver Diseases, Alcoholic enzymology, Mice, Aldehyde Oxidoreductases physiology, Ethanol metabolism
Abstract

Alcohol metabolism is known to be mainly carried out by the classic ADH1 (Class I) of the liver. However, another pathway has been also suggested to play important roles in alcohol metabolism especially at high levels of blood ethanol and under chronic drinking. Over the past three decades, vigorous attempts to identify the enzyme responsible for the non-ADH1 pathway have focused on the microsomal oxidizing system (MEOS) and catalase, but have failed to clarify their roles in systemic alcohol metabolism. Recently, we used ADH3-null mutant mice to demonstrate that high Km ADH3 (Class III), a ubiquitous enzyme of ancient origin, contributes to systemic alcohol metabolism dose-dependently resulting in a diminution of acute alcohol intoxication. Although the ethanol activity of ADH3 in vitro is usually low due to its very high Km, the catalytic efficiency (k(cat)/Km) was markedly enhanced when the solution hydrophobicity of the reaction medium was increased. The hydrophobic activation of ADH3 is also expected in liver cells, because the cytoplasmic solution in mouse liver cell was shown to be much more hydrophobic than the buffer solution by using Nile red as a hydrophobic probe. By acute administrations of ethanol to mice at various doses, liver ADH3 activity was dynamically regulated through induction or kinetic activation, though ADH1 activity was markedly decreased at higher doses (3 - 5 g/kg). These data suggest that ADH3 plays a dynamical share in alcohol metabolism with ADH1, collaborating with it or supplementing the decreased role of ADH1. The two ADH-complex model, which ascribes total liver ADH activity to both ADH1 and ADH3, explained well the dose-dependent changes in pharmacokinetic parameters (beta, CL(T), AUC) of blood ethanol, suggesting that alcohol metabolism in mice is primarily governed by the two ADHs. In patients with alcoholic liver diseases, the liver ADH3 activity increased but the ADH1 activity decreased with an increase in alcohol intake. Furthermore, ADH3 was induced in damaged cells with increased hydrophobicity, whereas ADH1 decreased its activity in severe liver diseases. These data suggest that heavy and chronic drinking shifts the main enzyme in alcohol metabolism from low Km ADH1 to high Km ADH3 to develop alcoholic liver diseases by the nonlinear increase in AUC due to the decrease of the metabolic rate. However, the adaptively increased ADH3 keeps the ability of alcohol metabolism even in patients with alcoholic liver cirrhosis and make possible for them to keep drinking to death. Therefore, the regulation of ADH3 activity may be important to prevent the development of alcoholism.

Published
2009

35. Phytophenols in whisky lower blood acetaldehyde level by depressing alcohol metabolism through inhibition of alcohol dehydrogenase 1 (class I) in mice.

Author

Haseba T, Sugimoto J, Sato S, Abe Y, and Ohno Y

Subjects
Acetaldehyde metabolism, Alcohol Dehydrogenase metabolism, Animals, Benzaldehydes pharmacokinetics, Chemical Fractionation, Down-Regulation drug effects, Ellagic Acid pharmacokinetics, Liver drug effects, Liver enzymology, Liver metabolism, Male, Mice, Models, Biological, Phenols metabolism, Volatilization, Acetaldehyde blood, Alcohol Dehydrogenase antagonists & inhibitors, Alcoholic Beverages, Ethanol pharmacokinetics, Phenols pharmacology
Abstract

We recently reported that the maturation of whisky prolongs the exposure of the body to a given dose of alcohol by reducing the rate of alcohol metabolism and thus lowers the blood acetaldehyde level (Alcohol Clin Exp Res. 2007;31:77s-82s). In this study, administration of the nonvolatile fraction of whisky was found to lower the concentration of acetaldehyde in the blood of mice by depressing alcohol metabolism through the inhibition of liver alcohol dehydrogenase (ADH). Four of the 12 phenolic compounds detected in the nonvolatile fraction (caffeic acid, vanillin, syringaldehyde, ellagic acid), the amounts of which increase during the maturation of whisky, were found to strongly inhibit mouse ADH 1 (class I). Their inhibition constant values for ADH 1 were 0.08, 7.9, 15.6, and 22.0 mumol/L, respectively, whereas that for pyrazole, a well-known ADH inhibitor, was 5.1 mumol/L. The 2 phenolic aldehydes and ellagic acid exhibited a mixed type of inhibition, whereas caffeic acid showed the competitive type. When individually administered to mice together with ethanol, each of these phytophenols depressed the elimination of ethanol, thereby lowering the acetaldehyde concentration of blood. Thus, it was demonstrated that the enhanced inhibition of liver ADH 1 due to the increased amounts of these phytophenols in mature whisky caused the depression of alcohol metabolism and a consequent lowering of blood acetaldehyde level. These substances are commonly found in various food plants and act as antioxidants and/or anticarcinogens. Therefore, the intake of foods rich in them together with alcohol may not only diminish the metabolic toxicity of alcohol by reducing both the blood acetaldehyde level and oxidative stress, but also help limit the amount of alcohol a person drinks by depressing alcohol metabolism.

Published
2008
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36. Maturation of whisky changes ethanol elimination kinetics and neural effects by increasing nonvolatile congeners.

Author

Haseba T, Mashimo K, Sugimoto J, Sato S, and Ohno Y

Subjects
Acetaldehyde pharmacokinetics, Acetates pharmacokinetics, Alcohol Dehydrogenase blood, Animals, Injections, Intraperitoneal, Liver drug effects, Metabolic Clearance Rate, Mice, Mice, Inbred Strains, Postural Balance drug effects, Reaction Time drug effects, Reflex drug effects, Alcoholic Beverages toxicity, Alcoholic Intoxication blood, Ethanol pharmacokinetics
Abstract

Background: The maturation of distilled spirits is known to change constituent congeners to improve the qualities of smell and taste. However, it has been largely unknown how maturation modifies the pharmacokinetics or neuropharmacological effects of ethanol. We used single malt whiskies to investigate the effects of spirit maturation on ethanol metabolism and drunkenness., Methods: Mice were injected with 5-year (5-y) or 20-year (20-y) aged single malt whisky with a concentration of 20% (w/v) ethanol at a dose of 3 g/kg. The concentrations of ethanol and its metabolites in the blood and the duration of loss of righting reflex (LORR) were compared between the 2 whisky groups. In addition, the effects of nonvolatile congeners in whisky on the biomedical reactivities of ethanol were investigated by administering a nonvolatile fraction added to a 20% ethanol solution, whose fraction was prepared by evaporating 16-y whisky. Liver alcohol dehydrogenase (ADH) activity was measured with whisky as the substrate or in the presence of nonvolatile congeners with ethanol as the substrate., Results: The rate of ethanol elimination (mmol/kg/h) was smaller in the 20-y whisky group than in the 5-y group (p<0.01 by Fisher's protected least significant difference), which resulted in lower concentrations of blood acetaldehyde and acetate in the former group than in the latter group (p<0.01 by ANOVA). Nonvolatile congeners added to the ethanol solution also depressed the rate of ethanol elimination in mice. In vitro studies demonstrated that liver ADH activity measured with whisky as the substrate was decreased as a function of the age of the whisky, and that the activity measured with ethanol as the substrate was strongly inhibited by nonvolatile congeners. The duration of LORR was longer in the 20-y group than in the 5-y group (p<0.01). Nonvolatile congeners also prolonged the duration of ethanol-induced LORR, when administered together with ethanol., Conclusion: Maturation of whisky delayed ethanol metabolism to lower the level of blood acetaldehyde and acetate with increasing inhibition of liver ADH activity by nonvolatile congeners. It also prolonged drunkenness by enhancing the neurodepressive effects of ethanol, due to increases in the amount of nonvolatile congeners. These biomedical effects of whisky maturation may reduce aversive reactions and cytotoxicity due to acetaldehyde, and may also limit overdrinking with the larger neurodepression.

Published
2007
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37. In vivo contribution of Class III alcohol dehydrogenase (ADH3) to alcohol metabolism through activation by cytoplasmic solution hydrophobicity.

Author

Haseba T, Duester G, Shimizu A, Yamamoto I, Kameyama K, and Ohno Y

Subjects
Alcohol Dehydrogenase genetics, Animals, Behavior, Animal drug effects, Enzyme Activation, Ethanol pharmacology, Hydrophobic and Hydrophilic Interactions, Isoenzymes genetics, Liver chemistry, Liver cytology, Liver metabolism, Male, Mice, Mice, Inbred Strains, Mice, Knockout, Oxidation-Reduction, Alcohol Dehydrogenase metabolism, Cytoplasm chemistry, Ethanol metabolism, Isoenzymes metabolism
Abstract

Alcohol metabolism in vivo cannot be explained solely by the action of the classical alcohol dehydrogenase, Class I ADH (ADH1). Over the past three decades, attempts to identify the metabolizing enzymes responsible for the ADH1-independent pathway have focused on the microsomal ethanol oxidizing system (MEOS) and catalase, but have failed to clarify their roles in systemic alcohol metabolism. In this study, we used Adh3-null mutant mice to demonstrate that Class III ADH (ADH3), a ubiquitous enzyme of ancient origin, contributes to alcohol metabolism in vivo dose-dependently resulting in a diminution of acute alcohol intoxication. Although the ethanol oxidation activity of ADH3 in vitro is low due to its very high Km, it was found to exhibit a markedly enhanced catalytic efficiency (kcat/Km) toward ethanol when the solution hydrophobicity of the reaction medium was increased with a hydrophobic substance. Confocal laser scanning microscopy with Nile red as a hydrophobic probe revealed a cytoplasmic solution of mouse liver cells to be much more hydrophobic than the buffer solution used for in vitro experiments. So, the in vivo contribution of high-Km ADH3 to alcohol metabolism is likely to involve activation in a hydrophobic solution. Thus, the present study demonstrated that ADH3 plays an important role in systemic ethanol metabolism at higher levels of blood ethanol through activation by cytoplasmic solution hydrophobicity.

Published
2006
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38. Dose and time changes in liver alcohol dehydrogenase (ADH) activity during acute alcohol intoxication involve not only class I but also class III ADH and govern elimination rate of blood ethanol.

Author

Haseba T, Tomita Y, Kurosu M, and Ohno Y

Subjects
Animals, Dose-Response Relationship, Drug, Ethanol metabolism, Ethanol poisoning, Isoenzymes metabolism, Liver enzymology, Male, Mice, Mice, Inbred Strains, Time Factors, Alcohol Dehydrogenase metabolism, Ethanol blood, Liver metabolism
Abstract

Background: The elimination rate of blood ethanol usually depends on the activity of liver alcohol dehydrogenase (ADH). During acute alcohol intoxication, however, it is unclear how liver ADH activity changes with dose and time and what the involvement is of the two major isozymes of liver ADH: the classically known class I ADH and the very high Km class III ADH. We investigated dose- and time-wise changes in liver ADH activity and the contents of both ADHs by administering ethanol to mice, and analyzed the relationship among these ADH parameters to assess the contributions of these ADHs to liver ADH activity and ethanol metabolism in vivo., Methods: Mice were given ethanol doses of 0, 1, 3 or 5 g/kg body weight and killed 0.5, 1, 2, 4, 8 or 12 h after administration. The elimination rate of blood ethanol was calculated from the regression line fitted to the blood ethanol curve. The liver ADH activity of crude extract was conventionally measured with 15 mM ethanol as a substrate. The liver class I and class III ADH contents were determined by enzyme immunoassay. These three ADH parameters were statistically analyzed., Results: The change in liver ADH activity depended on both dose and time (P<0.001 by two-way ANOVA, n=74), but the change in the class I content depended on dose alone (P<0.0001). The class III content depended on both dose and time (P<0.001) with a time course similar to that of liver ADH activity for each dose. The sum of the class I and class III contents exhibited a higher correlation with liver ADH activity (r=0.882, P<0.0001) than the class I content alone did (r=0.825). The mean liver ADH activity during ethanol metabolism for each dose correlated significantly with the elimination rate of blood ethanol (r=0.970, P<0.0001)., Conclusion: Liver ADH activity changes dose and time dependently during acute alcohol intoxication and governs the elimination rate of blood ethanol through the involvement not only of class I but also of class III ADH.

Published
2003
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39. Flow cytometric and fluorescence microscopic analysis of ethanol-induced G2+M block: ethanol dose-dependently delays the progression of the M phase.

Author

Mashimo K, Haseba T, and Ohno Y

Subjects
Cell Size, Cells, Cultured, Cyclin B drug effects, Cyclin B genetics, Cyclin B immunology, Dose-Response Relationship, Drug, Fluorescent Antibody Technique, Humans, Karyotyping, Microtubules drug effects, Time Factors, Cell Division drug effects, Ethanol pharmacology, Flow Cytometry methods, Interphase drug effects, Microscopy, Fluorescence methods, Mitosis drug effects
Abstract

We found previously that short-term (3 and 6 h) exposure to ethanol (100 and 200 mM) induced the transient arrest of L929 cells at the G2+M phase. To identify the exact site blocked during the G2+M phase, we carried out flow cytometry and microscopic analysis with asynchronous L929 cells exposed to ethanol (12.5-330 mM) for 3, 6 or 24 h. Flow cytometry (the simultaneous analysis of cellular DNA and cyclin B1 content) revealed that the percentage of 4c (tetraploid) cells with a high level of cyclin B1 increased after continuous 6 h exposure to ethanol (> or =82.5 mM) and decreased after 24 h exposure, which supports the idea of a transient M-phase block. To determine the sub-M phase of 4c cells with high levels of cyclin B1 based on spindle microtubules and their karyotype, we viewed immunofluorescent images by double staining with Hoechst 33258 (bis-benzimide trihydrochloride) for DNA and with fluorescein isothiocyanate-labelled antibody for cyclin B1 or beta-tubulin. A 6 h exposure to intermediate concentrations (50-100 mM) of ethanol increased the number of early-anaphase cells, compared with the control, suggesting an inhibition of the elongation of polar microtubules. Both 6 and 24 h exposure to higher concentrations (100-200 mM) of ethanol increased metaphase cells, indicating an arrest at the spindle assembly checkpoint and suggesting an inhibition of the shortening of kinetochore microtubules and/or the degradation of cyclin B . Moreover, 6 h exposure to 330 mM ethanol increased round, probably early-prophase, cells, suggesting inhibition of the formation of spindle microtubules. Thus, it is likely that higher concentrations of ethanol affect the elongation, contraction, and formation of the spindle microtubules of L929 cells dose-dependently and also disrupt the correlation between microtubule organization and the synthesis and degradation of cyclin B1, thereby delaying the progress of karyokinesis, which may lead to an ethanol-induced G2+M block.

Published
1999
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40. [Assay methods of alcohol metabolizing enzymes].

Author

Haseba T and Ohno Y

Subjects
Animals, Chemistry Techniques, Analytical methods, Ethanol metabolism, Humans, Liver enzymology, Alcohol Dehydrogenase analysis, Alcohol Oxidoreductases analysis, Catalase analysis, Cytochrome P-450 Enzyme System analysis
Published
1997

41. Alcohol dehydrogenase (ADH) isozymes in the AdhN/AdhN strain of Peromyscus maniculatus (ADH-deermouse) and a possible role of class III ADH in alcohol metabolism.

Author

Haseba T, Yamamoto I, Kamii H, Ohno Y, and Watanabe T

Subjects
Animals, Mice, Alcohol Dehydrogenase analysis, Ethanol metabolism, Gastric Mucosa metabolism, Isoenzymes analysis, Liver metabolism, Peromyscus metabolism
Abstract

Although the AdhN/AdhN strain of Peromyscus maniculatus (so-called ADH- deermouse) has been previously considered to be deficient in ADH, we found ADH isozymes of Classes II and III but not Class I in the liver of this strain. On the other hand, the AdhF/AdhF strain (so-called ADH+ deermouse), which has liver ADH activity, had Class I and III but not Class II ADH in the liver. In the stomach, Class III and IV ADHs were detected in both deermouse strains, as well as in the ddY mouse, which has the normal mammalian ADH system with four classes of ADH. These ADH isozymes were identified as electrophoretic phenotypes on the basis of their substrate specificity, pyrazole sensitivity, and immunoreactivity. Liver ADH activity of the ADH- strain was barely detectable in a conventional ADH assay using 15 mM ethanol as substrate; however, it increased markedly with high concentrations of ethanol (up to 3 M) or hexenol (7 mM). Furthermore, in a hydrophobic reaction medium containing 1.0 M t-butanol, liver ADH activity of this strain at low concentrations of ethanol (< 100 mM) greatly increased (about sevenfold), to more than 50% that of ADH+ deermouse. These results were attributable to the presence of Class III ADH and the absence of Class I ADH in the liver of ADH- deermouse. It was also found that even the ADH+ strain has low liver ADH activity (< 40% that of the ddY mouse) with 15 mM ethanol as substrate, probably due to low activity in Class I ADH. Consequently, liver ADH activity of this strain was lower than its stomach ADH activity, in contrast with the ddY mouse, whose ADH activity was much higher in the liver than in the stomach, as well as other mammals. Thus, the ADH systems in both ADH- and ADH+ deermouse were different not only from each other but also from that in the ddY mouse; the ADH- strain was deficient in only Class I ADH, and the ADH+ strain was deficient in Class II ADH and down-regulated in Class I ADH activity. Therefore, Class III ADH, which was found in both strains and activated allosterically, may participate in alcohol metabolism in deermouse, especially in the ADH- strain.

Published
1995
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42. [Mirroring on palmar interdigital configurational areas].

Author

Tomita Y, Haseba T, Ohno Y, and Watanabe T

Subjects
Adult, Anthropometry, Female, Humans, Japan, Male, Polymorphism, Genetic, Dermatoglyphics
Abstract

The palmar prints of 902 medical students (732 male and 170 female) were analyzed according to the method of Cummins and Midlo, in an attempt to reveal a bilateral variance of palmar interdigital configurations within individuals. 1) No sex differences were observed in the frequency of true patterns in each interdigital area. The overall frequency of true patterns was highest in the fourth interdigital area (left 86.7%, right 70.8%) and decreased in the following order: the hypothenar area (left 25.6%, right 22.8%), the third interdigital area (left 12.1%, right 29.7%), the thenar/first interdigital area (left 14.6%, right 4.3%) and the second interdigital area (left 0.6%, right 1.2%). 2) Each palmar configurational area showed a different frequency of true patterns in the right and left hands. In the hypothenar area, the thenar/first interdigital area and the fourth interdigital area, true patterns were found most frequently on the left hand. On the other hand, true patterns were found most frequently on the right hand in the second interdigital area and the third interdigital area, especially the frequency of the loop pattern, which was 2.8 times higher in the left palm than in the right palm in males, and 2.5 times higher in females. 3) The frequency of students who had the same pattern type in both hands was highest in the second interdigital area (98.4%) and decreased in the following order: the thenar/first interdigital area (88.0%), the hypothenar area (77.9%), the third interdigital area (74.1%) and the fourth interdigital area (68.0%).(ABSTRACT TRUNCATED AT 250 WORDS)

Published
1994

43. Lineage-specific and differentiation-dependent expression of K12 keratin in rabbit corneal/limbal epithelial cells: cDNA cloning and northern blot analysis.

Author

Wu RL, Zhu G, Galvin S, Xu C, Haseba T, Chaloin-Dufau C, Dhouailly D, Wei ZG, Lavker RM, and Kao WY

Subjects
Amino Acid Sequence, Animals, Base Sequence, Blotting, Northern, Cell Differentiation, Cells, Cultured, Cloning, Molecular, Conjunctiva cytology, Conjunctiva metabolism, Consensus Sequence, Cornea cytology, Epithelial Cells, Epithelium metabolism, Fluorescent Antibody Technique, Gene Library, Immune Sera, Immunoblotting, Keratins analysis, Molecular Sequence Data, Oligopeptides chemical synthesis, Oligopeptides immunology, RNA, Messenger analysis, Rabbits, Skin cytology, Cornea metabolism, Keratins biosynthesis, RNA, Messenger biosynthesis, Skin metabolism
Abstract

Corneal epithelial cells synthesize an acidic (55 kDa) K12 and a basic (64 kDa) K3 keratin as their major differentiation products during an advanced stage of differentiation. In this paper, we describe the cDNA cloning of rabbit K12 keratin. We used a 36 base pairs (bp) oligonucleotide corresponding to a consensus sequence of many known acidic keratins as a probe to screen a cDNA library of normal rabbit corneal epithelium. Several partial cDNA clones were isolated. Hybrid-selection showed that the 3'keratin chain-specific portion of the cDNA hybridizes with K12 mRNA. A rabbit antiserum raised against the C-terminus of the cDNA-deduced amino acid sequence recognizes, in immunoblotting, the K12 keratin. In situ hybridization showed that K12 mRNA is present in all cell layers of central corneal epithelium, but in only the suprabasal cells of limbal epithelium indicating a parallel expression pattern between K12 and K3. Cultured rabbit corneal epithelial cells initially synthesize K14/K5 keratins, but later when the cells become heavily stratified they synthesize large quantities of K12 and K3 mRNAs, as detected by Northern blotting. Cultured esophageal epithelial cells do not make K12 mRNA confirming the tissue-specificity of K12 expression. Although it has been suggested that conjunctival epithelial cells can trans-differentiate into a bona fide corneal epithelium, we showed here that cultured conjunctival cells do not synthesize significant amounts of K12/K3 mRNAs. These results strongly suggest that conjunctival epithelial cells, whose differentiation can be modulated significantly by the extracellular matrix, form a lineage intrinsically distinct from the corneal/limbal epithelial lineage.

Published
1994
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44. Expression of collagen I, smooth muscle alpha-actin, and vimentin during the healing of alkali-burned and lacerated corneas.

Author

Ishizaki M, Zhu G, Haseba T, Shafer SS, and Kao WW

Subjects
Actins genetics, Animals, Collagen genetics, Cornea metabolism, DNA Probes, Eye Burns chemically induced, Female, Fibroblasts metabolism, Gene Expression, Immunoenzyme Techniques, Male, RNA, Messenger metabolism, Rabbits, Vimentin genetics, Wound Healing, Actins metabolism, Burns, Chemical metabolism, Collagen metabolism, Corneal Injuries, Eye Burns metabolism, Eye Injuries, Penetrating metabolism, Vimentin metabolism
Abstract

Purposes: Alkali-burned corneas can seldom heal properly to restore corneal transparency. To provide a better understanding of this devastating corneal injury, we compared the expression of collagen I, smooth muscle alpha-actin (alpha-SMA), and vimentin in lacerated and alkali-burned rabbit corneas., Methods: A radiolabeled cDNA probe of alpha 1(I) chain was used in slot-blot hybridization to determine the levels of alpha 1(I) mRNA in alkali-burned corneas. In situ hybridization was used to identify the cell types that express the alpha 1(I) chain. Antibodies against collagen I, alpha-SMA, and vimentin were used in immunohistochemical studies to determine the tissue distribution of collagen I and to identify cells expressing alpha-SMA and vimentin., Results: The levels of alpha 1(I) mRNA in alkali-burned corneas increased steadily after the alkali burn and reached a plateau within 2 weeks. One day after alkali burn, specific in situ hybridization signals were detected in stromal cells immediately surrounding the edge of the corneal injury. As the healing proceeded, the fibroblastic cells migrated into the injured stroma, and they showed positive reactions by in situ hybridization and by immunostaining with anti-collagen I probes. In alkali-burned corneas, retrocorneal membranes were formed 1 week after injury. This fibrillar membrane was stained by anti-collagen I antibody, and the fibroblastic cells in the membrane were hybridized by the 3H-labeled alpha 1(I) cDNA probe. No retrocorneal membrane was formed in the lacerated corneas, even after the injured corneas were allowed to heal for 3 weeks. The epithelial cells in the epithelial plug of lacerated corneas were positive by in situ hybridization, whereas the epithelial cells in the regenerated epithelium of alkali-burned cornea was not. Antibodies against alpha-SMA reacted with the migrating fibroblastic cells but did not react with epithelial cells or endothelial cells in the injured corneas. Anti-vimentin antibody reacted with fibroblastic cells, endothelial cells, and keratocytes in normal and injured corneas, and with the basal epithelial cells of injured corneas., Conclusions: During wound healing, the keratocytes that migrate to injured stroma transform into myofibroblasts. These myofibroblasts express high levels of alpha 1(I) mRNA, alpha-SMA, and vimentin. The healing of alkali-burned corneas differ from that of lacerated corneas in that the retrocorneal membranes are formed in the former but not in the latter. In addition, the epithelial cells of alkali-burned corneas lack alpha 1(I) mRNA, whereas it is found in the epithelium of lacerated corneas. These differences may result from the persistence of inflammatory cells in the alkali-burned corneas.

Published
1993

45. Diminution of biological reactivity of ethanol by changing the solution structure by weak ultrasonication.

Author

Haseba T, Matsushita K, Asakura T, Kameyama K, Tamaki T, Okouchi S, Watanabe T, and Uedaira H

Subjects
Adult, Animals, Ethanol analysis, Ethanol pharmacokinetics, Female, Humans, Hydroxyl Radical analysis, Injections, Intraperitoneal, Male, Mice, Mice, Inbred Strains, Molecular Structure, Reflex drug effects, Alcoholic Beverages toxicity, Alcoholic Intoxication psychology, Arousal drug effects, Ethanol toxicity, Postural Balance drug effects, Smell drug effects, Sonication, Taste drug effects
Abstract

The weak ultrasonication (40 kHz, 12 mW, 1 week) of ethanol solutions was found to reduce stimulation of the senses of smell and taste by the ethanol on the basis of blind tests with an aqueous ethanol solution (33.0% w/v) and an immature distilled spirit (25.0% v/v). Experiments on mice also demonstrated that a treated aqueous ethanol solution had a weaker depressant effect on the central nervous system, as evaluated by the relative frequency with which mice regained the righting reflex at a dose of either 4.0 or 4.5 g/kg (p < 0.05 or p < 0.01, respectively) and by the reduction in rectal temperature at a dose of 5.0 g/kg (p < 0.05) soon after ethanol administration. Analyses of both the ethanol concentration by head-space gas chromatography and the free radicals by electron spin resonance spectrometer failed to reveal any chemical changes in aqueous ethanol solutions subjected to weak ultrasonication. However, measurement of the spin-lattice relaxation time (T1) of the 2H of water molecules by 2H-NMR showed that the treatment slightly accelerated the thermal motion of water molecules in the solutions. Treated solutions were also found to have a slightly higher density than untreated ones. These physical data demonstrate that weak ultrasonication induces a structural change, such as a more compact and homogeneous structure by changing the microdynamic behavior of the solution. These biological and physical studies suggest that only a slight structural change in an ethanol solution induces a marked change in the biological reactivity of ethanol without any chemical modification of the solution itself.

Published
1993
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46. Expression of K12 keratin in alkali-burned rabbit corneas.

Author

Zhu G, Ishizaki M, Haseba T, Wu RL, Sun TT, and Kao WW

Subjects
Animals, Autoradiography, Cells, Cultured, Corneal Injuries, DNA Probes, Disease Models, Animal, Epithelium injuries, Epithelium metabolism, Eye Burns chemically induced, Female, Gene Expression, In Situ Hybridization, Keratins genetics, Male, RNA, Messenger metabolism, Rabbits, Sodium Hydroxide, Wound Healing physiology, Burns, Chemical metabolism, Cornea metabolism, Eye Burns metabolism, Keratins metabolism
Abstract

The healing of alkali-injured corneas is characterized by the persistence of polymorphonuclear leukocytes (PMN) in tissues and recurrent corneal epithelial defects. It has been suggested that the proteolytic enzymes secreted by PMN may account in part for the recurrent epithelial defects in the alkali-burned corneas. Cytoplasmic keratins, which form intracellular intermediate filaments, participate in the formation of hemidesmosomes and play a key role in the focal adhesion of epithelial cells to the basement membranes. The K3/K12 keratin pair is a major constituent of differentiated and stratified corneal epithelium. We have recently cloned the cDNA encoding the rabbit K12 keratin. In the present study we examined the expression of K12 keratin during the healing of alkali-burned rabbit corneas by slot-blot and in situ hybridization. Our results indicate that in normal cornea K12 keratin is equally expressed in all cell layers of stratified corneal epithelium and suprabasal layers of limbal epithelium, but not in bulbar conjunctival and other epithelia, i.e., lens, iris, and retinal pigment epithelium. The basal cells of the detached regenerating epithelium of the injured cornea express a very low level of K12 keratin. These observations are consistent with the notion that defective expression of K3/K12 keratins may play a role in the abnormal attachment of the regenerating epithelium to the basement membrane.

Published
1992
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47. [Allosterism of acidic alcohol dehydrogenase (class III ADH) of mouse liver and its role in alcohol metabolism].

Author

Yamamoto I, Haseba T, Kurosu M, and Watanabe T

Subjects
Aldehyde Oxidoreductases metabolism, Allosteric Site, Animals, Enzyme Activation, Liver enzymology, Male, Mice, Mice, Inbred Strains, Aldehyde Oxidoreductases physiology, Ethanol metabolism, Liver metabolism
Abstract

Two major ADH isozymes of mouse liver, basic ADH (Class I) and acidic ADH (Class III) were purified and the effects of various hydrophobic substances (t-butanol, butyramide, trifluoroethanol, trichloroacetic acid, stearic acid, oleamide, phenylalanine and norleucine) on their activities were investigated. All these hydrophobic substances activated acidic ADH with a range of from 15 to 560%, and reversely inactivated basic ADH activity with a range of from 10 to 100%, when 150 mmol/l ethanol was used as a substrate. Among these substances, t-butanol, which was the most potent activator of acidic ADH, enhanced the activity by 560% and completely inactivated basic ADH at a concentration of 1.0 mol/l. Kinetics studies demonstrated that the activation of acidic ADH by the hydrophobic substances was due to marked decreases of Km for ethanol in spite of decreases of Vmax, suggesting these substances were positive allosteric effectors for the isozyme. The inactivation of basic ADH by the hydrophobic substances was due to a decrease of Vmax without changing Km for ethanol. These results indicate that the activities of two ADH isozymes are regulated reversely by the hydrophobicity of the reaction environment which changes their kinetics constants. The ELISA method using the isozyme-specific antibody demonstrated that the content of acidic ADH in mouse liver was about 7 times larger than that of basic ADH (5.3 +/- 0.86 vs 0.72 +/- 0.06 mg/g-liver). In the light of the hydrophobic regulation of ADH isozyme activities and their liver contents, the role of acidic ADH on alcohol metabolism may be more predominant than basic ADH in the liver under hydrophobic condition.

Published
1992
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48. Effects of chronic ethanol intoxication on aldehyde dehydrogenase in mouse liver.

Author

Tomita Y, Haseba T, Kurosu M, and Watanabe T

Subjects
Animals, Mice, Alcoholism physiopathology, Aldehyde Dehydrogenase drug effects, Ethanol adverse effects
Abstract

Effects of chronic ethanol treatment with liquid diet (ethanol constituted 28% of the calories) on hepatic aldehyde dehydrogenase (ALDH) isozymes were studied in mice. One week of ethanol feeding caused 66% loss of mitochondrial low Km ALDH activity and 80% loss of mitochondrial high Km ALDH activity, compared with the control-fed group. However, these decreases recovered after 4 weeks of ethanol feeding. The cytosolic ALDH activity increased up to 140% after 10 weeks of ethanol feeding, compared with the control-fed group. Effects of acute ethanol injection on ALDH activity after prolonged ethanol feeding were studied. The severe acute ethanol injection (4.5 g/kg body wt) after 4 weeks of ethanol feeding caused a drastic decrease of the mitochondrial low Km ALDH activity; however, that did not affect the ethanol-fed group. After 10 weeks of ethanol feeding, acute ethanol injection (4.5 g/kg body wt) caused about twofold increase in mitochondrial low Km ALDH activity. From the agarose IEF study, it was found that ethanol intoxication does not affect the number and pI value of ALDH isozymes.

Published
1992

49. Effects of acute ethanol intoxication on aldehyde dehydrogenase in mouse liver.

Author

Tomita Y, Haseba T, Kurosu M, and Watanabe T

Subjects
Acetaldehyde pharmacokinetics, Alcoholic Intoxication blood, Animals, Ethanol pharmacokinetics, Male, Metabolic Clearance Rate, Mice, Mice, Inbred Strains, Alcoholic Intoxication enzymology, Aldehyde Dehydrogenase metabolism, Liver enzymology
Abstract

To elucidate the effects of acute ethanol intoxication on hepatic aldehyde dehydrogenase (ALDH), the activities of these isozymes were measured after acute ethanol injection at the doses of 1, 3 or 5 g/Kg body weight in mice. At the same time, blood ethanol and acetaldehyde levels were measured to consider their correlation to the changes in ALDH activities. In the cytosolic fraction, acute ethanol injection caused no effects on high Km ALDH. However, low Km ALDH activity decreased significantly after 0.5 and 12 hr at the dose of 5 g/Kg body weight. In the granule fraction, acute ethanol injection caused more than 50% loss of low Km ALDH activity after 2 to 8 hr at the dose of 1 g/Kg and after 0.5 to 8 hr at the dose of 3 or 5 g/Kg body weight, in comparison with the untreated group. However, high Km ALDH activity decreased only after 4 hr at the dose of 3 or 5 g/Kg body weight. The elimination rate of blood ethanol was 158.0 mumol/min/1 and 125.6 mumol/min/1 after 0.5 to 4 hr of ethanol injection at the dose of 3 or 5 g/Kg body weight, respectively. However, these elimination rates decreased drastically after 4 to 8 hr following ethanol injection. The elimination rate of blood acetaldehyde was 116.6 nmol/min/1 after 1 to 2 hr, and the rate decreased to 6.9 nmol/min/1 after 2 to 8 hr following ethanol injection at the dose of 5 g/Kg body weight. These drastic decreases in acetaldehyde elimination rate appear to be caused by reduction of the granule low Km ALDH activity.

Published
1990

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