Racial Differences in Biological Sensitivity to Ethanol: The Role of Alcohol Dehydrogenase and Aldehyde Dehydrogenase Isozymes

Electrophoretic and kinetic studies of autopsy liver specimens from individuals of different racial groups revealed a polymorphism in alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH). About 85% of the Japanese livers had an atypical ADH and 52% of the livers an unusual ALDH. Only 13% of German liver specimens had the atypical ADH and none showed the unusual form of ALDH which lacks in the isozyme with low Km for acetaldehyde. Using hair roots as the source of ADH and ALDH, individuals showing sensitivity to ethanol were examined. Data on the distribution of phenotypes in random European and Japanese population as well as family studies suggest a direct relationship between the lack of low Km isozyme of ALDH and alcohol-induced biological sensitivity. Our findings suggest that the alcohol sensitivity quite common in individuals of Mongoloid origin might be due to delayed oxidation of acetaldehyde by an unusual type of ALDH.     

Intralobular Distribution of Class I Alcohol Dehydrogenase and Aldehyde Dehydrogenase 2 Activities in the Hamster Liver

The hepatic lobular localization of class I alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) 2 activities was examined histochemically using livers of hamsters with high ethanol preferences. The activity of class I ADH detected by the nitro blue tetrazolium method using 5 mM ethanol as a substrate was extremely high and was almost homogeneously distributed throughout the lobule. The ALDH 2 activity (substrate, 8 μM acetaldehyde) was localized to the centrilobular zone, whereas low K_m ALDH (ALDH 1 + ALDH 2) activity (substrate, 50 μM acetaldehyde) showed a gradient distribution in the lobule with high centrilobular to moderate periportal activity, suggesting that the ALDH 1 activity was distributed throughout the lobule.     

Polymorphisms of Alcohol Dehydrogenase‐1B and Aldehyde Dehydrogenase‐2 and the Blood and Salivary Ethanol and Acetaldehyde Concentrations of Japanese Alcoholic Men

Background: The effects of genetic polymorphism of aldehyde dehydrogenase‐2 (ALDH2) on alcohol metabolism are striking in nonalcoholics, and the effects of genetic polymorphism of alcohol dehydrogenase‐1B (ADH1B) are modest at most, whereas genetic polymorphisms of both strongly affect the susceptibility to alcoholism and upper aerodigestive tract (UADT) cancer of drinkers. Methods: We evaluated associations between ADH1B/ADH1C/ALDH2 genotypes and the blood and salivary ethanol and acetaldehyde levels of 168 Japanese alcoholic men who came to our hospital for the first time in the morning and had been drinking until the day before. Results: The ethanol levels in their blood and saliva were similar, but the acetaldehyde levels in their saliva were much higher than in their blood, probably because of acetaldehyde production by oral bacteria. Blood and salivary ethanol and acetaldehyde levels were both significantly higher in the subjects with the less active ADH1B*1/*1 genotype than in the ADH1B*2 carriers, but none of the levels differed according to ALDH2 genotype. Significant linkage disequilibrium was detected between the ADH1B and ADH1C genotypes, but ADH1C genotype did not affect the blood or salivary ethanol or acetaldehyde levels. High blood acetaldehyde levels were found even in the active ALDH2*1/*1 alcoholics, which were comparable with the levels of the inactive heterozygous ALDH2*1/*2 alcoholics with less active ADH1B*1/*1. The slope of the increase in blood acetaldehyde level as the blood ethanol level increased was significantly steeper in alcoholics with inactive heterozygous ALDH2*1/*2 plus ADH1B*2 allele than with any other genotype combinations, but the slopes of the increase in salivary acetaldehyde level as the salivary ethanol level increased did not differ between the groups of subjects with any combinations of ALDH2 and ADH1B genotypes. Conclusions: The ADH1B/ALDH2 genotype affected the blood and salivary ethanol and acetaldehyde levels of nonabstinent alcoholics in a different manner from nonalcoholics, and clear effects of ADH1B genotype and less clear effects of ALDH2 were observed in the alcoholics. Alterations in alcohol metabolism as a result of alcoholism may modify the gene effects, and these findings provide some clues in regard to associations between the genotypes and the risks of alcoholism and UADT cancer.     

ADH and ALDH Polymorphisms and Alcohol Dependence in Mexican and Native Americans

Background: Ethanol is primarily metabolized in the liver by two rate-limiting reactions: conversion of ethanol to acetaldehyde by alcohol dehydrogenase (ADH) and subsequent conversion of acetaldehyde to acetate by aldehyde dehydrogenase (ALDH). ADH and ALDH exist in multiple isozymes that differ in their kinetic properties. Notably, polymorphisms within the genes that encode for these isozymes vary in their allele frequencies between ethnic groups, and thus, they have been considered as candidate genes that may differentially influence risk for the development of alcohol dependence across ethnic groups. Objectives and methods: Associations between alcohol dependence and polymorphisms in ADH1B, ADH1C, and ALDH2 were compared in a community sample of Native Americans (n 791) living on reservations and Mexican Americans (n 391) living within the same county. Results: Two Mexican Americans and no Native Americans possessed one ALDH2*2 allele. Presence of at least one ADH1B*2 allele was found in 7% of the Native Americans and 13% of the Mexican Americans, but was only associated with protection against alcohol dependence in the Mexican Americans. Presence of at least one ADH1B*3 allele was found in 4% of the Native Americans and 2% of the Mexican Americans, but was associated with protection against alcohol dependence only in the Native Americans. No associations between alcohol dependence and polymorphisms in ADH1C were found. Conclusions and Scientific Significance: Polymorphisms in ADH1B are protective against alcoholism in these two populations; however, these findings do not explain the high prevalence of alcoholism in these populations.     

Slow-metabolizing ADH1B and inactive heterozygous ALDH2 increase vulnerability to fatty liver in Japanese men with alcohol dependence

Background

Genetic polymorphisms of alcohol dehydrogenase-1B (ADH1B; rs1229984, His48Arg) and aldehyde dehydrogenase-2 (ALDH2; rs671, Glu504Lys) affect body weight, body fat, and lipid metabolism in individuals with alcohol dependence, and the aim of this study was to identify their determinants in relation to the development of fatty liver.

Methods

We evaluated associations between the presence of fatty liver and ADH1B and ALDH2 genotypes and other factors in 1604 Japanese men who had been admitted for treatment of alcohol dependence.

Results

Fatty liver was diagnosed when ultrasonography showed both hepatorenal contrast and liver brightness. Age-adjusted usual alcohol intake did not differ according to ADH1B or ALDH2 genotypes. A multivariate analysis showed that the adjusted odds ratio (OR, 95% confidence interval) of slow-metabolizing ADH1B Arg/Arg carriers was 1.61 (1.27–2.03) for fatty liver and 1.82 (1.37–2.41) for fatty liver with deep attenuation in comparison with the ADH1B His/Arg or His/His carriers, and that the OR of inactive heterozygous ALDH2 Glu/Lys carriers was 1.43 (1.08–1.91) for fatty liver and 1.84 (1.31–2.59) for fatty liver with deep attenuation in comparison with the ALDH2 Glu/Glu carriers. Younger age, shorter interval between the last drink and the ultrasound examination, larger body mass index, and absence of cirrhosis were identified as other positive determinants for fatty liver.

Conclusions

The ADH1B Arg/Arg genotype and the ALDH2 Glu/Lys genotype were positive determinants of fatty liver in the subjects. These results suggest that slow ethanol and acetaldehyde metabolism accelerates the development of alcoholic fatty liver in heavy drinkers.

     

Ethanol metabolism by HeLa cells transduced with human alcohol dehydrogenase isoenzymes: control of the pathway by acetaldehyde concentration

Background: Human class I alcohol dehydrogenase 2 isoenzymes (encoded by the ADH1B locus) have large differences in kinetic properties; however, individuals inheriting the alleles for the different isoenzymes exhibit only small differences in alcohol elimination rates. This suggests that other cellular factors must regulate the activity of the isoenzymes. Methods: The activity of the isoenzymes expressed from ADH1B*1, ADH1B*2, and ADH1B*3 cDNAs was examined in stably transduced HeLa cell lines, including lines which expressed human low K_m aldehyde dehydrogenase (ALDH2). The ability of the cells to metabolize ethanol was compared with that of HeLa cells expressing rat class I alcohol dehydrogenase (ADH) (HeLa‐rat ADH cells), rat hepatoma (H4IIEC3) cells, and rat hepatocytes. Results: The isoenzymes had similar protein half‐lives in the HeLa cells. Rat hepatocytes, H4IIEC3 cells, and HeLa‐rat ADH cells oxidized ethanol much faster than the cells expressing the ADH1B isoenzymes. This was not explained by high cellular NADH levels or endogenous inhibitors; but rather because the activity of the β1 and β2 ADHs was constrained by the accumulation of acetaldehyde, as shown by the increased rate of ethanol oxidation by cell lines expressing β2 ADH plus ALDH2. Conclusion: The activity of the human β2 ADH isoenzyme is sensitive to inhibition by acetaldehyde, which likely limits its activity in vivo. This study emphasizes the importance of maintaining a low steady‐state acetaldehyde concentration in hepatocytes during ethanol metabolism.     

The Activity of Class I, II, III, and IV Alcohol Dehydrogenase (ADH) Isoenzymes and Aldehyde Dehydrogenase (ALDH) in Esophageal Cancer

Background/Aims Ethanol consumption is associated with an increased risk of esophageal cancer. The carcinogenic compound is acetaldehyde, the product of ethanol metabolism. Alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) are the main enzymes involved in ethanol metabolism, which leads to generation of acetaldehyde. In this study the activity of ADH isoenzymes and ALDH in esophageal cancer were compared with the activity in normal tissue. Methods For measurement of the activity of class I and II ADH isoenzymes and ALDH activity fluorimetric methods were employed. Total ADH activity and activity of class III and IV isoenzymes was measured by the photometric method. Samples were taken from 59 esophageal cancer patients (27 adenocarcinoma, 32 squamous cell cancer). Results The total activity of ADH and activity of class IV ADH were significantly higher in cancer cells than in healthy tissues. The other tested classes of ADH showed a tendency toward higher activity in cancer than in normal cells. Differences between the activity of enzymes of drinkers and non-drinkers in both cancer and healthy tissue were not significant. Conclusion Increased ADH IV activity may be a factor intensifying carcinogenesis, because of the increased ability to form acetaldehyde from ethanol.     

ADH and ALDH Polymorphisms and Alcohol Dependence in Mexican and Native Americans

Background: Ethanol is primarily metabolized in the liver by two rate-limiting reactions: conversion of ethanol to acetaldehyde by alcohol dehydrogenase (ADH) and subsequent conversion of acetaldehyde to acetate by aldehyde dehydrogenase (ALDH). ADH and ALDH exist in multiple isozymes that differ in their kinetic properties. Notably, polymorphisms within the genes that encode for these isozymes vary in their allele frequencies between ethnic groups, and thus, they have been considered as candidate genes that may differentially influence risk for the development of alcohol dependence across ethnic groups. Objectives and methods: Associations between alcohol dependence and polymorphisms in ADH1B, ADH1C, and ALDH2 were compared in a community sample of Native Americans (n 791) living on reservations and Mexican Americans (n 391) living within the same county. Results: Two Mexican Americans and no Native Americans possessed one ALDH2*2 allele. Presence of at least one ADH1B*2 allele was found in 7% of the Native Americans and 13% of the Mexican Americans, but was only associated with protection against alcohol dependence in the Mexican Americans. Presence of at least one ADH1B*3 allele was found in 4% of the Native Americans and 2% of the Mexican Americans, but was associated with protection against alcohol dependence only in the Native Americans. No associations between alcohol dependence and polymorphisms in ADH1C were found. Conclusions and Scientific Significance: Polymorphisms in ADH1B are protective against alcoholism in these two populations; however, these findings do not explain the high prevalence of alcoholism in these populations.     

Aldehyde Dehydrogenases of the Rat Colon: Comparison with Other Tissues of the Alimentary Tract and the Liver

Intracolonic bacteria have previously been shown to produce substantial amounts of acetaldehyde during ethanol oxidation, and it has been suggested that this acetaldehyde might be associated with alcohol-related colonic disorders, as well as other alcohol-induced organ injuries. The capacity of colonic mucosa to remove this bacterial acetaldehyde by aldehyde dehydrogenase (ALDH) is, however, poorly known. We therefore measured ALDH activities and determined ALDH isoenzyme profiles from different subcellular fractions of rat colonic mucosa. For comparison, hepatic, gastric, and small intestinal samples were studied similarly. Alcohol dehydrogenase (ADH) activities were also measured from all of these tissues. Rat colonic mucosa was found to possess detectable amounts of ALDH activity with both micromolar and millimolar acetaldehyde concentrations and in all subcellular fractions. The ALDH activities of co-Ionic mucosa were, however, generally low when compared with the liver and stomach, and they also tended to be lower than in small intestine. Mitochondrial low K_m ALDH2 and cytosolic ALDH with low K_m for acetaldehyde were expressed in the colonic mucosa, whereas some cytosolic high K_m isoenzymes found in the small intestine and stomach were not detectable in colonic samples. Cytosolic ADH activity corresponded well to ALDH activity in different tissues: in co-Ionic mucosa, it was ～6 times lower than in the liver and about one-half of gastric ADH activity. ALDH activity of the colonic mucosa should, thus, be sufficient for the removal of acetaldehyde produced by colonic mucosal ADH during ethanol oxidation. It may, however, be insufficient for the removal of the acetaldehyde produced by intracolonic bacteria. This may lead to the accumulation of acetaldehyde in the colon and colonic mucosa after ingestion of ethanol that might, at least after chronic heavy alcohol consumption, contribute to the development of alcohol-related colonic morbidity, diarrhea, and cancer.     

Haplotype-based study of the association of alcohol-metabolizing genes with alcohol dependence in four independent populations

Background: Ethanol is metabolized by 2 rate‐limiting reactions: alcohol dehydrogenases (ADH) convert ethanol to acetaldehyde that is subsequently metabolized to acetate by aldehyde dehydrogenases (ALDH). Approximately 50% of East Asians have genetic variants that significantly impair this pathway and influence alcohol dependence (AD) vulnerability. We investigated whether variation in alcohol metabolism genes might alter the AD risk in four non‐East Asian populations by performing systematic haplotype association analyses to maximize the chances of capturing functional variation. Methods: Haplotype‐tagging SNPs were genotyped using the Illumina GoldenGate platform. Genotypes were available for 40 SNPs across the ADH genes cluster and 24 SNPs across the two ALDH genes in four diverse samples that included cases (lifetime AD) and controls (no Axis 1 disorders). The case control sample sizes were the following: Finnish Caucasians: 232, 194; African Americans: 267, 422; Plains American Indians: 226, 110; and Southwestern American (SW) Indians: 317, 72. Results: In all four populations, as well as HapMap populations, 5 haplotype blocks were identified across the ADH gene cluster: (i) ADH5‐ADH4; (ii) ADH6‐ADH1A‐ADH1B; (iii) ADH1C; (iv) intergenic; (v) ADH7. The ALDH1A1 gene was defined by 4 blocks and ALDH2 by 1 block. No haplotype or SNP association results were significant after correction for multiple comparisons; however, several results, particularly for ALDH1A1 and ADH4, replicated earlier findings. There was an ALDH1A1 block 1 and 2 (extending from intron 5 to the 3′ UTR) yin yang haplotype (haplotypes that have opposite allelic configuration) association with AD in the Finns driven by SNPs rs3764435 and rs2303317, respectively, and an ALDH1A1 block 3 (including the promoter region) yin yang haplotype association in SW Indians driven by 5 SNPs, all in allelic identity. The ADH4 SNP rs3762894 was associated with AD in Plains Indians. Conclusions: The systematic evaluation of alcohol‐metabolizing genes in four non‐East Asian populations has shown only modest associations with AD, largely for ALDH1A1 and ADH4. A concentration of signals for AD with ALDH1A1 yin yang haplotypes in several populations warrants further study.     

The Activity of Class I,II, III,and IV Alcohol Dehydrogenase (ADH) Isoenzymes and Aldehyde Dehydrogenase (ALDH) in Liver Cancer

Background Alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH), which are most abundant in the liver, are the main enzymes involved in ethanol and acetaldehyde metabolism. Aims The purpose of this study was to compare the activity of ADH isoenzymes and ALDH between liver carcinoma cells and healthy hepatocytes. Patients Samples were taken from 44 liver cancer patients (19 drinkers, 25 nondrinkers). Seventeen patients had primary liver tumors and 27 had metastatic liver tumors. Methods Fluorimetric methods were used for measurement of the activity of class I and II ADH isoenzymes and ALDH activity. Total ADH activity and activity of class III and IV isoenzymes were measured by a photometric method. Results The activities of total ADH, ALDH, and class I ADH were significantly higher in cancer cells than in healthy tissues. The other tested classes of ADH showed a tendency toward higher activity in cancer than in normal cells. The differences between enzymes of drinkers and nondrinkers in both cancer and healthy tissue, were not significant. Conclusion Differences in the activities of total ADH, ALDH and class I ADH isoenzyme between cancer liver tissues and healthy hepatocytes might be a factor in ethanol metabolism disorders, which can intensify carcinogenesis.     

Polymorphism of ADH and ALDH Genes among Four Ethnic Groups in China and Effects upon the Risk for Alcoholism

The alcohol dehydrogenases (ADHs) and aldehyde dehydrogenases (ALDHs) that metabolize ethanol are polymorphic. Different alleles encode subunits of the enzymes that differ in their rate of metabolizing ethanol. These polymorphisms are distributed differently among populations and have been shown to influence the risk for alcoholism in some Asian populations. We have examined the allele frequencies at the ADH2, ADH3 , and ALDH2 loci in four populations from China (Han, Mongolian, Korean, and Elunchun) and in alcoholics within each population. The four populations differ in allele frequencies, with the Elunchun having a much lower frequency of ADH2 *2 alleles, and the Mongolian and Elunchun having a much lower frequency of ALDH2 *2 alleles. Within each population, alleles at one or more of these three loci are protective against alcoholism, although the populations differ in which loci play significant roles. The protective allele at each locus ( ALDH2 * 2 , ADH2 * 2 , and ADH3 * 1 ) encodes a subunit that either metabolizes ethanol to acetaldehyde more rapidly or slows the conversion of acetaldehyde to acetate. Taken as a whole, data demonstrate that genetic differences in the enzymes that metabolize alcohol can substantially affect the risk for alcoholism.     

The Activity of Class I, II, III, and IV Alcohol Dehydrogenase Isoenzymes and Aldehyde Dehydrogenase in Colorectal Cancer

Chronic ethanol consumption is associated with an increased risk for cancer of the colorectum. The highly toxic and carcinogenic compound is acetaldehyde, the product of ethanol metabolism. Ethanol is metabolized to acetaldehyde by alcohol dehydrogenase (ADH) in colorectal mucosa and bacteria. The enzyme responsible for oxidation of acetaldehyde is aldehyde dehydrogenase. The aim of this study was to compare ADH isoenzymes and ALDH activity in colorectal cancer with the activity in normal colonic mucosa. Total ADH activity was measured by a photometric method with p-nitrosodimethylaniline (NDMA) as substrate, and ALDH activity by a fluorometric method with 6-methoxy-2-naphthaldehyde as a substrate. For measurement of the activity of class I and II isoenzymes we employed fluorometric methods, with class-specific fluorogenic substrates. The activity of class III ADH was measured by the photometric method with n-octanol as substrate, and class IV with m-nitrobenzaldehyde as substrate. Samples were taken surgically during routine operations of colorectal carcinomas from 32 patients. The activities of total ADH and, the most important in colon mucosa, class I ADH were significantly higher in cancer than in healthy tissues. The other tested classes of ADH had a tendency to higher-level activity in cancer cells than in healthy mucosa. ALDH activity was not significantly lower in the cancer cells. The activities of all tested enzymes and isoenzymes were not significantly higher in drinkers than in nondrinkers both in colorectal cancer and in normal mucosa. The differences in activities of total ADH and class I isoenzyme between cancer tissues and normal colon mucosa might be a factor for metabolic changes and disturbances in low-mature cancer cells and, additionally, might be a reason for the higher level of acetaldehyde, which can intensify carcinogenesis.     

The Activity of Class I,III, and IV of Alcohol Dehydrogenase Isoenzymes and Aldehyde Dehydrogenase in Gastric Cancer

The metabolism of cancer is in many way different than in healthy cells. Increased metabolism of several carcinogenic substances may take place in cancer cells. The one of them was ethanol, that is oxidized by alcohol dehydrogenase (ADH) to high concentration of acetaldehyde, a toxic and carcinogenic compound. The enzyme responsible for oxidation of acetaldehyde is aldehyde dehydrogenase (ALDH). The aim of this study was to compare the capacity for ethanol metabolism measured by ADH isoenzymes and ALDH activity between gastric cancer and normal gastric mucosa. Total ADH activity was measured by photometric method with p-nitrosodimethylaniline (NDMA) as a substrate and ALDH activity by the fluorometric method with 6-methoxy-2-naphtaldehyde as a substrate. For the measurement of the activity of class I isoenzymes, we used fluorometric methods, with class-specific fluorogenic substrates. The activity of class III ADH was measured by the photometric method with n-octanol and class IV with m-nitrobenzaldehyde as a substrate. The samples were taken surgically during routine operations of gastric carcinomas from 55 patients. The activities of total ADH, and the most important in gastric mucosa, class IV ADH were significantly higher in cancer cells than in healthy tissues. The other tested classes of ADH and ALDH showed a tendency toward higher activity in cancer than in healthy mucosa. The activities of all tested enzymes and isoenzymes were not significantly higher in men than in women in wither gastric cancer tissues or normal mucosa. The increased ADH IV activity may be 1 of the factors intensifying carcinogenesis by the increased ability to acetaldehyde formation from ethanol.     

Expression Pattern, Ethanol-Metabolizing Activities, and Cellular Localization of Alcohol and Aldehyde Dehydrogenases in Human Pancreas: Implications for Pathogenesis of Alcohol-Induced Pancreatic Injury

Background:  Alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) are major enzymes responsible for metabolism of ethanol. Genetic polymorphisms of ADH1B , ADH1C , and ALDH2 occur among racial populations. The metabolic effect and metabolites contribute to pathogenesis of pancreatic injury. The goal of this study was to determine the functional expressions and cellular localization of ADH and ALDH families in human pancreas.
Methods:  Fifty five surgical specimens of normal pancreas as well as 15 samples each for chronic pancreatitis and pancreatic cancer from archival formalin-fixed paraffin-embedded tissue specimens were investigated. Class-specific antibodies were prepared by affinity chromatographies from rabbit antisera raised against recombinant human ADH1C1, ADH4, ADH5, ADH7, ALDH1A1, ALDH2, and ALDH3A1. The isozyme expression patterns of ADH/ALDH were identified by isoelectric focusing, and the activities were assayed spectrophotometrically. The protein contents of ADH/ALDH isozymes were determined by immunoblotting, and the cellular localizations were detected by immunohistochemistry and histochemistry.
Results:  At 33 mM ethanol, pH 7.5, the activities were significantly different between allelic phenotypes of ADH1B. The activity of ALDH2-inactive phenotypes was slightly lower than ALDH2-active phenotypes at 200 μM acetaldehyde. The protein contents were in the following decreasing order: ALDH1A1, ALDH2, ADH1, and ADH5. ADH1B was detected in the acinar cells and ADH1C in the ductular, islet, and stellate cells. The expression of ADH1C appeared to be increased in the activated pancreatic stellate cells in chronic pancreatitis and pancreatic cancer.
Conclusions:  Alcohol dehydrogenase and ALDH family members are differentially expressed in the various cell types of pancreas. ADH1C may play an important role in modulation of activation of pancreatic stellate cells.     

Alcohol dehydrogenase (ADH) isoenzymes and aldehyde dehydrogenase (ALDH) activity in the human pancreas

Ethanol metabolism in the pancreas occurs predominantly by way of an nonoxidative pathway to fatty acid ethyl esters but oxidative routes to acetaldehyde also may contribute to injury of pancreatic cells. Three metabolic systems are responsible for the oxidative metabolism of ethanol, among which the cytochrome P-4502E1 and alcohol dehydrogenase have been found in the pancreas. The aims of this study were to detect ADH and ALDH in the human pancreas and to assess which ADH isoenzymes are present in this organ. ADH activity was measured by the photometric method and ADH isoenzyme activity was determined using sensitive and specific substrates. ALDH activity was measured by the fluorometric method. We have shown that the activities of ADH and ALDH are present in the pancreas, although the activity of ALDH was not proportionally as low as ADH activity. The class III isoenzyme exhibited the highest activity of all ADH isoenzymes tested and it was about 7 times higher than the activity of class I. The activities of classes II and IV were low. The activities of ADH isoenzymes of classes I, II, and III in the pancreas of men were significantly higher than in women. This study demonstrates that alcohol dehydrogenase and aldehyde dehydrogenase are present in the pancreas.     

Ethanol Oxidation and Acetaldehyde Production in Vitro by Human Intestinal Strains of Escherichia coli under Aerobic,Microaerobic, and Anaerobic Conditions

Background: Many human colonic facultative anaerobic and aerobic bacteria are capable of alcohol dehydrogenase (ADH)-mediated ethanol oxidation. In this bacteriocolonic pathway for ethanol oxidation intracolonic ethanol is first oxidized by bacterial ADHs to acetaldehyde, which is further oxidized by either colonic mucosal or bacterial aldehyde dehydrogenases to acetate. The produced acetaldehyde is a highly toxic and carcinogenic agent. This study was aimed to investigate the ethanol oxidation capability and acetaldehyde formation of Escherichia coli IH 50546 and IH 50817. These intestinal E. coli strains expressed either high (IH 50546) or low (IH 50817) ADH activity. Methods: Strains were cultured for 48 h on agar plates supplemented with ethanol under aerobic, microaerobic (6% O₂), and anaerobic conditions. Results: Under aerobic conditions both E. coli     

Association of aldehyde dehydrogenase 2 gene polymorphism with multiple oesophageal dysplasia in head and neck cancer patients

BACKGROUND: Multiple occurrences of oesophageal dysplasia are frequently observed in head and neck cancer patients, and closely associated with alcohol consumption. Acetaldehyde, the first metabolite of ethanol, is thought to play an important role in the carcinogenesis of the upper aerodigestive tract. AIM: To investigate if genetic polymorphism in alcohol metabolising enzymes (ADH3, alcohol dehydrogenase 3; ALDH2, aldehyde dehydrogenase 2) is associated with oesophageal multiple dysplasia in head and neck cancer patients. METHODS: Thirty one consecutive patients with head and neck cancer were included in the study. Multiple oesophageal dysplasia was detected endoscopically as multiple Lugol voiding lesions (multiple LVL) using the Lugol dye staining method. The ADH3 and ALDH2 genotypes were determined by polymerase chain reaction-restriction fragment length polymorphism. RESULTS: Among the 31 patients with head and neck cancer, 17 had multiple LVL. Multiple LVL were closely associated with a second primary oesophageal carcinoma in head and neck cancer patients (odds ratio 60.7, 95% CI 5.6-659). Furthermore, the mutant ALDH2 allele was significantly more prevalent in patients with multiple LVL (65% v 29%; p<0.05) whereas no difference was observed in ADH3 polymorphism. CONCLUSIONS: The mutant ALDH2 allele appears to be a risk indicator for multiple LVL in head and neck cancer patients. Accumulation of acetaldehyde due to low ALDH2 activity may play a critical role in cancerous changes throughout the mucosa in the upper aerodigestive tract.     

Disposition of Ethanol and Activity of Hepatic and Placental Alcohol Dehydrogenase and Aldehyde Dehydrogenases in the Third-Trimester Pregnant Guinea Pig for Single and Short-Term Oral Ethanol Administration

The disposition of ethanol and its metabolite, acetaldehyde, and the activity of alcohol dehydrogenase (ADH) and aldehyde dehydrogenases (ALDH) were determined in the third-trimester pregnant guinea pig following single and 7-day oral administration of ethanol (0.5 g X kg maternal body weight-1 X day-1). Animals were killed at each of selected times after the single and seventh ethanol dose. For both ethanol dosage regimens, the maternal and fetal blood and brain ethanol concentrations were virtually identical during the elimination phase of the time-course study. There was initial slow transfer of ethanol into amniotic fluid, followed by significantly higher ethanol concentration in amniotic fluid relative to maternal and fetal blood during the elimination phase. Acetaldehyde was measurable in maternal blood, maternal brain, and fetal brain at concentrations that were low and variable. For both ethanol dosage regimens, ADH activity was measurable only in maternal liver. Low Km ALDH activity was measurable only in maternal liver and fetal liver. High Km ALDH was measurable in maternal liver, fetal liver, and placenta and was significantly greater in maternal liver. The data indicate that there is bidirectional placental transfer of ethanol in the maternal-fetal unit; the elimination of ethanol from the maternal and fetal compartments is regulated by maternal hepatic biotransformation involving ADH; the amniotic fluid is a reservoir for ethanol in utero; the low Km ALDH in fetal liver protects the fetus from ethanol-derived acetaldehyde in the maternal circulation; and short-term maternal administration of once-daily, low-dose ethanol does not produce major changes in ethanol disposition and the activity of the enzymes involved in ethanol biotransformation.     

胃,直肠粘膜乙醇脱氢酶及醛脱氢酶含量测定及意义

流行病学研究表明，慢性酒精消耗增加了直肠癌发生的危险性。乙醇脱氢酶及乙醛可能与其发生机理有关。本研究应用分光光度法对３２例胃窦粘膜及３８例直肠粘膜活检标本乙醇脱氢酶和醛脱氢酶进行测定。结果表明：胃及直肠粘膜乙醇脱氢酶含量分别为０．８４ｎｍｏｌ／ｍｉｎ／ｇ和１．２７ｎｍｏｌ／ｍｉｎ／ｇ（Ｐ＜０．０５）；醛脱氢酶含量分别为０．７２ｎｍｏｌ／ｍｉｎ／ｇ和０．１３ｎｍｏｌ／ｍｉｎ／ｇ（Ｐ＜０．００１）。直肠粘膜内乙醇脱氢酶含量高而醛脱氢酶含量低将使饮酒后直肠粘膜内形成更多乙醛及增强致癌物的活化。本研究为流行病学研究结果提供了酶学依据。