Genetics and ontogeny of alcohol dehydrogenase isozymes in the mouse: evidence for a cis-acting regulator gene (Adt-i) controlling C2 isozyme expression in reproductive tissues and close linkage of Adh-3 and Adt-i on chromosome 3

Ontogeny of mammalian metabolizing enzymes in humans and animals used in toxicological studies

It is well recognized that expression of enzymes varies during development and growth. However, an in-depth review of this acquired knowledge is needed to translate the understanding of enzyme expression and activity into the prediction of change in effects (e.g. kinetics and toxicity) of xenobiotics with age. Age-related changes in metabolic capacity are critical for understanding and predicting the potential differences resulting from exposure. Such information may be especially useful in the evaluation of the risk of exposure to very low (µg/kg/day or ng/kg/day) levels of environmental chemicals. This review is to better understand the ontogeny of metabolizing enzymes in converting chemicals to either less-toxic metabolite(s) or more toxic products (e.g. reactive intermediate[s]) during stages before birth and during early development (neonate/infant/child). In this review, we evaluated the ontogeny of major "phase I" and "phase II" metabolizing enzymes in humans and commonly used experimental animals (e.g. mouse, rat, and others) in order to fill the information gap.

Alcohol dehydrogenases: gene multiplicity and differential functions of five classes of isozymes

Mammalian alcohol dehydrogenases (ADHs) constitute an enzyme family of multiple forms (isozymes) which are differentially distributed throughout the body. Subunit types alpha, beta and gamma in dimeric combinations constitute the isozymes of human liver class I ADH, and are >94% homologous in structure. Human pi and chi subunits form homodimeric Class II and III ADH isozymes. pi-ADH is liver specific whereas chi-ADH is widely distributed throughout the body. A sixth human ADH subunit (designated mu or sigma), forming a new dimeric human stomach ADH, has been recently reported as Class IV ADH. Evidence for a seventh human ADH subunit has also been described, designated as Class V, the transcripts having been reported in the stomach and liver. All five classes of ADH represent isozymes which are homologous but exhibit at least 30% sequence differences in primary srtructure. Kinetic analyses of four of these classes of ADH indicated differential functions, serving either in the oxidative or reductive mode. Studies from various laboratories indicate the following respective functions: oxidation of aliphatic and aromatic alcohols-liver Class I and Class II, and stomach Class IV ADHs; reduction of peroxidic aldehydes-Classes I, II and IV; 'biogenic' alcohol oxidation-Classes I and II; and glutathione-dependent formaldehyde dehydrogenase-Class III.

Aldehyde oxidase and alcohol dehydrogenase genetics in the mouse. New alleles for the Aox-2 and Adh-3 loci

The genetic variability of one of the liver isozymes of aldehyde oxidase (AOX-B2 or AOX-2) and the stomach isozyme of alcohol dehydrogenase (ADH-C2) has been examined among strains of mice. Evidence is presented for a fourth allele of Aox-2 and a third allele of Adh-3. The hybrid allozyme pattern for mouse liver AOX was consistent with a dimeric subunit structure for this enzyme.

Alcohol dehydrogenase isozymes in the mouse: genetic regulation, allelic variation among inbred strains and sex differences of liver and kidney A2 isozyme activity

Genetic analysis of a proposed cis-acting temporal locus (Adh-3t), which regulates alcohol dehydrogenase C2 (ADH-C2) activity in mouse epididymis extracts, among F1 (ddN X BALB/c) X ddN male backcross progeny provided evidence for genetic distinctness between the structural (Adh-3) and temporal (Adh-3t) loci on chromosome 3. Genetic analysis also confirmed the close linkage of Adh-1 (encoding liver and kidney ADH-A2) and Adh-3 (encoding stomach ADH-C2) to within 0.3 centimorgans on the mouse genome. Evidence is presented for a proposed closely linked cis-acting temporal locus (designated Adh-lt) for the A2 isozyme (encoded by Adh-1) controlling the activity of this enzyme in mouse kidney extracts, but having no apparent affect on liver and intestine ADH-A2 activities. An extensive survey of the distribution of Adh-1, Adh-3 and Adh-3t alleles among 65 strains of mice is reported--with the exception of two Japanese strains (ddN and KF), linkage disequilibrium between Adh-3 and Adh-3t was observed. Sex differences in mouse liver and kidney ADH-A2 activities were observed, with male/female ratios of approximately 0.6 and 3 respectively for these tissue extracts.

Gene markers for alcohol-metabolizing enzymes among recombinant inbred strains of mice with differential behavioural responses towards alcohol

The genetic variability of alcohol dehydrogenase (C2 isozyme), aldehyde dehydrogenase (A2 isozyme) and aldehyde oxidase (A2 isozyme) has been examined among recombinant inbred strains of mice which have been previously studied concerning their differential behavioural responses towards alcohol. The results showed no correlation between biochemical phenotype for these loci and behavioural response.

Sorbitol dehydrogenase genetics in the mouse: a 'null' mutant in a 'European' C57BL strain

A 'null' activity variant phenotype for sorbitol dehydrogenase (SDH) was observed in C57BL/LiA mice and used to examine the genetics of this enzyme. Linkage studies of the locus (Sdh-1) with non-agouti (a) and a biochemical locus encoding liver L-alpha-hydroxyacid oxidase (Hao-1) demonstrated that it is coincident with or closely linked to the structural locus, previously localized on chromosome 2. Alcohol dehydrogenase (ADH) isozymes were also examined, since the liver A2 isozyme exhibited some activity as a sorbitol dehydrogenase on cellulose acetate zymograms. It is apparent that SDH activity is not 'essential' in this mouse strain.

Opossum alcohol dehydrogenases: Sequences, structures, phylogeny and evolution: evidence for the tandem location of ADH genes on opossum chromosome 5

BLAT (BLAST-Like Alignment Tool) analyses and interrogations of the recently published opossum genome were undertaken using previously reported rat ADH amino acid sequences. Evidence is presented for six opossum ADH genes localized on chromosome 5 and organized in a comparable ADH gene cluster to that reported for human and rat ADH genes. The predicted amino acid sequences and secondary structures for the opossum ADH subunits and the intron-exon boundaries for opossum ADH genes showed a high degree of similarity with other mammalian ADHs, and four opossum ADH classes were identified, namely ADH1, ADH3, ADH6 and ADH4 (for which three genes were observed: ADH4A, ADH4B and ADH4C). Previous biochemical analyses of opossum ADHs have reported the tissue distribution and properties for these enzymes: ADH1, the major liver enzyme; ADH3, widely distributed in opossum tissues with similar kinetic properties to mammalian class 3 ADHs; and ADH4, for which several forms were localized in extrahepatic tissues, especially in the digestive system and in the eye. These ADHs are likely to perform similar functions to those reported for other mammalian ADHs in the metabolism of ingested and endogenous alcohols and aldehydes. Phylogenetic analyses examined opossum, human, rat, chicken and cod ADHs, and supported the proposed designation of opossum ADHs as class I (ADH1), class III (ADH3), class IV (ADH4A, ADH4B and ADH4C) and class VI (ADH6). Percentage substitution rates were examined for ADHs during vertebrate evolution which indicated that ADH3 is evolving at a much slower rate to that of the other ADH classes.

Alcohol dehydrogenases and aldehyde dehydrogenases among inbred strains of mice: multiplicity, development, genetic studies and metabolic roles

Alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) are the major enzymes responsible for the metabolism of alcohols and aldehydes in the body. Both exist as a family of isozymes in mammals, and have been extensively studied in animal models, particularly among inbred strains of mice. Mouse ADH exists as at least three major classes, which are predominantly localized in liver (classes I and III), and in stomach/cornea (class IV). Mouse ALDH exhibits extensive multiplicity, several forms of which have been characterized, including ALDH1 (liver cytoplasmic/class 1 isozyme); ALDH2 (liver mitochondrial/class 2.); ALDH3 (stomach cytosolic/class 3); ALDH4 (liver microsomal/class 3); and ALDH5 (testis cytosolic/class 3). Biochemical, genetic and molecular genetic analyses have been performed on several of these enzymes, including studies on variant forms of ADH and ALDH. Distinct metabolic roles are proposed, based upon their tissue and subcellular distribution characteristics and the biochemical properties for these enzymes.

Molecular analysis of genetic differences among inbred mouse strains controlling tissue expression pattern of alcohol dehydrogenase 4

The ADH gene family in vertebrates is composed of at least seven distinct classes based upon sequence comparisons and enzyme properties. The Adh4 gene product may play an important role in differentiation and development because of its capacity to metabolize retinol to retinoic acid. Allelic gene differences exist among inbred mouse strains which control structure and tissue-specific regulation of Adh4. C57BL/6 mice are unique and have no detectable ADH4 enzyme activity in epididymis and low levels in seminal vesicle, ovary and uterus compared to other strains. C57BL/6 mice express Adh4 in stomach at levels similar to other strains. The goal of this research was to investigate this genetic variation at the molecular level. Northern analysis revealed that the content of ADH4 mRNA in tissues correlate with the enzyme expression pattern. Interestingly, C57BL/6 mice express an ADH4 mRNA in stomach which is smaller than expressed in C3H and other mice. An analysis of the 5'- and 3'-ends of the mRNA using RACE analysis determined that the ADH4 mRNA in C57BL/6 mice is truncated in the 3'-untranslated region. Sequence analysis of RACE products showed that the truncation is due to a single nucleotide mutation which produces an early polyadenylation signal. Additional RACE and Northern analysis revealed that at least five different polyadenylation sites are used in the Adh4 gene. Using 3'-end polymorphisms found between C57BL/6 and C3H strains and RT-PCR, it was shown that the lack of expression in epididymis in C57BL/6 mice is cis-acting in F(1) hybrid animals. The DNA sequence of the proximal promoter (-600/+42 nt) was determined in several mouse strains differing in tissue-specific expression patterns and did not reveal any nucleotide substitutions correlating with expression pattern suggesting further upstream or downstream sequences may be involved.

Regulation of the mammalian alcohol dehydrogenase genes

This review focuses on the regulation of the mammalian medium-chain alcohol dehydrogenase (ADH) genes. This family of genes encodes enzymes involved in the reversible oxidation of alcohols to aldehydes. Interest in these enzymes is increased because of their role in the metabolism of beverage alcohol as well as retinol, and their influence on the risk for alcoholism. There are six known classes ADH genes that evolved from a common ancestor. ADH genes differ in their patterns of expression: most are expressed in overlapping tissue-specific patterns, but class III ADH genes are expressed ubiquitously. All have proximal promoters with multiple cis-acting elements. These elements, and the transcription factors that can interact with them, are being defined. Subtle differences in sequence can affect affinity for these factors, and thereby influence the expression of the genes. This provides an interesting system in which to examine the evolution of tissue specificity. Among transcription factors that are important in multiple members of this gene family are the C/EBPs, Sp1,USF, and AP1, HNF-1, CTF/NF-1, glucocorticoid, and retinoic acid receptors, and several as-yet unidentified negative elements, are important in at least one of the genes. There is evidence that cis-acting elements located far from the proximal promoter are necessary for proper expression. Three of the genes have upstream AUGs in the 5' nontranslated regions of their mRNA, unusual for mammalian genes. The upstream AUGs have been shown to significantly affect expression of the human ADH5 gene.

A genetic basis for corneal sensitivity to ultraviolet light among recombinant SWXJ inbred strains of mice

PURPOSE

To examine a possible genetic basis for corneal sensitivity to UV-B light exposure.

METHODS

To this end, adult male mice from the 14 SWXJ recombinant inbred albino strains (originating from SJL/J and SWR/J parental strains) were subjected to ultraviolet (UV) radiation exposure of 0.078 J/cm2 and photographed four days post-exposure, to assess corneal opacity and the possible correlation with corneal aldehyde dehydrogenase (ALDH) activity, alcohol dehydrogenase (ADH) activity and soluble protein content.

RESULTS

Those recombinant strains that exhibited the SWR/J strain phenotype of having low levels of ALDH and decreased soluble protein levels also exhibited greater levels of corneal clouding after UV-exposure than the other strains, which exhibited "normal" levels of both ALDH activity and soluble protein in the cornea.

CONCLUSIONS

These data support an hypothesis for a major role for ALDH in assisting the cornea to protect the eye against UV-induced tissue damage.

Gene structure and promoter for Adh3 encoding mouse class IV alcohol dehydrogenase (retinol dehydrogenase)

Class IV alcohol dehydrogenase (ADH) has been shown to function in vitro as a retinol dehydrogenase catalyzing the synthesis of retinoic acid, a pleiotropic gene regulator. To enable genetic studies on the function of this enzyme and regulation of its gene, we have screened a genomic library and isolated the mouse class IV ADH gene (Adh3). The complete mouse class IV ADH coding region was found in nine exons spanning a 14-kb region. Primer extension analysis was used to map the transcription initiation site to a position lying 30 bp upstream of the ATG translation start codon. Nucleotide sequence analysis of the promoter region indicated an absence of both TATA-box and GC-box sequences; this distinguishes it from the promoters for class I, II, and III ADH genes. Sequence comparison of the mouse and human class IV ADH promoters indicated that they share a conserved region located 125-145 bp upstream of the coding region containing adjacent sequences matching the consensus binding sites for transcription factors AP-1 and C/EBP.

Gene expression in a young multigene family: tissue-specific differences in the expression of the human alcohol dehydrogenase genes ADH1, ADH2, and ADH3

Three human alcohol dehydrogenase genes, ADH1, ADH2, and ADH3, were formed by tandem duplications and have diverged in their tissue-specific and developmental expression. Their proximal promoters remain 80-84% identical in sequence, approximately the same degree of identity as at synonymous sites in the coding regions of these three genes. To understand the evolution of tissue specificity, gene expression must be studied in many different cells and tissues. A systematic comparison of their promoters reveals the effects of subtle sequence differences on the binding of nuclear proteins to their cis-acting elements. There are differences in the affinity with which some proteins are bound to altered sites including C/EBP sites, USF/MLTF sites, and the G3T site (which binds Sp1). There are also differences in the sites that are occupied, e.g. CTF/NFI-related sites. These sequence differences are reflected in differences in gene expression in three cell lines. In H4IIE-C3 hepatoma cells, the ADH1 promoter was more active than the ADH2 promoter, and the ADH3 promoter was nearly nonfunctional. In HeLa cells, both ADH1 and ADH2 promoters directed expression; again the ADH3 promoter was extremely weak. None of the three promoters had much activity in CV-1 cells. Coexpression of C/EBP alpha greatly stimulated expression of the ADH1 promoter in HeLa cells and in CV-1 cells, but only weakly stimulated expression in H4IIE-C3 cells. The stimulation of the ADH1 promoter by C/EBP alpha was comparable to that of ADH2, despite the weaker binding to the C/EBP sites that flank the TATA box in ADH1. The ADH3 promoter was not greatly stimulated by C/EBP alpha, despite good binding of C/EBP alpha. These results demonstrate that small differences in the cis-acting elements affect affinity of binding by transcription factors and the pattern of gene expression.

Alcohol dehydrogenases in the brain of mice

Alcohol dehydrogenase (ADH) phenotypes were investigated in the brain of 15 different inbred mice by isoelectric focusing followed by staining of enzyme activities. The Class III ADH activity was detected in all the strains studied, whereas the Class II ADH activity was found only in few strains (including the alcohol-preferring strain--C57BL/6J) having the "a" allele (ADH-C2(2)) for this isozyme in stomach. The inbred strains having the "b" allele (ADH-C2(1)) for the Class II ADH in stomach (including the alcohol avoiding strains--BALB/c, CBA/H, C3H/He, DBA/2J, and SJL/J) demonstrated null variant for this phenotype in their brain. The Class I ADH activity was very low or absent in the brain extracts of all the strains studied. The ADH activities were confined to the cytosolic fractions of brain and were higher in the extracts of cerebral hemispheres than in cerebellum. The genetic linkage studies showed that the locus for the brain Class II ADH is closely linked to the "Adh gene complex" on chromosome 3 of mice.

Characterization of a new hybrid mink-mouse clone panel: chromosomal and regional assignments of the GLO, ACY, NP, CKBB, ADH2, and ME1 loci in mink (Mustela vison)

To expand the mink map, we established a new panel consisting of 23 mink-mouse clones. On the basis of statistical criteria (Wijnen et al. 1977; Burgerhout 1978), we developed a computer program for choice of clones of the panel. Assignments of the following mink genes were achieved with the use of the hybrid panel: glyoxalase (GLO), Chromosome (Chr) 1; acetyl acylase (ACY), Chr 5; creatine phosphokinase B (CKBB), Chr 10; alcohol dehydrogenase-2 (subunit B) (ADH2), Chr 8. Using a series of clones carrying rearrangements involving mink Chr 1 and 8, we assigned the gene for ME1 to the short arm of Chr 1 and that for ADH2 to Chr 8, in the region 8p12-p24. Mapping results confirm the ones we previously obtained with a mink-Chinese hamster panel. However, by means of an improved electrophoretic technique, we revised the localization of the gene for purine nucleoside phosphorylase (NP), which has been thought to be on mink Chr 2. It is reassigned to mink Chr 10.

Genetics of alcohol dehydrogenase and aldehyde dehydrogenase from Monodelphis domestica cornea: further evidence for identity of corneal aldehyde dehydrogenase with a major soluble protein

A didelphid marsupial, the gray short-tailed opossum (Monodelphis domestica), was used as a model species to study the biochemical genetics of alcohol dehydrogenases (ADHs) and aldehyde dehydrogenase (ALDH) in corneal tissue. Isoelectric point variants of corneal ALDH (designated ALDH3) and a major soluble protein in corneal extracts were observed among eight families of animals used in studying the genetics of these proteins. Both phenotypes exhibited identical patterns following PAGE-IEF and were inherited in a normal Mendelian fashion, with two alleles at a single locus (ALDH3) showing codominant expression. The data provided evidence for genetic identity of corneal ALDH with this major soluble protein, and supported biochemical evidence, recently reported for purified bovine corneal ALDH, that this enzyme constitutes a major portion of soluble corneal protein (Abedinia et al. 1990). Isoelectric point variants for corneal ADH were also observed, with patterns for the two major forms (ADH3 and ADH4) and one minor form (ADH5) being consistent with the presence of two ADH subunits (designated gamma and delta), and variant phenotypes existing for the gamma subunit. The genetics of this enzyme was studied in the eight families, and the results were consistent with codominant expression of two alleles at a single locus (designated ADH3). It is relevant that a major detoxification function has been proposed for corneal ADH and ALDH, in the oxidoreduction of peroxidic aldehydes induced by available oxygen and UV-B light (Holmes & VandeBerg, 1986a). In addition, a direct role for corneal ALDH as a UV-B photoreceptor in this anterior eye tissue has also been proposed (Abedinia et al. 1990).

Genetics of ocular NAD+-dependent alcohol dehydrogenase and aldehyde dehydrogenase in the mouse: evidence for genetic identity with stomach isozymes and localization of Ahd-4 on chromosome 11 near trembler

Electrophoretic and activity variation of the stomach and ocular isozyme of aldehyde dehydrogenase (designated AHD-4) was observed between C57BL/6J and SWR/J inbred strains of mice. The phenotypes were inherited in a normal mendelian fashion, with two alleles at a single locus (Ahd-4) showing codominant expression. The alleles assorted independently of those at Adh-3 [encoding the stomach and ocular isozyme of alcohol dehydrogenase (ADH-C2)] on chromosome 3. Three chromosome 11 markers, hemoglobin alpha-chain (Hba), trembler (Tr), and rex (Re), were used in backcross analyses which established that Ahd-4 is closely linked to trembler. The distribution patterns for stomach and ocular AHD-4 phenotypes were examined among SWXL recombinant inbred mice, and those for stomach and ocular ADH-C2 among BXD recombinant inbred strains. The data provided evidence for the genetic identity of stomach and ocular ADH-C2 and of stomach and ocular AHD-4.

Mapping and gene order of U1 small nuclear RNA, endogenous viral env sequence, amylase, and alcohol dehydrogenase-3 on mouse chromosome 3

Linkage was established between a number of genes that map on chromosome 3 by studying the distribution patterns of DNA polymorphisms and protein electrophoretic mobility polymorphisms in recombinant inbred (RI) strains of mice. This analysis resulted in the following suggested gene order between the newly assigned genes and previously mapped genes: gamma-fibrinogen (Fgg), Xmmv-22 of mink cell focus-inducing (MCF) virus, U1b small nuclear RNA gene cluster (Rnu-1b), amylase (Amy-1,2), cadmium resistance (cdm), alcohol dehydrogenase-3 (Adh-3), alcohol dehydrogenase-1 (Adh-1). In situ hybridization to chromosome spreads confirmed the assignment of the Ulb small nuclear RNA (snRNA) gene cluster and the gamma-fibrinogen gene to the center of chromosome 3.

Chromosome maps of man and mouse, III

Data on loci whose positions are known in both man and mouse are presented in the form of chromosomal displays, a table, and autosomal and X-chromosomal grids. At least 40 conserved autosomal segments with two or more loci, as well as 17 homologous X-linked loci, are now known in the two species, in which mitochondrial DNA is also highly conserved. Apart from the Y, the only chromosome now lacking a conserved group is human 13. Human 17 has a single conserved group which includes both short and long arms, and so may have remained largely intact in mammalian evolution. Human and mouse chromosomal maps show the approximate locations of homologous genes while the mouse map also shows the positions of translocations used in gene location.

A gene (Bmn) controlling beta-mannosidase activity in the mouse is located in the distal part of chromosome 3

A gene (Bmn) with a major effect on beta-mannosidase activity in kidney and liver of the house mouse was revealed by assay with the synthetic substrate p-nitrophenyl-beta-D-mannoside. Activity is low in DBA/2J and CSB mice and high in C57BL/6J mice. By the use of the BXD series of recombinant inbred strains and by crosses between C57BL and CSB, it was possible to map the gene to the distal part of chromosome 3 by demonstration of linkage to a gene for cadmium resistance, cdm, as well as to the Adh-3 locus.

Alcohol dehydrogenase isozymes in baboons: tissue distribution, catalytic properties, and variant phenotypes in liver, kidney, stomach, and testis

Isoelectric focusing and cellulose acetate electrophoresis were used to examine the multiplicity, tissue distribution, and variability of alcohol dehydrogenase (ADH) among baboons, a primate species used as a model for research on alcohol metabolism and alcohol-induced liver pathology. Five major ADH isozymes were resolved and distinguished on the basis of their isoelectric points, tissue distributions, relative activities with alcohol substrates, and sensitivities to inhibition with 4-methyl pyrazole. ADH-1 and ADH-2 exhibited class I kinetic properties and were observed in high activity in kidney and liver extracts, respectively. ADH-3 showed class II kinetic properties, exhibiting high activity in stomach extracts, and was widely distributed in extracts of other baboon tissues, including kidney, esophagus, heart, testis, brain, and male sex accessory tissues. ADH-4 also showed class II ADH properties but was found only in liver (similar to human "pi-ADH"). ADH-5 exhibited class III ADH kinetic properties, being inactive with ethanol up to 0.5 M (similar to human "chi-ADH") and was distributed widely in baboon tissue extracts. Major activity variation was observed for liver ADH-4 between different animals. An electrophoretic variant for ADH-3 was observed for the enzyme in stomach, kidney, and testis extracts, and activity variation existed for this isozyme in kidney extracts. It is apparent that baboon ADH shares a number of features with the human ADH phenotype; however, several species-specific differences were observed, particularly for the liver and kidney class I isozymes and for stomach ADH.

Biochemical genetic variants in mice selectively bred for sensitivity or resistance to ethanol-induced sedation

The distribution of biochemical genetic variants was examined among eight inbred strains of mice, which served as contributors to a heterogeneous stock of mice (HS), and in short-sleep (SS) and long-sleep (LS) mice, selectively bred from the HS stock for differential ethanol sensitivity. Fifteen loci for enzymes of alcohol and aldehyde metabolism, as well as 12 other biochemical loci, were investigated. Thirteen of these loci exhibited allelic variation between strains, of which six were separately fixed in the SS and LS mice. Comparisons of genetic similarity coefficients, based upon the distributions of allelic variants for the loci examined, with behavioural sensitivities (sleep-time) to an acute dose of ethanol for the inbred and selected strains of mice, indicated no correlations between these data. This suggests that this collective group of loci are not useful indicators of the genes selectively bred in the SS and LS strains, which are responsible for the differential sensitivities to acute doses of ethanol.

Genetic variants of enzymes of alcohol and aldehyde metabolism

The distribution of genetic variants (or gene markers) for alcohol dehydrogenase, aldehyde dehydrogenase, aldehyde oxidase, and aldehyde reductase isozymes has been examined among 12 inbred strains of mice. Electrophoretic variants are described for the major liver and stomach alcohol dehydrogenase isozymes (ADH-A2 and C2); liver, kidney, and stomach aldehyde dehydrogenase isozymes (AHD-1; AHD-2; AHD-4); a liver-specific aldehyde reductase (AHR-A2); and a liver aldehyde oxidase isozyme (AOX-2). Genetically determined activity variants were observed for a testis-specific aldehyde dehydrogenase (AHD-6); liver and kidney aldehyde reductase isozymes (AHR-3 and AHR-4); and the major liver AOX isozyme (AOX-1). These variants may serve as useful gene markers in alcohol research involving animal model studies with inbred strains in mice.

Interferon-induced guanylate-binding proteins: mapping of the murine Gbp-1 locus to chromosome 3

GBP-1 is the predominant species of a family of guanylate-binding proteins synthesized in mouse cells in response to interferons (IFNs) alpha, beta, or gamma. IFN inducibility of this 65,000-Da protein is controlled by alleles at a single autosomal locus, Gbp-1, with allele a encoding inducibility and allele b noninducibility. Here, we present evidence suggesting that both alleles occur in outbred populations of wild mice. Using recombinant inbred strains and classical linkage analysis of offspring of two-point and three-point backcrosses we demonstrate that Gbp-1 is linked to Adh-3 (encoding alcohol dehydrogenase C2) and VaJ (varitintwaddler-Jackson) located on the distal part of chromosome 3. The relevant recombination frequencies (RFs) (+/- SE) were 3.5 (+/- 1.1) and 11.7 (+/- 2.8)%, respectively. We further show that strain B6.C-H-23c/By(HW 53), congenic for a small segment of chromosome 3, carries the BALB/c alleles at both the Gbp-1 and the Adh-3 locus and not the alleles of the B6 background strain confirming the chromosomal location and close linkage of the two loci.

Aldehyde reductase isozymes in the mouse: evidence for two new loci and localization of Ahr-3 on chromosome 7

Evidence is presented for two new forms of mouse liver and kidney aldehyde reductase activity (designated AHR-3 and AHR-4) resolved using cellulose acetate electrophoresis zymogram techniques and stained by glyceraldehyde and NADPH as substrate and coenzyme, respectively. Activity variants were observed for those isozymes among inbred strains of mice and used in a genetic analyses to support a proposal for two new genetic loci (Ahr-3 and Ah-4) which control the activity phenotype for these isozymes. Segregation analysis indicated that these loci are separately localized on the mouse genome, with Ahr-3 positioned on the distal end of chromosome 7. Liver AHR-2 (or hexonate dehydrogenase) exhibited no detectable phenotypic variation among the 44 inbred strains of mice examined. The AHR-3 and AHR-4 isozymes were readily distinguished from AHR-1 [or aldehyde reductase A2, described previously by Duley and Holmes (Biochem. Genet. 20:1067, 1982)], hexonate dehydrogenase (AHR-2), and alcohol dehydrogenase A2 in terms of their differential substrate, coenzyme, and inhibitor specificities.

Biochemical genetics of aldehyde dehydrogenase isozymes in the mouse: evidence for stomach- and testis-specific isozymes

Electrophoretic and activity variants have been observed for stomach and testis aldehyde dehydrogenases, respectively, among inbred strains of the house mouse (Mus musculus). Genetic evidence was obtained for two new loci encoding these isozymes (designated Ahd-4 and Ahd-6, respectively, for the stomach and testis isozymes) which segregated independently of a number of mouse gene markers, including Ahd-1 (encoding mitochondrial aldehyde dehydrogenase) on chromosome 4, ep (pale ears), a marker for chromosome 19, on which Ahd-2 (encoding liver cytosolic aldehyde dehydrogenase) has been previously localized, and Adh-3 (encoding the stomach-specific isozyme of alcohol dehydrogenase) on chromosome 3. Recombination studies have indicated, however, that Ahd-4 and Ahd-6 are distinct but closely linked loci on the mouse genome. An extensive survey of the distribution of Ahd-1, Ahd-2, Ahd-4, and Ahd-6 alleles among 56 strains of mice is reported. No variants have been observed, so far, for the microsomal (AHD-3) and mitochondrial/cytosolic (AHD-5) isozymes previously described. This study, in combination with previous investigations on mouse aldehyde dehydrogenases, provides evidence for six genetic loci for this enzyme.

A two dimensional model of alcohol consumption: possible interaction of brain catalase and aldehyde dehydrogenase

The possible existence of a biological marker system mediating voluntary consumption of ethanol in rats has been examined in a series of studies. The working hypothesis underlying this research was that acetaldehyde, the primary metabolite of ethanol, mediates the positive reinforcing properties of ethanol and thus underlies the voluntary consumption of ethanol in both animals and humans. We further hypothesized that brain catalase and aldehyde dehydrogenase, the enzymes controlling the production and elimination of acetaldehyde in the brain, may represent a biological marker system underlying the affinity of the animals to consume ethanol. Data demonstrating that the activity levels of these enzymes are positively correlated with alcohol ingestion seems to suggest that it is likely that the enzyme activity can serve as a predictor of the propensity to drink alcohol. A predictive model is proposed which describes the modulation of voluntary ethanol intake through the activity of these enzymes and their role in determining rates of formation and degradation of acetaldehyde in the brain.

An isozyme-specific selective system for the recovery of mammalian cells deficient in hepatic alcohol dehydrogenase activity

A selective system toxic towards mammalian cells expressing the liver-specific isozyme of alcohol dehydrogenase (L-ADH) has been developed. A number of alpha-unsaturated primary and secondary alcohols were assayed for their ability to serve as substrates for rat liver ADH and were screened for cytotoxicity towards L-ADH+ and L-ADH- cells. 1-Propen-3-ol and 1-penten-3-ol were identified as agents showing selective cytotoxicity. Reconstruction experiments demonstrated that 1-propen-3-ol at a concentration of 15 microM could be used to recover L-ADH- clones from mixed populations of L-ADH+ and L-ADH cells. Cells expressing the non-allelic S-ADH isozyme were not killed under these conditions. The selective system defined in this report is thus isozyme-specific.

Regulation of Cat1 gene expression in the scutellum of maize during early sporophytic development

A regulatory element has been identified in maize that appears to exert an effect specifically on Cat1 gene expression in the scutellum of maize during early sporophytic development. Cat1 encodes CAT-1 catalase, one of two forms of catalase expressed in the scutellum during this developmental time period. Density-labeling experiments indicate that the regulatory element influences the overall levels of CAT-1 protein synthesis in the scutellum but has no effect on CAT-2 protein synthesis. Immunoprecipitation experiments of in vitro translation products suggest that this element has an effect on the level of translatable Cat1 mRNA associated with the scutellar polysomes. The element exhibits additive inheritance and is tissue and time specific in its action. This element, therefore, meets all the criteria of a regulatory gene and has been designated Car2. The element acts to regulate the temporal expression of the Cat1 structural locus in maize.

Genetic considerations in the effects of ethanol in mice. II. A trans-acting inducibility regulator(s) affecting alcohol dehydrogenase (ADH) activity

The inducibility of alcohol dehydrogenase (ADH) has been recognized in different systems including maize, Drosophila, and mice. Our earlier results showed strain-specific ADH responses to chronic ethanol administration relative to matched littermate controls in mice. For this study we used two strains which showed "induction" (BALB/c and S.W.) and two strains which showed "repression" (C57BL/6J and 129/ReJ) to produce three sets of F1 hybrids and their reciprocals and one set (BALB/c X C57BL/6J) of recombinant inbred (RI) lines. The ADH properties of the resulting genotypes were again evaluated following 15% ethanol treatment in drinking water (2 weeks) in relation to their littermate matched controls in replicated trials. Our F1 results suggest complete dominance for induction over repression at the phenotypic level, and the two repressed strains showed complementation. No significant differences were observed in the reciprocal F1's and all pairs of a given genotype-treatment combination yielded consistent results. The 1:1 segregation of RI lines suggests a single gene difference for ADH inducibility between BALB/c and C57BL/6J. These findings suggest the presence of a trans-acting inducibility regulator(s) for ADH which may or may not represent a single locus. Variability for such regulatory elements may provide an explanation for the commonly observed individual differences in natural populations for response to alcohol including alcohol metabolism.

Purification and molecular properties of mouse alcohol dehydrogenase isozymes

Alcohol dehydrogenase isozymes from mouse liver (A2 and B2) and stomach (C2) tissues have been purified to homogeneity using triazine-dye affinity chromatography. The enzymes are dimers with similar but distinct subunit sizes, as determined by SDS/polyacrylamide gel electrophoresis: A, 43000; B, 39000, and C, 47000. Zinc analyses and 1,10-phenanthroline inhibition studies indicated that the A and C subunits each contained two atoms of zinc, with at least one being involved catalytically, whereas the B subunit probably contained a single non-catalytic zinc atom. The isozymes exhibited widely divergent kinetic characteristics. A2 exhibited a Km value for ethanol of 0.15 mM and a broad substrate specificity, with Km values decreasing dramatically with an increase in chain length; C2 also exhibited this broad specificity for alcohols but showed a Km value of 232 mM for ethanol. These isozymes also showed broad substrate specificities as aldehyde reductases. In contrast, B2 showed no detectable activity as an aldehyde reductase for the aldehydes examined, and used ethanol as substrate only at very high concentrations (greater than 0.5 M). The isozyme exhibited low Km and high Vmax values, however, with medium-chain alcohols. Immunological studies showed that A2 was immunologically distinct from the B2 and C2 isozymes. In vitro molecular hybridization studies gave no evidence for association between the alcohol dehydrogenase subunits. The results confirm genetic analyses [Holmes, Albanese, Whitehead and Duley (1981) J. Exp. Zool. 215, 151-157] which are consistent with at least three structural genes encoding alcohol dehydrogenase in the mouse and confirm the role of the major liver isozyme (A2) in ethanol metabolism.

Trans-acting temporal locus within the beta-glucuronidase gene complex

Mice carrying the [Gus]H haplotype of the beta-glucuronidase gene complex have considerably decreased enzyme levels and a decreased rate of enzyme synthesis. This is now shown to result from the action of two regulatory loci within the gene complex. One is a systemic regulator, Gus-u, that acts cis to cause a uniform reduction in enzyme levels in all tissues. The other is a temporal locus, Gus-t, that acts trans to cause abrupt switches in the rate of enzyme synthesis in only certain tissues and at characteristic stages of development. The distinction between these two loci was made possible by the introduction of a method for quantitating the relative numbers of A and H allozyme subunits in beta-glucuronidase tetramers. The procedure involves purification of the enzyme, cleavage at methionyl residues with CNBr, isoelectric focusing to separate the peptides, and quantitation of the peptide containing the A/H amino acid substitution. The presence of a trans-acting regulatory locus within a gene complex raises evolutionary and functional questions about why it is located there and how it acts.

Alcohol dehydrogenase in the mouse epididymis. Genetic variation and cellular localization

The cellular localization of alcohol dehydrogenase (ADH) in the mouse epididymis was investigated using differential substrate specificities and genetic variation as a means of distinguishing these enzymes histochemically in tissue sections. ADH-C2 exhibited high activity in BALB/c epididymis and was observed as a discrete zone within duct epithelial cells near the nuclei. This isozyme exhibited no detectable activity in C57BL/6J epididymis extracts or histochemical sections.

Purification and properties of sorbitol dehydrogenase from mouse liver

1. The sorbitol dehydrogenase (L-iditol: NAD oxidoreductase, EC 1.1.1.14) from mouse liver has been purified to homogeneity. 2. The enzyme has a mol. wt of 140,000 and is composed of four identical subunits of mol. wt 35,000. 3. the purified enzyme catalyses both sorbitol oxidation and fructose reduction. 4. It is specific for NAD+ (NADH) and does not function with NADP+ (NADPH). 5. The Michaelis constants for sorbitol, fructose, NAD+ and NADPH are 1.54 and 154 mM, 58.8 and 15 microM, respectively. 6. The enzyme is SH-group reagent sensitive and is strongly inhibited by 1,10-phenanthroline.

Biochemical genetics of aldehyde reductase in the mouse: Ahr-1--a new locus linked to the alcohol dehydrogenase gene complex on chromosome 3

Electrophoretic and activity variants for a liver aldehyde reductase (AHR-A2) among strains of Mus musculus have been used in genetic analyses to demonstrate close linkage between the locus encoding this enzyme (designated Ahr-1) and the alcohol dehydrogenase gene complex on chromosome 3. No recombinants were observed between Adh-3 (encoding alcohol dehydrogenase C2; ADH-C2) and Ahr-1 among 42 backcross animals. Moreover, linkage disequilibrium between these loci was observed among 58 of 60 strains of mice examined and among seven recombinant inbred strains derived from C57BL/6J and BALB/c mice. Liver hexonate dehydrogenase (HDH-A) was electrophoretically invariant among the strains examined. Gel filtration analyses demonstrated that AHR-A2 and HDH-A had native molecular weights of approximately 80,000 and 32,000, respectively. Three-banded allozyme patterns for AHR-A2 in CBA/H x castaneus hybrid animals were consistent with a dimeric subunit structure. Comparative substrate and coenzyme specificities for AHR-A2, HDH-A, and ADH-A2 (liver ADH isozyme) were examined. AHR-A2 exhibited a defined specificity toward p-nitrobenzaldehyde as substrate, whereas the other enzymes exhibited broad specificities toward various aliphatic, aromatic, and monosaccharide aldehydes. It is proposed that Ahr-1 is a product of a gene duplication event during mammalian evolution of the primordial mammalian Adh locus and that considerable divergence in catalytic properties has subsequently occurred.

Linkage of the structural gene for uroporphyrinogen I synthase to markers on mouse chromosome 9 in a cross between feral and inbred mice

The Ups locus has been mapped to mouse chromosome 9 in a three-point cross. The observed gene order is centromere-Ups-15-Mpi-1-22-Mod-1. Ups is unlinked to Lv, which encodes the previous enzyme in the heme biosynthesis pathway. Feral mice collected at Skive, Denmark, have been characterized at several biochemical loci; multiple differences from inbred strains make this a useful stock for linkage analysis.

Mouse alcohol dehydrogenase isozymes: products of closely localized duplicate genes exhibiting divergent kinetic properties

Electrophoretic variants for the stomach isozyme (ADH-C2) and liver isozyme (ADH-A2) of alcohol dehydrogenase in strains of Mus musculus have been used in genetic analyses to demonstrate close linkage between the structural genes (Ahd-3 and Adh-1, respectively) encoding these enzymes. No recombinants were observed between these loci among 126 backcross animals, which places them less than 0.8 centimorgans apart. Previous studies have positioned Adh-3, and a temporal locus (ADh-3t), on chromosome 3 (Holmes, "79; Holmes et al., "80). Kinetic analyses on partially purified preparations of these isozymes have demonstrated widely divergent catalytic properties and inhibitor specificities. The liver isozyme exhibited Michaelis constants that were nearly 3 orders of magnitude lower than the stomach isozyme for various alcohol and aldehyde substrates. Moreover, aminopropyl pyrazole strongly inhibited ADH-A2 (Ki=1.2M), whereas ADH-C2 was insensitive to inhibition under the conditions used. It is proposed that Adh-1 and Adh-3 are products of a recent gene duplication event during mammalian evolution and that considerable divergence in the active sites of these enzymes and the "temporal" genes controlling loci expression in differentiated tissues has subsequently occurred.

Genetic regulation and development of alcohol dehydrogenases in the mouse

Alcohol dehydrogenase (ADH) of mouse tissues was investigated using electrophoretic zymogram methods. ADH activity is widely distributed in mouse tissues and exists as at least two genetic isozymes, designated A2 and C2, which are predominantly localised in liver and stomach respectively. Electrophoretic and activity variants of ADH-C2 among inbred strains of mice have been used to localise the gene encoding this enzyme (Adh-3) and a closely linked temporal locus (Adh-3-t) on chromosome 3 of this organism. Recent developmental studies on ADH isozymes in the mouse have been reviewed.

Genetics and ontogeny of butyryl CoA dehydrogenase in the mouse and linkage of Bcd-1 with Dao-1

A zymogram method has been developed for fatty acyl CoA dehydrogenase and used to examine the electrophoretic properties of butyryl CoA dehydrogenase (BCD) from mouse tissues. A single form of BCD is present in extracts of liver, kidney, heart, and intestine. Ontogenetic, tissue distribution, and subcellular fractionation results are consistent with the mitochondrial origin previously reported for this enzyme. A genetic variant for BCD-1 was used to provide evidence for a locus determining the electrophoretic properties of this enzyme (designated Bcd-1), which is linked to Dao-1 (encoding D-amino acid oxidase).