Isoelectric focusing studies of aldehyde dehydrogenases from mouse tissues: variant phenotypes of liver, stomach and testis isozymes

Isoelectric focusing techniques (IEF) were used to examine the tissue distribution and genetic variability of aldehyde dehydrogenases (AHDs) from inbred strains of mice. Twelve zones of AHD activity were resolved which were differentially distributed between tissues. Liver extracts exhibited highest activity for most enzymes, with the exception of isozymes found in stomach (AHD-4) and testis (AHD-4 and AHD-6). Genetic variants for AHD-1 (liver mitochondrial isozyme) and AHD-4 (stomach isozyme) were examined from inbred strains and F1 hybrid animals. The results were consistent with dimeric subunit structures (designated as A2 and D2 isozymes respectively). IEF patterns for activity variants of testis-specific AHD-6 were identical, with 3-banded phenotypes being observed. pI values for the AHD forms as well as for aldehyde oxidase and xanthine oxidase isozymes, which stain in the absence of coenzyme, were reported.

Biochemical and genetic studies on mouse aldehyde dehydrogenases

Aldehyde dehydrogenase (AHD) exists as isozymes which are differentially distributed among tissues and subcellular fractions of mouse tissues. Genetic variants for liver mitochondrial (AHD-1) and cytoplasmic (AHD-2) isozymes have been used to map the responsible loci (Ahd-1 and Ahd-2) on chromosomes 4 and 19 respectively. Evidence for a regulatory locus (Ahd-3r) controlling the inducibility of the mouse liver microsomal isozyme (AHD-3) has also been obtained. More recent studies have described genetic and biochemical evidence for three additional AHD isozymes: a stomach isozyme (AHD-4); another liver mitochondrial enzyme (AHD-5); and a testis isozyme (AHD-6). Genetic analyses have indicated that AHD-4 and AHD-6 are encoded by distinct but closely linked loci on the mouse genome (Ahd-4 and Ahd-6), which segregate independently of Ahd-1 and Ahd-2. Liver mitochondrial isozymes, AHD-1 and AHD-5, have been purified to homogeneity using affinity chromatography. The very high affinity of AHD-5 for acetaldehyde suggests that this enzyme is predominantly responsible for acetaldehyde oxidation in mouse liver mitochondria.

Electrophoretic analyses of alcohol dehydrogenase, aldehyde dehydrogenase, aldehyde reductase, aldehyde oxidase and xanthine oxidase from horse tissues

Cellulose acetate zymograms of alcohol dehydrogenase (ADH), aldehyde dehydrogenase (AHD), aldehyde reductase (AHR), aldehyde oxidase (AOX) and xanthine oxidase (XOX) extracted from horse tissues were examined. Five ADH isozymes were resolved: three corresponded to the previously reported class I ADHs (EE, ES and SS) (Theorell, 1969); a single form of class II ADH (designated ADH-C2) and of class III ADH (designated ADH-B2) were also observed. The latter isozyme was widely distributed in horse tissues whereas the other enzymes were found predominantly in liver. Four AHD isozymes were differentially distributed in subcellular preparations of horse liver: AHD-1 (large granules); AHD-3 (small granules); and AHD-2, AHD-4 (cytoplasm). AHD-1 was more widely distributed among the horse tissues examined. Liver represented the major source of activity for most AHDs. A single additional form of NADPH-dependent AHR activity (identified as hexonate dehydrogenase), other than the ADHs previously described, was observed in horse liver. Single forms of AOX and XOX were observed in horse tissue extracts, with highest activities in liver.

Purification and molecular properties of a Class II alcohol dehydrogenase (ADH-C2) from horse liver

An alcohol dehydrogenase (ADH) from horse liver was purified by ion-exchange and affinity chromatography. The enzyme (designated ADH-C2), is a dimer with a similar subunit size (47,300 mol. wt), as determined by SDS-polyacrylamide gel electrophoresis, to other mammalian ADHs. Zinc analyses and 1,10 phenanthroline inhibition studies indicated that each subunit contained 2 g atoms of zinc, with at least one involved catalytically. The enzyme exhibited similar kinetic properties to human pi-ADH and mouse ADH-C2, previously classified as class II ADHs [Vallee and Bazzone (1983) Isozymes, Vol. 8, pp. 219-244; Algar et al. (1983) Eur. J. Biochem. 137, 139-147] but differed in most respects from the extensively investigated horse Class I ADHs; EE, ES and SS. Horse ADH-C2 exhibited a Km value for ethanol of 42 mM and a broad substrate specificity, with Km values decreasing dramatically with an increase in chain length. The enzyme was much less sensitive to pyrazole inhibition (by at least 3 orders of magnitude) as compared with the Class I ADHs.

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.

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.

Genetics and ontogeny of aldehyde dehydrogenase isozymes in th mouse: evidence for a locus controlling the inducibility of the liver microsomal isozyme

Variation in the inducibility of the liver microsomal isozyme of aldehyde dehydrogenase (designated AHD-Cy) by phenobarbital administration was observed among inbred strains an linkage testing stocks of Mus musculus. The phenotypes were inherited in a normal Mendelian fashion with two alleles showing codominance at a proposed regulatory locus (designated Ahd-3r). Strain variation was also observed for the induction of liver AHD-Cy by 17 -Beta-oestradiol administration to ovarectimized female mice. Moreover, this enzyme was elevated in activity by the administration of high (nonphysiological) levels of progesterone. Development studies showed that the liver and kidney AHD-Cy isozyme exhibited low activities in late-stage fetal and neonatal mice and reached adult levels by approximately 6 weeks of age.

Lens opacity: a new gene for congenital cataract on chromosome 10 of the mouse

Mouse mutant genes which result in defects similar to those of medical importance in man may be of value as models for the study of the defect concerned. We report here a new gene causing congenital cataract in the mouse, which may be useful in the understanding of cataract in man.

A further point of interest is that Kratochvilova & Ehling (1979) have recently developed a new method of measuring increased mutation rates in the mouse, by examining offspring of animals treated with mutagens for the presence of cataracts due to mutant genes. For the purposes of this test it is valuable to have information on the number and map position of loci which can mutate to give cataracts.

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).

Genetics of aldehyde dehydrogenase isozymes in the mouse: evidence for multiple loci and localization of Ahd-2 on chromosome 19

Electrophoretic and activity variation of the cytoplasmic isozyme of aldehyde dehydrogenase (designated AHD-B4) was observed among inbred strains and Harwell linkage-testing stocks of Mus musculus. The phenotypes are inherited in a normal Mendelian fashion, with two alleles showing co-dominant expression at a single locus (Ahd-2). The locus was shown to segregate independently of Ahd-1 (encoding the mitochondrial AHD-A2 isozymes on chromosome 4; HOLMES 1978). Linkage data of Ahd-2 with ep (pale ears), ru (ruby eyes) and bm (brachymorphic) suggest that it is localized near the centromeric end of chromosome 19. Electrophoretic evidence for a third AHD isozyme (designated AHD-Cy), which is predominantly localized in the liver microsomal fraction, is also presented.

Genetic variability of alcohol dehydrogenase among Australian Drosophila species: correlation of ADH biochemical phenotype with ethanol resource utilization

Alcohol dehydrogenase (ADH) activities, electrophoretic phenotypes, and the extent of ethanol resource utilization are compared for three groups of species distinguishable on ecological criteria: 1) the cosmopolitan species D. melanogaster, a frequent inhabitant of wineries; 2) fruit-baited species of the typically Australian subgenus Scaptodrosophila: D. lativittata, D. nitidithorax and D. howensis; and 3) Scaptodrosophila species not attracted to fermented-fruit baits being collected by sweeping in temperate rain forests (D. inornata, D. collessi) or from Hibiscus flowers (D. hibisci). D. melanogaster showed the highest levels of ADH activity and an electrophoretic polymorphism with two active allelic forms, while group 2) species showed intermediate ADH activities and polymorphisms, which were consistent with "high activity" and "low activity" allelic forms in natural populations of these species, and group 3) species showed only "low activity" forms. Ethanol resource utilization follows the same sequence, being 1 greater than 2 greater than 3 (D. howensis and D. collessi were not tested). Therefore the species considered show an association of ADH biochemical phenotype, laboratory ethanol utilization, and resources utilized.

Genetic regulation of alcohol dehydrogenase, aldehyde dehydrogenase and aldehyde oxidase isozymes in the mouse

Electrophoretic and activity variants for the C2 isozyme of alcohol dehydrogenase (ADH-C2), the mitochondrial isozyme of aldehyde dehydrogenase (AHD-A2) and aldehyde oxidase isozymes (AOX-1; AOX-2) in inbred strains of Mus musculus were used to map the genes encoding these enzymes on the mouse genome. Adh-3 (encoding ADH-C2) was localized on chromosome 3 and was closely linked to a cis-acting regulator locus (Adh-3-t), which determined ADH-C2 activity in male reproductive tissues. Ahd-1 (encoding AHD-A2) was found on chromosome 4 near Gpd-1 (encoding the liver isozyme of glucose-6-phosphate dehydrogenase), whereas the aldehyde oxidase loci (Aox-1, Aox-2) were closely linked on chromosomes 1 near Id-1 (encoding isocitrate dehydrogenase).

Electrophoretic analyses of lactate dehydrogenase C4 in testes and vesicular glands of normal and male sterile translocation mice

Lactate dehydrogenase (LDH) C, activity was observed in testis extracts from normal mice but was progressively reduced in mice carrying the male-sterile translocations T31H, T32H, T37H, T38H, T40H and T42H, with no detectable activity being observed in the last two mice. None of the vesicular gland extracts from these male-steriles showed LDH-C4 activity, unlike normal mice. The differential LDH-C4 activity in male-sterile testes is interpreted as reflecting the varying stages of the spermatogenic defect during meiosis. In general, early meiotic defects exhibited no LDH-C4 activity whereas late stage (usually after metaphase-1 stage) defect animals exhibited some activity. The results also provide evidence for contaminating sperm being the source of normal vesicular gland LDH-C4 activity.

Genetics, ontogeny, and testosterone inducibility of aldehyde oxidase isozymes in the mouse: evidence for two genetic loci (Aox-I and Aox-2) closely linked on chromosome 1

"Null"-activity and low-activity variants for the liver supernatant isozymes of aldehyde oxidase (designated AOX-1 and AOX-2) were observed in inbred strains and in Harwell linkage testing stocks of Mus musculus. The genetic loci determining the activity of these isozymes (designated Aox-1 and Aox-2, respecitively) are closely linked on chromosome 1 near Id-1 (encoding the soluble isozyme of isocitrate dehydrogenase). Linkage data of Aox-1 with Id-1 and Dip-1 (encoding a kidney peptidase) demonstrated that this gene coincides with or is closely linked to Aox (Watson et al., 1972). Ontogenetic analyses demonstrated that liver AOX-1 appeared just before birth and increased in activity during postnatal development, whereas liver AOX-2 was observed only during postnatal development. Adult male livers exhibited higher AOX-1 and AOX-2 activities than adult female livers. Both isozymes were significantly reduced in activity by castration of adult males and increased following testosterone administration to castrated males and normal female mice.

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

An electrophoretic variant previously reported for the stomach isozyme of alcohol dehydrogenase (ADH-C2) in inbred strains of Mus musculus (Holmes, 1977) has been used to localize the gene encoding this enzyme (Adh-3) on chromosome 3 near Va (varitint) (9.6 +/- 3.6% recombinants). Genetic variation of ADH-C2 activity in male and female reproductive tissues among inbred strains and Harwell linkage testing stocks was also observed. Reproductive tissue ADH-C2 phenotypes were inherited in a normal Mendelian fashion among F2 progeny of an F1 (LII x C57BL/Go) x C57BL/Go backcross as though controlled by a single cis-acting regulator locus (designated Adt-1) with two alleles: Adt-1a (presence of ADH-C2) and Adt-1b (absence or low activity of ADH-C2). No recombinants were observed among 73 progeny or among 13 inbred strains and six Harwell linkage testing stocks of mice, indicating that Adh-3 and Adt-1 are closely linked or identical genes. A single recombinant phenotype was observed in Peru-Coppock mice, suggesting that they are separate genes. Ontogenetic analyses demonstrated that ADH-B2 is present throughout development from late fetal stages in stomach, liver, and kidney; similar results were found for ADH-C2 in developing kidney and stomach extracts, whereas ADH-A2 exhibited high activity in liver extracts after 3 weeks of age in both sexes and in male kidney extracts after 6 weeks.

Genetics and ontogeny of aldehyde dehydrogenase isozymes in the mouse: localization of Ahd-1 encoding the mitochondrial isozyme on chromosome 4

Electrophoretic variants for the mitochondrial isozyme of aldehyde dehydrogenase (AHD) have been observed in inbred strains and in Harwell linkage testing stocks of Mus musculus. F1 (LVC X C57BL/Go) mice showed a codominant allele three-bounded phenotype, which suggests a dimeric subunit structure (designated AHD-A2). The anodal-migrating supernatant isozyme of AHD was electrophoretically invariant among the 23 inbred strains and stocks examined. The genetic locus encoding AHD-A2 (suggested name Ahd-1) is localized on chromosome 4 and was mapped close to je (jerker) and Gpd-1 (encoding the liver and kidney isoenzyme of glucose-6-phosphate dehydrogenase). Ontogenetic analyses demonstrated that both AHD isozymes exhibited low activity in late fetal and early neonatal liver and kidney extracts, and reached adult levels within 3 weeks of birth.

Genetics of hydroxyacid oxidase isozymes in the mouse: localisation of Hao-2 on linkage group XVI

Electrophoretic variants of individual isozymes of L-alpha-hydroxyacid oxidase (HAOX-B4) and amylase (AMY-A) in an Asian subspecies of mouse, Mus musculus castaneus, have been used to localise the gene encoding the HAOX B subunit. The structural gene loci for these isozymes (Hao-2 and Amy-1) are apparently linked (4.9 +/- 2.4 per cent recombinants) in this organism, which places Hao-2 on linkage group XVI, since previous studies by Eicher and co-workers (1976) have localised Amy-1 on this chromosome.

Genetic variation, cellular distribution and ontogeny of sorbitol dehydrogenase and alcohol dehydrogenase isozymes in male reproductive tissues of the mouse

Cellulose acetate zymograms of alcohol dehydrogenase (ADH) and sorbitol dehydrogenase (SDH) extracted from male reproductive tissues of inbred mice were examined. ADH isozymes were differentially distributed in these tissues of C3H/He mice; ADH-B2 was observed in all tissues and testis cellular preparations examined; ADH-C2 was localized predominantly in the epididymis but was also present in the seminal vesicles, coagulating gland, and prostate gland. SDH was broadly distributed in these tissues but exhibited highest activities in the seminal vesicles, coagulating glands, and germinal cells of mature testes. Genetic variants for ADH-C2 and SDH provided evidence for (1) the identity of a second form of SDH in epididymis with ADH-C2; (2) the genetic identity of kidney, seminal vesicle, and testis SDH; and (3) the gentic identity of stomach and epididymal ADH-C2. Developmental changes in testis and epididymal ADH isozymes during maturation were examined. ADH-C2 appeared in the mature epididymis whereas ADH-B2 exhibited no major changes in activity in testis and epididymis during development.

Purification and properties of the native form of rabbit liver aldolase. Evidence for proteolytic modification after tissue extraction

Aldolase was purified from rabbit liver by affinity-elution chromatography. By taking precautions to avoid rupture of lysosomes during the isolation procedure, a stable form of liver aldolase was obtained. The stable form of the enzyme had a specific activity with respect to fructose 1,6-bisphosphate cleavage of 20-28 mumol/min per mg of protein and a fructose 1,6-bisphosphate cleavage of 20-28mumol/min per mg of protein and a frutose 1,6-bisphosphate/fructose 1-phosphate activity ratio of 4. It was distinguishable from rabbit muscle aldolase, as previously isolated, on the basis of its electrophoretic mobility and N-terminal analysis. Muscle and liver aldolases were immunologically distinct. The stable liver aldolase was degraded with a lysosomal extract to a form with catalytic properties resembling those reported for aldolase B4. It is postulated that liver aldolase prepared by previously described methods has been modified by proteolysis and does not constitute the native form of the enzyme.