Michael R. Felder

Ethanol metabolism in Peromyscus genetically deficient in alcohol dehydrogenase

Abstract Ethanol metabolism was compared in two strains of the deermouse, Peromyscus maniculatus . Animals of the Adh N / Adh N strain, which lack liver alcohol dehydrogenase (ADH) activity, eliminated ethanol at a signficantly slower rate (P Adh F / Adh F strain, which have normal liver ADH activity. However, a comparison of the blood ethanol elimination rate (BEER) in the two strains indicated that, at high blood ethanol concentrations, non-ADH mediated pathways may account for as much as two-thirds of normal ethanol elimination in this species. Chronic ethanol consumption induced an elevated BEER in Adh F / Adh F mice but not in AdhN / Adh N mice. This strain difference in response to ethanol feeding suggests that increases in BEER are mediated primarily via the ADH pathway. A microsomal ethanol-oxidizing system (MEOS), independent of ADH and catalase, was shown to exist in microsomal preparations from both strains of P . maniculatus. MEOS activity of naive Adh N / Adh N mice was 2.3-fold higher than that of naive Adh F / Adh H animals. Both strains had a 3-fold greater MEOS activity following chronic ethanol consumption. Contrary to similar investigations in ethanol-fed rats, the alteration in MEOS activity was not accompanied by significant changes in cytochrome P-450, NADPH-cytochrome c reductase or phospholipid. Most importantly, the elevated in vitro MEOS activity of ethanol-fed Adh N / Adh N mice had no significant effect upon BEER. These results suggest caution in attaching physiological significance to the simultaneous, ethanol-induced increase of the in vitro MEOS and of BEER in experimental animals with normal liver ADH activities.

Ethanol metabolism in vivo by the microsomal ethanol-oxidizing system in deermice lacking alcohol dehydrogenase (ADH)

To assess the importance of non-ADH ethanol metabolism, ADH-negative and ADH-positive deermice were fed liquid diets containing ethanol or isocaloric carbohydrate for 2-4 weeks. Blood ethanol disappearance rate increased significantly after chronic ethanol feeding in both strains. Although at low ethanol concentrations (between 5 and 10 mM) there was no significant difference between ethanol-fed and pair-fed control animals, at high ethanol concentrations (between 40 and 70 mM) blood ethanol elimination rates were increased significantly after chronic ethanol feeding in both ADH-positive and ADH-negative animals. There was no significant effect of the catalase inhibitor 3-amino-1,2,4-triazole on the ethanol elimination/rates in both strains. Whereas catalase and ADH activities were not altered after chronic ethanol treatment, the activity of the microsomal ethanol-oxidizing system (MEOS) was enhanced three to four times in both strains, and microsomal cytochrome P-450 content was also increased significantly. When MEOS activity was expressed per cytochrome P-450 content, it was higher in ADH-negative than in ADH-positive animals, and it increased after ethanol administration. When microsomal proteins were separated by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis, ethanol-fed animals had a distinct band which reflected the increase in microsomal cytochrome P-450 content and seemed to reflect a unique form of cytochrome P-450 induced by ethanol. Thus, despite the absence of the ADH pathway, a large amount of ethanol was metabolized by MEOS in ADH-negative deermice; this was associated with increased blood ethanol elimination rates, enhanced MEOS activity, and quantitative and qualitative changes of cytochrome P-450.

Genetic Regulation of Liver Alcohol Dehydrogenase in Peromyscus

Data from genetic crosses of Peromyscus maniculatus and P. polionotus suggest that electrophoretic variants of liver alcohol dehydrogenase are coded by alleles at a single locus. These alleles, designated AdhF, AdhS, and AdhN, determine, respectively, the fast, slow, and not detectable (null) ADH electrophoretic phenotypes. Heterozygotes (AdhF/AdhS) exhibit three bands on zymograms, suggesting a dimeric subunit structure for the enzyme. However, AdhF/AdhN and AdhS/AdhN animals exhibit a single band, suggesting that the AdhN allele does not produce a polypeptide subunit capable of dimerizing into an active molecule. Fast and slow electrophoretic phenotypes exhibit multiple bands which can be converted into single major fast and slow bands, respectively, upon treatment with oxidized or reduced NAD. Addition of NAD also stabilizes both the fast and slow enzyme to heat inactivation at 60 C for at least 30 min.

Properties of rat and mouse β-glucuronidase mRNA and cDNA, including evidence for sequence polymorphism and genetic regulation of mRNA level

cDNA clones containing partial sequences for beta-glucuronidase (beta G) were constructed from rat preputial gland RNA and identified by their ability to selectively hybridize beta G mRNA. One such rat clone was used to isolate several cross-hybridizing clones from a mouse-cDNA library prepared from kidney RNA from androgen-treated animals. Together, the set of mouse clones spans about 2.0 kb of the 2.6-kb beta G mRNA. Using these cDNA clones as probes, a genomic polymorphism for DNA restriction fragment size was found that proved to be genetically linked to the beta G gene complex. A fragment of beta G cDNA was subcloned into a vector carrying an SP6 polymerase promoter to provide a template for the in vitro synthesis of single-stranded RNA complementary to beta G mRNA. This provided an extremely sensitive probe for the assay of beta G mRNA sequences. Using either nick-translated cDNA or transcribed RNA as a hybridization probe, we found that mouse beta G RNA levels are strongly induced by testosterone, and that induction by testosterone is pituitary-dependent. During the lag period preceding induction, during the induction period itself, and during deinduction following removal of testosterone, beta G mRNA levels paralleled rates of beta G synthesis previously measured by in vivo pulse-labelling experiments. Genetic variation in the extent of induction affected either the level of beta G mRNA or its efficiency of translation depending on the strain of mice tested.

High and complementary expression patterns of alcohol and aldehyde dehydrogenases in the gastrointestinal tract: implications for Parkinson's disease.

Parkinsons disease (PD) is a heterogeneous movement disorder characterized by progressive degeneration of dopamine neurons in substantia nigra. We have previously presented genetic evidence for the possible involvement of alcohol and aldehyde dehydrogenases (ADH; ALDH) by identifying genetic variants in ADH1C and ADH4 that associate with PD. The absence of the corresponding mRNA species in the brain led us to the hypothesis that one cause of PD could be defects in the defense systems against toxic aldehydes in the gastrointestinal tract. We investigated cellular expression of Adh1, Adh3, Adh4 and Aldh1 mRNA along the rodent GI tract. Using oligonucleotide in situ hybridization probes, we were able to resolve the specific distribution patterns of closely related members of the ADH family. In both mice and rats, Adh4 is transcribed in the epithelium of tongue, esophagus and stomach, whereas Adh1 was active from stomach to rectum in mice, and in duodenum, colon and rectum in rats. Adh1 and Adh4 mRNAs were present in the mouse gastric mucosa in nonoverlapping patterns, with Adh1 in the gastric glands and Adh4 in the gastric pits. Aldh1 was found in epithelial cells from tongue to jejunum in rats and from esophagus to colon in mice. Adh3 hybridization revealed low mRNA levels in all tissues investigated. The distribution and known physiological functions of the investigated ADHs and Aldh1 are compatible with a role in a defense system, protecting against alcohols, aldehydes and formaldehydes as well as being involved in retinoid metabolism.

Consequences of dietary methyl donor supplements: Is more always better?

Epigenetic mechanisms are now recognized to play roles in disease etiology. Several diseases increasing in frequency are associated with altered DNA methylation. DNA methylation is accomplished through metabolism of methyl donors such as folate, vitamin B12, methionine, betaine (trimethylglycine), and choline. Increased intake of these compounds correlates with decreased neural tube defects, although this mechanism is not well understood. Consumption of these methyl donor pathway components has increased in recent years due to fortification of grains and high supplemental levels of these compounds (e.g. vitamins, energy drinks). Additionally, people with mutations in one of the enzymes that assists in the methyl donor pathway (5-MTHFR) are directed to consume higher amounts of methyl donors to compensate. Recent evidence suggests that high levels of methyl donor intake may also have detrimental effects. Individualized medicine may be necessary to determine the appropriate amounts of methyl donors to be consumed, particularly in women of child bearing age.

Peromyscus as a Mammalian epigenetic model.

Deer mice (Peromyscus) offer an opportunity for studying the effects of natural genetic/epigenetic variation with several advantages over other mammalian models. These advantages include the ability to study natural genetic variation and behaviors not present in other models. Moreover, their life histories in diverse habitats are well studied. Peromyscus resources include genome sequencing in progress, a nascent genetic map, and >90,000 ESTs. Here we review epigenetic studies and relevant areas of research involving Peromyscus models. These include differences in epigenetic control between species and substance effects on behavior. We also present new data on the epigenetic effects of diet on coat-color using a Peromyscus model of agouti overexpression. We suggest that in terms of tying natural genetic variants with environmental effects in producing specific epigenetic effects, Peromyscus models have a great potential.

Peromyscus alcohol dehydrogenase: lack of cross-reacting material in enzyme-negative animals.

Two forms of alcohol dehydrogenase (ADH), coded by allelic genes, have been purified to homogeneity from Peromyscus. Monospecific antisera to the purified enzymes have been raised in rabbits. These antisera fail to detect cross-reacting material in the liver of ADH-negative animals on Ouchterlony plates. Immunotitration of anti-ADH antiserum with ADH in liver extracts from AdhS/AdhS and AdhS/AdhN animals results in identical equivalence points, again suggesting the absence of cross-reacting material coded by the AdhN allele. Over a wide range of anti-ADH antiserum dilutions, radiolabeled protein was not immunoprecipitable from liver extracts of AdhN/AdhN animals. These immunochemical tests, in conjunction with previous studies, suggest that the AdhN allele in Peromyscus does not produce inactive polypeptide in normal levels that bears immunological determinants similar to those of the fast and slow ADH isozymes.

Alcohol dehydrogenase (ADH) independent ethanol metabolism in deermice lacking ADH.

To assess the importance of non-ADH ethanol metabolism, ADH-negative (ADH-) and ADH-positive (ADH+) deermice were fed for 2-4 weeks liquid diets containing ethanol or isocaloric carbohydrate. They consumed progressively increasing amounts of ethanol. Blood ethanol clearance (BEC) increased significantly in both strains. It remained almost unchanged at low ethanol concentrations (5-10 mM), but at high levels (40-70 mM) BEC was strikingly increased with significant differences between ethanol-fed and control animals. Kinetics were consistent with the activity of a non-ADH high Km system such as the microsomal ethanol-oxidizing system (MEOS). Naive ADH- had a more active MEOS and more abundant SER than naive ADH+. After ethanol feeding, MEOS was increased 3-4 times in both strains. There was striking proliferation of SER and cytochrome P-450 was enhanced significantly. Expressed per P-450, MEOS activity was higher in ADH- than ADH+. Thus despite absence of ADH, ADH- deermice can consume large amounts of ethanol: this is associated with increased BEC, SER proliferation, enhanced MEOS activity and quantitative and qualitative changes of cytochrome P-450.

Peromyscus (deer mice) as developmental models

Deer mice (Peromyscus) are the most common native North American mammals, and exhibit great natural genetic variation. Wild‐derived stocks from a number of populations are available from the Peromyscus Genetic Stock Center (PGSC). The PGSC also houses a number of natural variants and mutants (many of which appear to differ from Mus). These include metabolic, coat‐color/pattern, neurological, and other morphological variants/mutants. Nearly all these mutants are on a common genetic background, the Peromyscus maniculatus BW stock. Peromyscus are also superior behavior models in areas such as repetitive behavior and pair‐bonding effects, as multiple species are monogamous. While Peromyscus development generally resembles that of Mus and Rattus, prenatal stages have not been as thoroughly studied, and there appear to be intriguing differences (e.g., longer time spent at the two‐cell stage). Development is greatly perturbed in crosses between P. maniculatus (BW) and Peromyscus polionotus (PO). BW females crossed to PO males produce growth‐restricted, but otherwise healthy, fertile offspring which allows for genetic analyses of the many traits that differ between these two species. PO females crossed to BW males produce overgrown but severely dysmorphic conceptuses that rarely survive to late gestation. There are likely many more uses for these animals as developmental models than we have described here. Peromyscus models can now be more fully exploited due to the emerging genetic (full linkage map), genomic (genomes of four stocks have been sequenced) and reproductive resources.