Mechanism of aldehyde oxidation catalyzed by horse liver alcohol dehydrogenase

The mechanism of oxidation of benzaldehyde to benzoic acid catalyzed by horse liver alcohol dehydrogenase (HLADH) has been investigated using the HLADH structure at 2.1 A resolution with NAD+ and pentafluorobenzyl alcohol in the active site [Ramaswamy et al. (1994) Biochemistry 33,5230-5237]. Constructs for molecular dynamics (MD) investigations with HLADH were obtained by a best-fit superimposition of benzaldehyde or its hydrate on the pentafluorobenzyl alcohol bound to the active site Zn(II)ion. Equilibrium bond lengths, angles, and dihedral parameters for Zn(II) bonding residues His67, Cys46, and Cys174 were obtained from small-molecule X-ray crystal structures and an ab initio-derived parameterization of zinc in HLADH [Ryde, U. (1995) Proteins: Struct., Funct., Genet. 21,40-56]. Dynamic simulations in CHARMM were carried out on the following three constructs to 100 ps: (MD1) enzyme with NAD+, benzaldehyde, and zinc-ligated HO-in the active site; (MD2) enzyme with NAD+ and hydrated benzaldehyde monoanion bound to zinc via the pro-R oxygen, with a proton residing on the pro-S oxygen; and (MD3) enzyme with NAD+ and hydrated benzaldehyde monoanion bound to zinc via the pro-S oxygen, with a proton residing on the pro-R oxygen. Analyses were done of 800 sample conformations taken in the last 40 ps of dynamics. Structures from MD1 and MD3 were used to define the initial spatial arrangements of reactive functionalities for semiempirical PM3 calculations. Using PM3, model systems were calculated of ground states and some transition states for aldehyde hydration, hydride transfer, and subsequent proton shuttling. With benzaldehyde and zinc-bound hydroxide ion in the active site, the oxygen of Zn(II)-OH resided at a distance of 2.8-5.5 A from the aldehyde carbonyl carbon during the dynamics simulation. This may be compared to the PM3 transition state for attack of the Zn(II)-OH oxygen on the benzaldehyde carbonyl carbon, which has an O...C distance of 1.877 A. HLADH catalysis of the aldehyde hydration would require very little motion aside from that in the ground state. Two simulations of benzaldehyde hydrate ligated to zinc (MD2 and MD3) both showed close approach of the aldehyde hydrate hydrogen to NAD+C4, varying from 2.3 to 3.3 A, seemingly favorable for the hydride transfer reaction. The MD2 configuration does not allow proton shuttling. On the other hand, when the pro-S oxygen is ligated to zinc (MD3), the proton on the pro-R oxygen averages 2.09 A from the hydroxyl oxygen of Ser48 such that initiation of shuttling of protons via Ser48 to the ribose 2'-hydroxyl oxygen to the 3'-hydroxyl oxygen to His51 nitrogen is sterically favorable. PM3 calculations suggest that this proton shuttle represents a stepwise reaction which occurs subsequent to hydride transfer. The PM3 transition state for hydride transfer based on the MD3 configuration has the transferring hydride 1.476 A from C4 of NAD+ and 1.433 A from the aldehyde alpha-carbon.     

Meta-analysis of the effects of alcohol dehydrogenase genotype on alcohol dependence and alcoholic liver disease

The purpose of this paper is to assemble and evaluate existing data on the effect of genetic variation in ADH2 and ADH3 on the risk of alcohol dependence, and on the risk of alcoholic liver disease. Calculations of odds ratios and their confidence limits, and tests for heterogeneity of the results from the available studies, have been performed. It is clear that possession of the ADH2-2 allele decreases the risk of alcohol dependence, but it increases the risk of alcoholic liver disease among alcoholics. ADH3 variation also has significant effects on alcohol dependence, which may be due to linkage to ADH2; the ADH3 effect differs significantly between Asian and European subjects. Therefore ADH genotype has substantial effects on risk of alcohol dependence and alcoholic liver disease, but more work is needed on the generalizability of these findings to non-Asian populations, and on possible mechanisms.     

Effect of methylmercury on the ethanol elimination from the blood and the activity of alcohol dehydrogenase

In an attempt to assess the effects of methylmercury on ethanol metabolism, Sprague-Dawley rats were treated with a daily dose (10 mg/kg i.p.) of methylmercuric chloride for 2 consecutive days and given a test dose (0.4 g/kgi.v.) of ethanol 24 hr after the last treatment. Blood ethanol levels were measured using gaschromatography by the direct introduction of blood samples into the sample vaporizing apparatus attached to the chromatograph. While treatment with methylmercury elicited a slight retardation in the ethanol elimination from the blood during 30 to 90 min, methylmercury did not essentially alter ethanol metabolism. There was no significant change in hepatic alcohol dehydrogenase activity of methylmercury-treated rats. By contrast, the activity of alcohol dehydrogenase purified from liver or yeast was remarkably inhibited by methyl-mercury and the type of inhibition proved to be non-competitive. Moreover, the inhibited activity was reactivated easily by sulfhydryl agents. From these results, it is conceivable that methylmercury has little influence on ethanol metabolism in vivo because of its non-specific binding with sulfhydryl groups in the organism.     

Helicobacter pylori infection decreases gastric alcohol dehydrogenase activity and first-pass metabolism of ethanol in man

Current world stockpiles of nuclear weapons and the status of treaties for nuclear disarmament and the ultimate elimination of nuclear weapons are summarised. The need for including stockpiles of civil plutonium in a programme for ending production and disposing of fissile materials is emphasized, and the ultimate difficulty of disposing of the last few nuclear weapons discussed.     

Optical spectroscopy of nicotinoprotein alcohol dehydrogenase from Amycolatopsis methanolica: a comparison with horse liver alcohol dehydrogenase and UDP-galactose epimerase

The NADH absorbance spectrum of nicotinoprotein (NADH-containing) alcohol dehydrogenase from Amycolatopsis methanolica has a maximum at 326 nm. Reduced enzyme-bound pyridine dinucleotide could be reversibly oxidized by acetaldehyde. The fluorescence excitation spectrum for NADH bound to the enzyme has a maximum at 325 nm. Upon excitation at 290 nm, energy transfer from tryptophan to enzyme-bound NADH was negligible. The fluorescence emission spectrum (excitation at 325 nm) for NADH bound to the enzyme has a maximum at 422 nm. The fluorescence intensity is enhanced by a factor of 3 upon binding of isobutyramide (Kd = 59 microM). Isobutyramide acts as competitive inhibitor (Ki = 46 microM) with respect to the electron acceptor NDMA (N,N-dimethyl-p-nitrosoaniline), which binds to the enzyme containing the reduced cofactor. The nonreactive substrate analogue trifluoroethanol acts as a competitive inhibitor with respect to the substrate ethanol (Ki = 1.6 microM), which binds to the enzyme containing the oxidized cofactor. Far-UV circular dichroism spectra of the enzyme containing NADH and the enzyme containing NAD+ were identical, indicating that no major conformational changes occur upon oxidation or reduction of the cofactor. Near-UV circular dichroism spectra of NADH bound to the enzyme have a minimum at 323 nm (Deltaepsilon = -8.6 M-1 cm-1). The fluorescence anisotropy decay of enzyme-bound NADH showed no rotational freedom of the NADH cofactor. This implies a rigid environment as well as lack of motion of the fluorophore. The average fluorescence lifetime of NADH bound to the enzyme is 0.29 ns at 20 degreesC and could be resolved into at least three components (in the range 0.13-0.96 ns). Upon binding of isobutyramide to the enzyme-containing NADH, the average excited-state lifetime increased to 1.02 ns and could be resolved into two components (0.37 and 1.11 ns). The optical spectra of NADH bound to nicotinoprotein alcohol dehydrogenase have blue-shifted maxima compared to other NADH-dehydrogenase complexes, but comparable to that observed for NADH bound to horse liver alcohol dehydrogenase. The fluorescence lifetime of NADH bound to the nicotinoprotein is very short compared to enzyme-bound NADH complexes, also compared to NADH bound to horse liver alcohol dehydrogenase. The cofactor-protein interaction in the nicotinoprotein alcohol dehydrogenase active site is more rigid and apolar than that in horse liver alcohol dehydrogenase. The optical properties of NADH bound to nicotinoprotein alcohol dehydrogenase differ considerably from NADH (tightly) bound to UDP-galactose epimerase from Escherichia coli. This indicates that although both enzymes have NAD(H) as nonexchangeable cofactor, the NADH binding sites are quite different.     

Genotypes of alcohol dehydrogenase and aldehyde dehydrogenase and their significance for alcohol sensitivity

Genotypes of alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) loci were determined, using allele specific oligonucleotides. Gene frequencies of ADH2(1) and ADH2(2) were 0.29 and 0.71, respectively, in the Japanese control group. No significant difference was found in the ADH2 genotype between the patients and the control group. Gene frequency of ALDH2(1) and ALDH2(2) were 0.65 and 0.35 in the control group, while 0.93 and 0.07, respectively in the patient group. Most of the patients, 20 out of 23, were homozygous Caucasian type. All individuals with homozygous atypical ALDH2(2)/ALDH2(2) and most of those with heterozygous atypical ALDH2(1)/ALDH2(1) were alcohol flushers, while all of the usual ALDH2(1)/ALDH2(1) were nonflushers. The results indicate that Japanese with the atypical ALDH2(2) allele are at a much lower risk in developing alcoholic liver disease than those with usual ALDH2(1)/ALDH2(1), presumably due to their sensitivity to alcohol intoxication.     

Effect of sex hormones on rat liver cytosolic alcohol dehydrogenase activity

A large public service organization was concerned with protection of its customers against hazards associated with furniture tipping in public use concourses. Because no injury experience was available for analysis, hazard patterns for tipping accidents were developed from an observational study of public interaction with the furniture. For each hazard pattern, anthropometric models were used to find the probability of the furniture being safe from tipping, for different age and gender combinations. A safety criterion was developed from this modeling, and used to change the weights of some furniture items to resist tipping. These modifications have now been implemented and are in widespread use. Implications for broader application of these models to the development of valid tipping standards for furniture are discussed.     

Kinetics of coupled reactions catalyzed by aspartate aminotransferase and glutamate dehydrogenase

Liver mitochondrial aspartate aminotransferase and glutamate dehydrogenase catalyze following sequence of reactions: see formula in text. In the presence of a slight excess of dehydrogenase, the time course of NADPH oxidation resulting from the overall reaction goes through a lag phase and reaches a linear phase. The slopes of the linear part of this curve is a linear function of transaminase concentration. At high concentration (approximately or equal to 10 microM) of both enzymes the lag phase, as observed after rapid mixing of the two enzymes in a Durrum stopped-flow spectrophotometer, is shorter, than that predicted from the kinetic parameters determined for the separate reactions catalyzed by each enzyme.     

Consumption of alcohol in the presence of hepatitis C virus is an additive risk for liver damage

BACKGROUND: Whether alcohol consumption influences the development of hepatitis C in the presence of a latent infection needs to be determined. METHODS: The interaction between alcohol intake and hepatitis C virus infection with regard to development of liver injury was cross-sectionally investigated for 399 inhabitants of a town in Nagano Prefecture, Japan. In this town, the prevalence of hepatitis C virus infection is 32.4%. RESULTS: The levels of indicators of liver function were significantly higher among subjects of both sexes who carried the antibody to hepatitis C virus than among those without the antibody. Among men, higher levels of liver function were more frequent among alcohol drinkers than among nondrinkers, suggesting that alcohol consumption may aid in the development of liver injury, even among subjects with a latent hepatitis C virus infection. gamma-Glutamyl transpeptidase activity was more sharply increased in relation to alcohol intake among subjects with hepatitis C virus infection than among those without it, suggesting that the presence of infection will influence alcohol-induced liver damage. CONCLUSION: Alcohol consumption and a concomitant hepatitis C virus infection apparently facilitate the development of hepatitis.     

Degradation of tetrahydrofurfuryl alcohol by Ralstonia eutropha is initiated by an inducible pyrroloquinoline quinone-dependent alcohol dehydrogenase

An organism tentatively identified as Ralstonia eutropha was isolated from enrichment cultures containing tetrahydrofurfuryl alcohol (THFA) as the sole source of carbon and energy. The strain was able to tolerate up to 200 mM THFA in mineral salt medium. The degradation was initiated by an inducible ferricyanide-dependent alcohol dehydrogenase (ADH) which was detected in the soluble fraction of cell extracts. The enzyme catalyzed the oxidation of THFA to the corresponding tetrahydrofuran-2-carboxylic acid. Studies with n-pentanol as the substrate revealed that the corresponding aldehyde was released as a free intermediate. The enzyme was purified 211-fold to apparent homogeneity and could be identified as a quinohemoprotein containing one pyrroloquinoline quinone and one covalently bound heme c per monomer. It was a monomer of 73 kDa and had an isoelectric point of 9.1. A broad substrate spectrum was obtained for the enzyme, which converted different primary alcohols, starting from C2 compounds, secondary alcohols, diols, polyethylene glycol 6000, and aldehydes, including formaldehyde. A sequence identity of 65% with a quinohemoprotein ADH from Comamonas testosteroni was found by comparing 36 N-terminal amino acids. The ferricyanide-dependent ADH activity was induced during growth on different alcohols except ethanol. In addition to this activity, an NAD-dependent ADH was present depending on the alcohol used as the carbon source.     

乙醇-碘化钾-硫酸铵体系萃取分离和富集铱

研究发现硫酸铵能使乙醇的水溶液分成两相,在分相过程中,Ir Ⅳ与碘化钾生成的IrI62-与质子化乙醇(C2H5OH2+)形成的缔合物[IrI62-][C2H5OH2+]2能被乙醇相完全萃取。当乙醇、碘化钾和硫酸铵的浓度分别为30%(V/V)、3.5×10-3mol/L、0.3 g/mL,pH 3时,Ir Ⅳ的萃取率达到100%,而Fe3+、Al3+、Cr3+、Pb2+、Co2+、Ni2+、Zn2+、Mn2+和Ga3+基本不被萃取,实现了Ir Ⅳ与上述金属离子的分离。该方法对合成水样中的Ir Ⅳ进行了分离和测定,在微量铱的分离和富集分析中有一定的实用价值。     

Induction of apoptosis in liver tumors by the monoterpene perillyl alcohol

The monoterpenes d-limonene and perillyl alcohol (POH) inhibit the growth of mammary tumors. In this investigation we tested whether POH is also effective in reducing liver tumor growth. Diethylnitrosamine was used to induce liver tumors in male Fischer 344 rats. Two weeks after diethylnitrosamine exposure was discontinued, the animals were divided into POH-treated and untreated groups. The mean liver tumor weight for the POH-treated rats after 19 weeks of POH treatment was 10-fold less than that for the untreated animals. POH did not influence tumor cell proliferation but increased the apoptotic index approximately 10-fold. The mRNA levels for the mannose 6-phosphate/insulin-like growth factor II receptor and the transforming growth factor beta type I, II, and III receptors were also significantly increased in the liver tumors from the POH-treated animals when compared to the corresponding receptor mRNA levels in the normal tissue surrounding the tumors and in the tumors of untreated animals. These results demonstrate that POH does not promote the formation of liver tumors, but rather inhibits their growth by enhancing tumor cell loss through apoptosis.     

Mechanism of NADH transfer between alcohol dehydrogenase and glyceraldehyde-3-phosphate dehydrogenase

To investigate the correlation between neural activity and intracellular Ca2+ ([Ca2+]i) mobilization in immature and adult brain during ischemia (hypoxia and glucose deprivation) and deprivation of glucose, hippocampal slices were prepared from 7-, 10-day-old and adult rats. Population spikes (PS) and antidromic responses (AR) were recorded in the pyramidal cell layer of the CA1 area as an index of neural function. [Ca2+]i mobilization of the stratum radiatum in the CA1 area was measured using the fluorescent dye fura-2 AM. The rise in [Ca2+]i occurred earlier in the adult animal and the decay times for the orthodromic PS and antidromic responses were shorter in the adult during ischemia. The field potentials and antidromic responses decreased substantially prior to the elevation of [Ca2+]i in both developing and adult brains. Furthermore, ATP levels decreased substantially before the elevation of [Ca2+]i during ischemia. These results suggest that neural activity and intracellular Ca2+ homeostasis in the immature rats brain are more resistant to energy failure than adult rats and that neuronal activity in the developing and adult brain is impaired initially by energy depletion during ischemia. In the immature animal, during glucose deprivation, the antidromic responses were slowly decayed or even failed to extinguish and [Ca2+]i levels were maintained for a longer period or even failed to rise in spite of the rapid loss of PS. Furthermore, ATP levels were well preserved at the time of PS loss. These results agree well with our previous reports showing that glucose plays an important role in the preservation of synaptic transmission in addition to its major function as an energy substrate.     

Assay of insulin receptors in mouse brain

We previously demonstrated that mouse adrenergic system undergoes age-related impairments which can be reversed by grafting thymus into old animals. Recently, our attention is devoted to brain insulin receptors (InsRs), because of their possible involvement in neuromodulation of monoaminergic systems. The paucity of information on brain InsRs in general, and on mouse in particular, prompted us to look for methods by which brain InsR characteristics can be determined accurately, before beginning a study on possible age-dependent modifications of this receptor system and their eventual recovery by thymus graft. Brain insulin receptor characteristics were studied in a group of young Balb/c-nu mice by binding competition experiments, set up incubating fresh brain membranes with a constant amount of 125I-insulin in presence of increasing concentrations of cold insulin. Experimental data were analysed using both one-site and two-site models. Comparison of results demonstrates that curvilinear Scatchard plot of brain InsRs is indicative of the presence of two binding sites with high and low affinity, respectively. Data also shows that density and affinity of the high affinity receptor subset can be determined accurately, while the low affinity receptor subpopulation presents a high degree of interindividual variability for both density and affinity. It can be concluded that this method of determination of InsR characteristics can be safely used to deepen the study of thymus graft-induced recovery of age-related modifications of brain InsR system.     

Gene-enzyme alcohol dehydrogenase system and adaptability in Drosophila melanogaster

As follows from the experiments on the genotypic related populations of Drosophila melanogaster with different frequency of ADH allozymes selection for postponement of ageing and resistance to hypothermia lead to saturation of population with S-allozyme ADH, and genotypic adaptation to ethanol-to increasing of frequency of F-allozyme. It is supposed that genotypic adaptation is realized by selection of specimens with the most favourable alleles of genes. At the same time ontogenetic adaptation is accompanied by biochemical modification of existing allozymes.     

Inversion of the substrate specificity of yeast alcohol dehydrogenase

The relationship between the size of the substrate binding pocket and the catalytic reactivities with varied alcohols was studied with the Saccharomyces cerevisiae alcohol dehydrogenase I (ScADH) and compared with the liver enzymes from horse (EqADH, EE isoenzyme) and monkey (MmADH alpha, alpha-isoenzyme). The yeast enzyme is most active with ethanol, and its activity decreases as the size of the alcohol is increased, whereas the activities of the liver enzymes increase with larger alcohols. The substrate pocket in ScADH was enlarged by single substitutions of Thr-48 to Ser (T48S), Trp-57 to Met (W57M), and Trp-93 to Ala (W93A), and a double change, T48S:W93A, and a triple, T48S:W57M:W93A. The T48S enzyme has the same pattern of activity (V/K) as wild-type ScADH for linear primary alcohols. The W57M enzymes have lowered reactivity with primary and secondary alcohols. The W93A and T48S:W93A enzymes resemble MmADH alpha in having an inverted specificity pattern for primary alcohols, being 3- and 10-fold more active on hexanol and 350- and 540-fold less active on ethanol, and are as reactive as the liver enzymes with long chain primary alcohols. The three Ala-93 enzymes also acquired weak activity on branched chain alcohols and cyclohexanol.     

Evolutionary genetics of the Drosophila alcohol dehydrogenase gene-enzyme system

The mitochondrion is the only extranuclear organelle containing DNA (mtDNA). As such, genetically determined mitochondrial diseases may result from a molecular defect involving the mitochondrial or the nuclear genome. The first is characterized by maternal inheritance and the second by Mendelian inheritance. Ragged-red fibers (RRF) are commonly seen with primary lesions of mtDNA, but this association is not invariant. Conversely, RRF are seldom associated with primary lesions of nuclear DNA. Large-scale rearrangements (deletions and insertions) and point mutations of mtDNA are commonly associated with RRF and lactic acidosis, e.g. Kearns-Sayre syndrome (KSS) (major large-scale rearrangements), Pearson syndrome (large-scale rearrangements), myoclonus epilepsy with RRF (MERRF) (point mutation affecting tRNA(lys) gene), mitochondrial myopathy, lactic acidosis, and stroke-like episodes (MELAS) (two point mutations affecting tRNA(leu)(UUR) gene) and a maternally-inherited myopathy with cardiac involvement (MIMyCa) (point mutation affecting tRNA(leu)(UUR) gene). However, RRF and lactic acidosis are absent in Leber hereditary optic neuropathy (LHON) (one point mutation affecting ND4 gene, two point mutations affecting ND1 gene, and one point mutation affecting the apocytochrome b subunit of complex III), and the condition associated with maternally inherited sensory neuropathy (N), ataxia (A), retinitis pigmentosa (RP), developmental delay, dementia, seizures, and limb weakness (NARP) (point mutation affecting ATPase subunit 6 gene). The point mutations in MELAS, MIMyCa, and MERRF, and the large-scale mtDNA rearrangements in KSS and Pearson syndrome have a broader biochemical impact since these molecular defects involve the translational sequence of mitochondrial protein synthesis. The nuclear defects involving mitochondrial function generally are not associated with RRF. The biochemical classification of mitochondrial diseases principally catalogues these nuclear defects. This classification divides mitochondrial diseases into five categories. Primary and secondary deficiencies of carnitine are examples of a substrate transport defect. A lipid storage myopathy is often present. Disturbances of pyruvate or fatty acid metabolism are examples of substrate utilization defects. Only four defects of the Krebs cycle are known: fumarase deficiency, dihydrolipoyl dehydrogenase deficiency, alpha-ketoglutarate dehydrogenase deficiency, and combined defects of muscle succinate dehydrogenase and aconitase. Luft disease is the singular example of a defect in oxidation-phosphorylation coupling. Defects of respiratory chain function are manifold. Two clinical syndromes predominate, one involving limb weakness, and the other primarily affecting brain function. Leigh syndrome may result from different enzyme defects, most notably pyruvate dehydrogenase complex deficiency, cytochrome c oxidase deficiency, complex I deficiency, and complex V deficiency associated with the recently described NARP point mutation. A new group of mitochondrial diseases has emerged.(ABSTRACT TRUNCATED AT 400 WORDS)     

Active site modifications in a double mutant of liver alcohol dehydrogenase: structural studies of two enzyme-ligand complexes

The oxidation of alcohol to aldehyde by horse liver alcohol dehydrogenase (LADH) requires the transfer of a hydride ion from the alcohol substrate to the cofactor nicotinamide adenine dinucleotide (NAD). A quantum mechanical tunneling contribution to this hydride transfer step has been demonstrated in a number of LADH mutants designed to enhance or diminish this effect [Bahnson, B. J., et al. (1997) Proc. Natl. Acad. Sci. U.S.A. 94, 12797-12802]. The active site double mutant Phe93 --> Trp/Val203 --> Ala shows a 75-fold reduction in catalytic efficiency relative to that of the native enzyme, and reduced tunneling relative to that of either single mutant. We present here two crystal structures of the double mutant: a 2.0 A complex with NAD and the substrate analogue trifluoroethanol and a 2.6 A complex with the isosteric NAD analogue CPAD and ethanol. Changes at the active site observed in both complexes are consistent with reduced activity and tunneling. The NAD-trifluoroethanol complex crystallizes in the closed conformation characteristic of the active enzyme. However, the NAD nicotinamide ring rotates away from the substrate, toward the space vacated by replacement of Val203 with the smaller alanine. Replacement of Phe93 with the larger tryptophan also produces unfavorable steric contacts with the nicotinamide carboxamide group, potentially destabilizing hydrogen bonds required to maintain the closed conformation. These contacts are relieved in the second complex by rotation of the CPAD pyridine ring into an unusual syn orientation. The resulting loss of the carboxamide hydrogen bonds produces an open conformation characteristic of the apoenzyme.     

Involvement of alcohol dehydrogenase, short-chain dehydrogenase/reductase, aldehyde dehydrogenase, and cytochrome P450 in the control of retinoid signaling by activation of retinoic acid synthesis

The effects of vitamin A (retinol) on growth and development are mediated by the active metabolite retinoic acid which controls a nuclear receptor signaling pathway. While elegant work on the retinoic acid receptor family has focused attention upon how the receptor controls this pathway, there now exists a relatively large gap in our understanding of how retinol is activated to form the ligand. During vertebrate embryogenesis and in adult organs retinoic acid is detected in a distinct spatiotemporal pattern, suggesting that it is produced from retinol in a regulated fashion. Enzymes involved in retinol and retinal metabolism are likely candidates for regulators of tissue retinoic acid levels. Members of the alcohol dehydrogenase and short-chain dehydrogenase/reductase enzyme families catalyze the reversible interconversion of retinol and retinal, the rate-limiting step, whereas members of the aldehyde dehydrogenase and cytochrome P450 enzyme families catalyze the irreversible oxidation of retinal to retinoic acid. The identification of enzymes likely to catalyze retinol oxidation in vivo has been particularly controversial, and this is made even more difficult by the reversible nature of this reaction. Taking into account enzymatic properties and coenzyme preferences, a case can be made that class IV alcohol dehydrogenase catalyzes retinol oxidation to provide retinal for retinoic acid synthesis, whereas microsomal retinol dehydrogenase (a short-chain dehydrogenase/reductase) catalyzes the reduction of retinal to retinol to promote retinoid storage. Further studies on these enzyme families will allow this layer of control in the retinoid signaling pathway to be understood.