Purification and characterization of a NAD+-dependent secondary alcohol dehydrogenase from propane-grown Rhodococcus rhodochrous PNKb1

NAD⁺-linked primary and secondary alcohol dehydrogenase activity was detected in cell-free extracts of propane-grown Rhodococcus rhodochrous PNKb1. One enzyme was purified to homogeneity using a two-step procedure involving DEAE-cellulose and NAD-agarose chromatography and this exhibited both primary and secondary NAD⁺-linked alcohol dehydrogenase activity. The Mr of the enzyme was approximately 86,000 with subunits of Mr 42,000. The enzyme exhibited broad substrate specificity, oxidizing a range of short-chain primary and secondary alcohols (C₂–C₈) and representative cyclic and aromatic alcohols. The pH optimum was 10. At pH 6.5, in the presence of NADH, the enzyme catalysed the reduction of ketones to alcohols. The K _m values for propan-1-ol, propan-2-ol and NAD were 12 mM, 18 mM and 0.057 mM respectively. The enzyme was inhibited by metal-complexing agents and iodoacetate. The properties of this enzyme were compared with similar enzymes in the current literature, and were found to be significantly different from those thus far described. It is likely that this enzyme plays a major role in the assimilation of propane by R. rhodochrous PNKb1.Abbreviations HPLC high performance liquid chromatography - DEAE diethyl amino ethyl - IEF isoelectrofocusing - NTG nitrosoguanidine - SDS-PAGE sodium dodecylsulphate polyacrylamide gel electrophoresis - pI isoelectric point     

A Novel Carbonyl Reductase with Anti-Prelog Stereospecificity from Acetobacter sp. CCTCC M209061: Purification and Characterization

A novel carbonyl reductase (AcCR) catalyzing the asymmetric reduction of ketones to enantiopure alcohols with anti-Prelog stereoselectivity was found in Acetobacter sp. CCTCC M209061 and enriched 27.5-fold with an overall yield of 0.4% by purification. The enzyme showed a homotetrameric structure with an apparent molecular mass of 104 kDa and each subunit of 27 kDa. The gene sequence of AcCR was cloned and sequenced, and a 762 bp gene fragment was obtained. Either NAD(H) or NADP(H) can be used as coenzyme. For the reduction of 4′-chloroacetophenone, the K_m value for NADH was around 25-fold greater than that for NADPH (0.66 mM vs 0.026 mM), showing that AcCR preferred NADPH over NADH. However, when NADH was used as cofactor, the response of AcCR activity to increasing concentration of 4′-chloroacetophenone was clearly sigmoidal with a Hill coefficient of 3.1, suggesting that the enzyme might possess four substrate-binding sites cooperating with each other The V_max value for NADH-linked reduction was higher than that for NADPH-linked reduction (0.21 mM/min vs 0.17 mM/min). For the oxidation of isopropanol, the similar enzymological properties of AcCR were found using NAD⁺ or NADP⁺ as cofactor. Furthermore, a broad range of ketones such as aryl ketones, α-ketoesters and aliphatic ketones could be enantioselectively reduced into the corresponding chiral alcohols by this enzyme with high activity.     

Purification and properties of NADP+:Isocitrate dehydrogenase from lactating bovine mammary gland

NADP⁺:isocitrate dehydrogenase has been purified to homogeneity from lactating bovine mammary gland. Purification was achieved through the use of affinity and DEAE-cellulose chromatography. The isolated enzyme gives one band when stained for protein or enzyme activity on discontinuous alkaline gel electrophoresis. The enzyme has a molecular weight of 55,000 as estimated by sodium dodecyl sulfate-gel electrophoresis and a Stokes radius of 4.1 nm as measured by gel chromatography. The enzyme will not use NAD⁺ in place of NADP⁺ and has an absolute requirement for divalent cations. The apparent K_m values for dl-isocitrate, Mn²⁺, and NADP⁺ were found to be 8, 6, and 11 μm, respectively. The Mn²⁺-d_s-isocitrate complex is the most likely substrate for the mammary enzyme with a K_m of 3 μm. The properties of mammary NADP⁺:isocitrate dehydrogenase are compared with those of the homologous enzymes from pig heart and bovine liver, and its characteristics are discussed with respect to the function of the enzyme in lactating mammary gland.     

Purification and characterization of constitutive polyethylene glycol (PEG) dehydrogenase of a PEG 4000-utilizing Flavobacterium sp. no. 203

Polyethylene glycol (PEG) 4000-utilizing bacterium no. 203 was identified as a Flavobacterium species. 2, 6-Dichlorophenol-indophenol (DCIP)-dependent PEG dehydrogenase was constitutively formed in nutrient broth, glucose and PEG media. However, the enzyme formation was repressed in the presence of an excess amount (over 0.25%) of PEG 400 or 1000. PEG dehydrogenase was purified approximately 34 fold by precipitation with ammonium sulfate, solubilization with benzalkonium chloride, chromatography with DEAE-Toyopearl 650 M and hydroxylapatite and gel filtration on Toyopearl HW-55. The molecular weight of the purified PEG dehydrogenase was calculated to be approximately 2.20 × 10⁵, a value which seemed to consist of four subunits with the same molecular weight of 5.70 × 10⁴. The enzyme was stable below 40°C and in the pH range of 7.0 and 8.0. The optimum pH and temperature of the activity were around 8.0 and 40°C, respectively. The enzyme reduced DCIP and coenzyme Q₁ and Q₂. PEG dehydrogenase showed activity toward various PEG molecules (dimer-PEG 20,000). The apparent K_m values for PEG 400, 1000, 4000 and 6000 were about 1.0, 1.7, 2.8 and 5.9 mM, respectively. The enzyme oxidized primary aliphatic alcohols of C₃–C₁₂, the corresponding aldehydes of C₃–C₇, aromatic alcohols and aldehydes, diols, etc. The enzyme was inactive on ethylene glycol, glycerol, secondary alcohols and sugar alcohols. The enzyme activity was strongly inhibited by sulfhydryl agents or heavy metals and 1, 4-benzoquinone. The purified enzyme showed absorption apectrum similar to that of PEG 6000 dehydrogenase which has already been reported to be a quinoprotein. The prosthetic group of the enzyme was extracted with methanol and identified as PQQ from its prosthetic group capability for glucose dehydrogenase and the fluorescence spectrum.     

Purification and some properties of NAD(P)H dehydrogenase from Saccharomyces cerevisiae: Contribution to glycolytic methylglyoxal pathway

NAD(P)H dehydrogenase was purified approximately 480-fold from Saccharomyces cerevisiae with 6.5% activity yield. The enzyme was homogeneous on polyacrylamide gel electrophoresis. The molecular weight of the enzyme was estimated to be 40,000–44,000 by gel filtration on Sephadex G-150 column chromatography and SDS-polyacrylamide gel electrophoresis. The K_m values for NADPH and NADH were 7.3 μM and 0.1 mM, respectively. The activity of the enzyme increased approximately 4-fold with Cu²⁺. FAD, FMN and cytochrome c were not effective as electron acceptors, although Fe(CN)₆³⁻ was slightly effective. NADH generated by the reaction of lactaldehyde dehydrogenase in the glycolytic methylglyoxal pathway will be reoxidized by NAD(P)H dehydrogenase. NAD(P)H dehydrogenase thus may contribute to the reduction/oxidation system in the glycolytic methylglyoxal pathway to maintain the flux of methylglyoxal to lactic acid via lactaldehyde.     

Purification and properties of alcohol oxidase from Tanacetum vulgare

Alcohol oxidase (alcohol: O₂ oxidoreductase) from leaves of Tanacetum vulgare has been purified 5150-fold to homogeneity on disc electrophoresis and gel electrofocussing. The enzyme which is probably flavoprotein, has molecular weight 180 000 daltons and is comprised of two sub-units of 94 000 and 75 000 daltons. It is active over a broad range (pH 5–9) and best accepts primary aliphatic alcohols with 6 to 10 carbons, especially those with a 2-ene group. K_m values for hex-trans-2-ene-1-ol, geraniol (3,7-dimethylocta-trans-2,6-dien-1-ol) and n-octanol were 0.19, 1.56 and 0.49 mM respectively. The significance of the enzyme in the formation of leaf aldehyde (hex-trans-2-ene-1-al) and in terpene metabolism is discussed.     

Alteration in substrate specificity of horse liver alcohol dehydrogenase by an acyclic nicotinamide analog of NAD+

A new, acyclic NAD-analog, acycloNAD⁺ has been synthesized where the nicotinamide ribosyl moiety has been replaced by the nicotinamide (2-hydroxyethoxy)methyl moiety. The chemical properties of this analog are comparable to those of β-NAD⁺ with a redox potential of −324 mV and a 341 nm λ_max for the reduced form. Both yeast alcohol dehydrogenase (YADH) and horse liver alcohol dehydrogenase (HLADH) catalyze the reduction of acycloNAD⁺ by primary alcohols. With HLADH 1-butanol has the highest V_max at 49% that of β-NAD⁺. The primary deuterium kinetic isotope effect is greater than 3 indicating a significant contribution to the rate limiting step from cleavage of the carbon–hydrogen bond. The stereochemistry of the hydride transfer in the oxidation of stereospecifically deuterium labeled n-butanol is identical to that for the reaction with β-NAD⁺. In contrast to the activity toward primary alcohols there is no detectable reduction of acycloNAD⁺ by secondary alcohols with HLADH although these alcohols serve as competitive inhibitors. The net effect is that acycloNAD⁺ has converted horse liver ADH from a broad spectrum alcohol dehydrogenase, capable of utilizing either primary or secondary alcohols, into an exclusively primary alcohol dehydrogenase. This is the first example of an NAD analog that alters the substrate specificity of a dehydrogenase and, like site-directed mutagenesis of proteins, establishes that modifications of the coenzyme distance from the active site can be used to alter enzyme function and substrate specificity. These and other results, including the activity with α-NADH, clearly demonstrate the promiscuity of the binding interactions between dehydrogenases and the riboside phosphate of the nicotinamide moiety, thus greatly expanding the possibilities for the design of analogs and inhibitors of specific dehydrogenases.     

Inhibiton of human placental 17 beta-hydroxysteroid dehydrogenase by steroids and nonsteroidal alcohols: aspects of inhibitor structure and binding specificity

Inhibition of human placental 17β-hydroxysteroid dehydrogenase by C₁₈ and C₁₉ steroids and nonsteroidal alcohols was assayed at pH 9.0 with 17β-estradiol 3-methyl ether and NAD⁺ as reactants. The nonstaroidal alcohols tested were poor inhibitors. Cyclopentanol and cyclohexanol had K_i values greater than 5 mm. Nonaromatic C₁₈ and C₁₉ steroids with oxygen functions at both positions 3 and 17 gave no detectable inhibition or had K_i, values greater than or equal to 160 μm. 3μ-Hydroxy-5,16-androstadiene, 5-androsten-3β-ol, 1,3,5(10)-estratrien-3-ol, and 1,3,5(10),16-estratetraen-3-ol, steroids lacking a C(17) oxygen function, had K_i values of 1.8, 6.0, 0.04, and 0.17 μm, respectively, demonstrating that both C₁₈ and C₁₉ steroids can bind at the steroid site. Binding specificity is narrowed and binding affinity for nonaromatic steroids weakened by oxygen functions at C(17) or both C(3) and C(17). The structural implications of the specificity data for steroid recognition and complex formation and in vivo control of enzyme activity are discussed.     

Purification and Characterization of an NAD+-Dependent XylB-Like Aryl Alcohol Dehydrogenase Identified in Acinetobacter baylyi ADP1

The gene xylB_ADP1 from Acinetobacter baylyi ADP1 (gene annotation number ACIAD1578), coding for a putative aryl alcohol dehydrogenase, was heterologously expressed in Escherichia coli BL21(DE3). The respective aryl alcohol dehydrogenase was purified by fast protein liquid chromatography to apparent electrophoretic homogeneity. The predicted molecular weight of 39,500 per subunit was confirmed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. According to the native M_w as determined by gel filtration, the enzyme forms dimers and therefore seems to be XylB related. The enzyme showed the highest activity at 40°C. For both the reduction and the oxidation reactions, the pH for optimum activity was 6.5. The enzyme was NADH dependent and able to reduce medium- to long-chain n-alkylaldehydes, methyl-branched aldehydes, and aromatic aldehydes, with benzaldehyde yielding the highest activity. The oxidation reaction with the corresponding alcohols showed only 2.2% of the reduction activity, with coniferyl alcohol yielding the highest activity. Maximum activities for the reduction and the oxidation reaction were 104.5 and 2.3 U mg⁻¹ of protein, respectively. The enzyme activity was affected by low concentrations of Ag⁺ and Hg²⁺ and high concentrations of Cu²⁺, Zn²⁺, and Fe²⁺. The gene xylB_ADP1 seems to be expressed constitutively and an involvement in coniferyl alcohol degradation is suggested. However, the enzyme is most probably not involved in the degradation of benzyl alcohol, anisalcohol, salicyl alcohol, vanillyl alcohol, cinnamyl alcohol, or aliphatic and isoprenoid alcohols.     

Purification and Properties of Primary and Secondary Alcohol Dehydrogenases from Thermoanaerobacter ethanolicus

Thermoanaerobacter ethanolicus (ATCC 31550) has primary and secondary alcohol dehydrogenases. The two enzymes were purified to homogeneity as judged from sodium dodecyl sulfate-polyacrylamide gel electrophoresis and gel filtration. The apparent M_rs of the primary and secondary alcohol dehydrogenases are 184,000 and 172,000, respectively. Both enzymes have high thermostability. They are tetrameric with apparently identical subunits and contain from 3.2 to 5.5 atoms of Zn per subunit. The two dehydrogenases are NADP dependent and reversibly convert ethanol and 1-propanol to the respective aldehydes. The V_m values with ethanol as a substrate are 45.6 μmol/min per mg for the primary alcohol dehydrogenase and 13 μmol/min per mg for the secondary alcohol dehydrogenase at pH 8.9 and 60°C. The primary enzyme oxidizes primary alcohols, including up to heptanol, at rates similar to that of ethanol. It is inactive with secondary alcohols. The secondary enzyme is inactive with 1-pentanol or longer chain alcohols. Its best substrate is 2-propanol, which is oxidized 15 times faster than ethanol. The secondary alcohol dehydrogenase is formed early during the growth cycle. It is stimulated by pyruvate and has a low K_m for acetaldehyde (44.8 mM) in comparison to that of the primary alcohol dehydrogenase (210 mM). The latter enzyme is formed late in the growth cycle. It is postulated that the secondary alcohol dehydrogenase is largely responsible for the formation of ethanol in fermentations of carbohydrates by T. ethanolicus.     

Plant pyruvate dehydrogenase complex: analysis of the kinetic properties and metabolite regulation

The pyruvate dehydrogenase complex was isolated from the mitochondria of broccoli florets and shown to be similar in its reaction mechanism to the complexes from other sources. Three families of parallel lines were obtained for the initial velocity patterns, indicating a multisite ping-pong mechanism. The apparent K_m values obtained were 321 ± 18, 148 ± 13, and 7.2 ± 0.51 μm for pyruvate, NAD⁺, and CoA, respectively. Product inhibition studies using acetyl-CoA and NADH yielded results which were in agreement with those predicted by the multisite ping-pong mechanism. Acetyl-CoA and NADH were found to be competitive inhibitors versus CoA and NAD⁺, respectively. All other substrate-product combinations showed uncompetitive inhibition patterns, except for acetyl-CoA versus NAD⁺. Among various metabolites tested, only hydroxypyruvate (K_i = 0.11 mM) and glyoxylate (K_i = 3.27 mM) were found to be capable of inhibiting the broccoli enzyme to a significant degree. Initial velocity patterns using Mg²⁺? or Ca²⁺-thiamine pyrophosphate and pyruvate as the variable substrate were found to be consistent with an equilibrium ordered mechanism where Mg? or Ca-thiamine pyrophosphate bind first, with dissociation constants of 33.8 and 3 μm, respectively. The Mg- or Ca-thiamine pyrophosphate complexes also dissociated rapidly from the enzyme complex.     

The specificities and configurations of ternary complexes of yeast and liver alcohol dehydrogenases

1. Some aspects of the substrate specificities of liver and yeast alcohol dehydrogenases have been investigated with pentan-3-ol, heptan-4-ol, (+)-butan-2-ol, (+/-)-butan-2-ol, (+/-)-hexan-3-ol and (+/-)-octan-2-ol as potential substrates. The liver enzyme is active with all substrates tested, including both isomers of each optically active alcohol. In contrast, the yeast enzyme is completely inactive towards those secondary alcohols where both alkyl groups are larger than methyl and active with only the (+)-isomers of butan-2-ol and octan-2-ol. 2. The absence of stereospecificity of liver alcohol dehydrogenase towards optically active secondary alcohols and its broad specificity towards secondary alcohols in general are explained in terms of an alkyl-binding site that will react with a variety of alkyl groups and the ability of the enzyme to accommodate a fairly large unbound alkyl group in an active enzyme-NAD(+)-secondary alcohol ternary complex. The absolute optical specificity of the yeast enzyme towards n-alkylmethyl carbinols and its unreactivity towards pentan-3-ol, hexan-3-ol and heptan-4-ol are explained by its inability to accept alkyl groups larger than methyl in the unbound position in a viable ternary complex. 3. Comparison of the known configurations of the n-alkylmethyl carbinols and [1-(2)H]ethanol and [1-(3)H]geraniol, which have been used in stereospecificity studies with these enzymes by other workers, provides strong evidence for which alkyl group of the substrate is bound to the enzyme in the oxidation of n-alkylmethyl carbinols. The conclusions reached are, for butan-2-ol oxidation with the liver enzyme, confirmed by deductions from kinetic data obtained with (+)-butan-2-ol and a sample of butan-2-ol containing 66% of (-)-butan-2-ol. 4. Initial-rate parameters for the oxidations of (+)-butan-2-ol, 66% (-)-butan-2-ol and pentan-3-ol by NAD with liver alcohol dehydrogenase are presented. The data are completely consistent with a general mechanism of catalysis previously proposed for this enzyme.     

Biosynthesis of secondary alcohols and ketones from alkanes

Combined gas-liquid chromatography-mass spectrometry of the secondary alcohols and ketones from broccoli (Brassica oleracea) showed that the former consisted of a mixture of nonacosan-14-ol (43%) and nonacosan-15-ol (57%) whereas the latter contained predominantly nonacosan-15-one (92%). Chemical degradation of the secondary alcohols derived from [4-¹⁴C]stearic acid in B. oleracea indicated that the intact C₁₈ chain was incorporated into nonacosan-14-ol and nonacosan-15-ol and that the hydroxyl groups of the positional isomers were introduced into a preformed aliphatic chain. [G-³H]Nonacosane was incorporated into nonacosan-14-ol and nonacosan-15-ol in B. oleracea in a ratio similar to that found in the natural mixture. A randomly tritiated natural mixture of secondary alcohols was incorporated into the ketone fraction by broccoli leaves. Chemical degradation of substrate secondary alcohols and the ketones biologically derived from them demonstrated that nonacosan-15-ol was the preferred secondary alcohol for biological oxidation to the ketone. The incorporation of [G-³H]nonacosane into nonacosanol and nonacosanone by broccoli leaves required O₂ and was inhibited by phenanthroline. The inhibition was reversed by Fe²⁺ suggesting that conversion of nonacosane into the oxygenated derivatives involve a mixed-function oxidase. From these results it is concluded that in B. oleracea nonacosane is hydroxylated to give nonacosan-15-ol and nonacosan-14-ol with subsequent preferential oxidation of the C-15 isomer to give the ketones.     

Purification and Characterization of a Novel (<Emphasis Type="Italic">R</Emphasis>)-1-Phenylethanol Dehydrogenase from <Emphasis Type="Italic">Lysinibacillus</Emphasis> sp. NUST506

A novel (R)-1-phenylethanol dehydrogenase was successfully purified from Lysinibacillus sp. NUST506 by preparative polyacrylamide gel electrophoresis. The enzyme is a NAD+-dependent oxidoreductase. The molecular weight of the (R)-1-phenylethanol dehydrogenase measured by SDS-PAGE was about 28 kDa. Furthermore, the optimal reaction conditions for the oxidative reaction were 70°C and pH 9.5 and for the reductive reaction were 65°C and pH 6.5. Under the optimal conditions, the K_M and k_cat values with (R)-1-phenylethanol as a substrate were found to be 0.78 mM and 123 s^–1 and with acetophenone they were 0.56 mM and 125 s^–1, respectively. The (R)-1-phenylethanol dehydrogenase became more stable at pH 9.5 in comparison with pH 5.0 and high stability was noticed at 4 and 37°C. Properties of the enzyme place it as a promising candidate for industrial applications.     

Purification,properties, and kinetic mechanism of coenzyme A-linked aldehyde dehydrogenase from Clostridium kluyveri

Coenzyme A-linked aldehyde dehydrogenase from Clostridium kluyveri was purified from the soluble fraction of crude extracts and its physical and kinetic properties were studied. The enzyme was purified approximately 90-fold over crude extracts to a specific activity of 50 units/mg protein and was estimated to be 40% pure by polyacrylamide gel electrophoresis. From active enzyme centrifugation studies, aldehyde dehydrogenase was found to have a sedimentation coefficient of s_{20, w} = 7.4. The Stokes radius of the enzyme was determined by gel filtration and found to be 9.5 nm in the presence of substrates and 11.0 nm in the absence of substrates. Using the values found for the sedimentation coefficient and the Stokes radius, the molecular weight of the enzyme in the presence of substrates was calculated to be 290,000 and the frictional ratio, 2.2. Aldehyde dehydrogenase can utilize thiols other than CoA as acetyl acceptors. A number of methods were employed in order to exclude the possibility that these thiols act merely by recycling nonenzymatically trace amounts of CoA that might be in the enzyme preparation. From steady-state kinetic measurements, a ping pong mechanism was proposed in which NAD⁺ binds to free enzyme, acetaldehyde binds next, and NADH is released before CoA binds and acetyl-CoA released. At K_m levels of other substrates, substrate inhibition by CoA was observed. The nature of the substrate inhibition is discussed.     

Microbial oxidation of methanol: Purification and properties of formaldehyde dehydrogenase from a Pichia sp. NRRL-Y-11328

An NAD⁺-linked, reduced glutathione-dependent formaldehyde dehydrogenase was purified to homogeneity from soluble extracts of methanol-grown yeast, Pichia sp. Formaldehyde and methylglyoxal are oxidized in the presence of NAD⁺ as an electron acceptor. NADP⁺ could not replace NAD⁺. Other straight chain aldehydes (C₂–C₆ tested), branched-chain aldehydes (e.g., isobutyaldehyde), aromatic aldehydes (e.g., salicylal-dehyde, benzaldehyde), glutyraldehyde, glyceraldehyde, glycoaldehyde, and glyoxal-dehyde tested were not oxidized by the purified formaldehyde dehydrogenase. The product of formaldehyde oxidation by purified enzyme was demonstrated to be S-for-mylglutathione by measuring the absorption at 240 nm due to the formation of thioester of formaldehyde and reduced glutathione. The K_m values for NAD⁺, formaldehyde, and reduced glutathione were 0.12, 0.31, and 0.16 mm, respectively, for the forward reaction at pH 8.0. The purified formaldehyde dehydrogenase also catalyzed the reduction of S-formylglutathione in the presence of NADH. Formate was not reduced by the purified enzyme. The K_m values for S-formylglutathione and NADH were 0.60 and 0.25 mm, respectively, for the reverse reaction at pH 6.0. Formaldehyde dehydrogenase has a molecular weight of 84,000 as determined by gel filtration and subunit molecular weight of 41,000 as determined by sodium dodecyl sulfate-gel electrophoresis. S-Formylglutathione, a product of formaldehyde oxidation, was oxidized by the partially purified formate dehydrogenase from Pichia sp. Formate dehydrogenase has a higher affinity toward S-formylglutathione (K_m value 1.8 mm) than toward formate (K_m value 25 mm). Antiserum prepared against the purified formaldehyde dehydrogenase from Pichia sp. NRRL-Y-11328 forms strong precipitin bands with isofunctional enzymes from methanol-grown Pichia pastoris NRRL-Y-7556 and Torulopsis candida Y-11419 and weak precipitin bands with Hansenula polymorpha NRRL-Y-2214. No cross-reaction was observed with isofunctional enzyme derived from methanol-grown Kloeckera sp.     

Characterization of a Pseudomonas putida Allylic Alcohol Dehydrogenase Induced by Growth on 2-Methyl-3-Buten-2-ol

We have been working to develop an enzymatic assay for the alcohol 2-methyl-3-buten-2-ol (232-MB), which is produced and emitted by certain pines. To this end we have isolated the soil bacterium Pseudomonas putida MB-1, which uses 232-MB as a sole carbon source. Strain MB-1 contains inducible 3-methyl-2-buten-1-ol (321-MB) and 3-methyl-2-buten-1-al dehydrogenases, suggesting that 232-MB is metabolized by isomerization to 321-MB followed by oxidation. 321-MB dehydrogenase was purified to near-homogeneity and found to be a tetramer (151 kDa) with a subunit mass of 37,700 Da. It catalyzes NAD⁺-dependent, reversible oxidation of 321-MB to 3-methyl-2-buten-1-al. The optimum pH for the oxidation reaction was 10.0, while that for the reduction reaction was 5.4. 321-MB dehydrogenase oxidized a wide variety of aliphatic and aromatic alcohols but exhibited the highest catalytic specificity with allylic or benzylic substrates, including 321-MB, 3-chloro-2-buten-1-ol, and 3-aminobenzyl alcohol. The N-terminal sequence of the enzyme contained a region of 64% identity with the TOL plasmid-encoded benzyl alcohol dehydrogenase of P. putida. The latter enzyme and the chromosomally encoded benzyl alcohol dehydrogenase of Acinetobacter calcoaceticus were also found to catalyze 321-MB oxidation. These findings suggest that 321-MB dehydrogenase and other bacterial benzyl alcohol dehydrogenases are broad-specificity allylic and benzylic alcohol dehydrogenases that, in conjunction with a 232-MB isomerase, might be useful in an enzyme-linked assay for 232-MB.     

Evidence for the existence of enzymatic variants of beta-hydroxybutyrate dehydrogenase from rat liver and brain mitochondria.

A comparison of rat brain and liver β-hydroxybutyrate dehydrogenase (EC 1.1.1.30) has revealed that significant differences exist between the enzymes with regard to their kinetic and physical properties. In contrast to the liver enzyme, brain β-hydroxybutyrate dehydrogenase is rapidly inactivated at 46° and is unstable when stored at ?20°. The brain dehydrogenase was found to have a larger K_m (apparent) for the 3-acetylpyridine analog of NAD⁺, and a greater energy of activation in the direction of β-hydroxybutyrate oxidation than the liver enzyme. In the reverse direction, the brain and liver dehydrogenase exhibit substrate inhibition by NADH (0.22 mM and 0.36 mM, respectively). The brain and liver β-hydroxybutyrate dehydrogenase did not differ significantly with regard to the Michaelis-Menten constants measured for NAD⁺ and β-hydroxybutyrate. The K_m constants of brain β-hydroxybutyrate dehydrogenase for acetoacetate (0.39 mM) and NADH (0.05 mM) were lower than those determined for the liver enzyme, acetoacetate (0.73 mM) and NADH (0.35 mM) respectively. These results suggest that the β-hydroxybutyrate dehydrogenase from rat brain and liver are isozymic variants.     

Essential sulfhydryl group of malic enzyme fromEscherichia coli

The activity of malic enzyme fromEscherichia coli was unaffected by the monovalent cations Na⁺ or Li⁺ at 10 mM. At 100 mM, Li⁺ or Na⁺ inhibited the enzyme activity by 88% and 83%, respectively. However, the enzyme activity was stimulated by 40–80-fold with 10 mM K⁺, Rb⁺, Cs⁺, or NH ₄ ⁺ . Less stimulation was observed with 100 mM of these stimulating cations. The stimulatory effect was lost after the enzyme was dialyzed against Tris-Cl buffer, but was regained after incubating the dialyzed enzyme with dithiothreitol. The regenerated enzyme was inactivated by 5,5′-dithiobis(2-nitrobenzoic acid). The resulting inactive thionitrobenzoyl enzyme could be regenerated to the active thiol-enzyme by eithiothreitol or converted to the inactive thiocyanoylated enzyme by KCN. The thiocyanoylated enzyme was insensitive to K⁺ stimulation, which suggested the essentiality of the sulfhydryl groups of theE. coli malic enzyme.     

Glycerol phosphate dehydrogenase in mammalian peroxisomes

Peroxisomes isolated on sucrose density gradients from homogenates of rat, chicken, or dog livers and rat kidney contained NAD⁺:α-glycerol phosphate dehydrogenase. Since the amount of sucrose in the peroxisomal fraction inhibited the enzyme activity about 70%, it was necessary to remove the sucrose by dialysis. About 8.4% of the total dehydrogenase of rat livers was in the surviving intact peroxisomes after homogenation. If corrected for particle breakage, this represented approximately 21% of the total activity. About 9.5% of the total enzyme was isolated in rat kidney peroxisomes, and because of severe particle rupture may represent over half of the total activity. No glycerol phosphate dehydrogenase was found in spinach leaf peroxisomes. A specific activity of 326 nmoles min^?1 mg^?1 protein in the rat liver peroxisomal fraction was at least twice that in the cytoplasm. NAD⁺:α-glycerol phosphate dehydrogenase was also present in a membrane fraction which was not identified, but none was in the mitochondria. The liver peroxisomal and cytoplasmic NAD⁺:α-glycerol phosphate dehydrogenase moved similarly on polyacrylamide gels and each resolved into two adjacent bands.Malate dehydrogenase was not found in peroxisomes from liver and kidney of rats and pigs, but 1–2% of the total particulate malate dehydrogenase was present in the peroxisomal area of the gradient from dog livers. However, this malate dehydrogenase in dog peroxisomal fractions did not exactly coincide with the peroxisomal marker, catalase. Malate dehydrogenase in dog liver mitochondria and in the peroxisomal fraction had similar pH optima and K_m values and migrated similarly to the anode at pH 6.5 on starch gels as a major and a minor band. The cytoplasmic malate dehydrogenase had a different pH optimum and K_m value and resolved into five different isoenzymes by electrophoresis. It is concluded that NAD⁺:α-glycerol phosphate dehydrogenase is in peroxisomes of liver and kidney, whereas malate dehydrogenase, present in peroxisomes of plants, is apparently absent in animal peroxisomes.