Kinetics of Inhibition of Horse Liver Alcohol Dehydrogenase byp-Methylbenzyl Hydroperoxide

Abstract

The complex kinetic behaviour of p-methylbenzyl hydroperoxide in its inhibitory action on horse liver alcohol dehydrogenase was examined. The kinetic patterns are markedly different at very low (<10^?8 M) and high (> 10^?7 M) hydroperoxide concentrations. In both cases very low inhibition constants (4nM and 14nM, respectively) were found. A possihle mechanistic model based on these results is discussed.     

马肝醇脱氢酶催化有机硅酮不对称还原反应动力学

探讨了马肝醇脱氢酶(HLADH)催化三甲基硅乙酮及其碳结构类似物不对称还原反应动力学.结果表明,在酶浓度低于150 mg/L时,底物浓度与反应初速度的关系符合米氏动力学方程;HLADH催化三甲基硅乙酮不对称还原反应的K_m、v_max和E_a分别为2.67 mmol/L、0.118 mmol/(L·min·mg)和37 kJ/mol, 其碳结构类似物的相应值分别为3.56 mmol/L、0.084 mmol/(L·min·mg)和61 kJ/mol.     

His-tagged Horse Liver Alcohol Dehydrogenase: Immobilization and application in the bio-based enantioselective synthesis of (S)-arylpropanols

The novel histidine-tagged Horse Liver Alcohol Dehydrogenase (His-HLADH-EE) was successfully purified and covalently immobilized onto a solid support in a one-step procedure through a metal-directed technique. A full characterization of the immobilized enzyme was carried out. Effects of pH, temperature and organic co-solvents were deeply investigated and they showed a shift in the optimum pH with respect to the free form as well as increased stability to temperature and solvents. The immobilized His-HLADH-EE proved to be effective as catalyst in the reduction of aliphatic and aromatic aldehydes. Application of the free and immobilized His-HLADH-EE to the chemo-enzymatic synthesis of (S)-Profenols demonstrated enhanced enantioselectivity and high reusability of the immobilized form. The achievement of a robust and effective immobilization of an alcohol dehydrogenase substantiated the use of biocatalytic reduction in the synthesis of primary alcohols and valuable chiral intermediates especially for pharmaceutical industries.     

New Function for an Old Enzyme: NEP Deficient Mice Develop Late-Onset Obesity

Background

According to the World Health Organization (WHO) there is a pandemic of obesity with approximately 300 million people being obese. Typically, human obesity has a polygenetic causation. Neutral endopeptidase (NEP), also known as neprilysin, is considered to be one of the key enzymes in the metabolism of many active peptide hormones.

Methodology/Principal Findings

An incidental observation in NEP-deficient mice was a late-onset excessive gain in body weight exclusively from a ubiquitous accumulation of fat tissue. In accord with polygenetic human obesity, mice were characterized by deregulation of lipid metabolism, higher blood glucose levels, with impaired glucose tolerance. The key role of NEP in determining body mass was confirmed by the use of the NEP inhibitor candoxatril in wild-type mice that increased body weight due to increased food intake. This is a peripheral and not a central NEP action on the switch for appetite control, since candoxatril cannot cross the blood-brain barrier. Furthermore, we demonstrated that inhibition of NEP in mice with cachexia delayed rapid body weight loss. Thus, lack in NEP activity, genetically or pharmacologically, leads to a gain in body fat.

Conclusions/Significance

In the present study, we have identified NEP to be a crucial player in the development of obesity. NEP-deficient mice start to become obese under a normocaloric diet in an age of 6–7 months and thus are an ideal model for the typical human late-onset obesity. Therefore, the described obesity model is an ideal tool for research on development, molecular mechanisms, diagnosis, and therapy of the pandemic obesity.     

A New Enzyme,d-Fructose Dehydrogenase

Genetic relatedness of 14 yeast strains and 2 mold strains was studied by the DNA-DNA hybridization method. The hybridization was performed between mitochondrial-DNA-free, ³²p-labeled DNA of Saccharomyces cerevisiae IAM 4009 and cold DNA of other strains. The DNA homology indices deviated considerably even among S. cerevisiae strains having similar GC contents, but, in general, yeast strains known to be able to mate with S. cerevisiae, showed high homology indices (35∽70%). Other species of Saccharomycetaceae and 6 asporogenous yeast strains exhibited values of 10∽20%. The relatedness suggested from these results was confirmed by the competition experiments and also by the hybridization with ³²P-DNA of Candida pulcherrima IFO 0561. DNA’s of Aspergillus oryzae I and Neurospora crassa IFO 6067 also exhibited low but appreciable homology indices (5∽7%). These results were discussed from the aspects of phylogenetics and also of gene conservation in microorganisms.     

Shaping of Drosophila Alcohol Dehydrogenase Through Evolution: Relationship with Enzyme Functionality

Drosophilidae is a large, widely distributed family of Diptera including 61 genera, of which Drosophila is the most representative. Drosophila feeding is part of the saprophytic trophic chain, because of its dependence upon decomposing organic matter. Many species have adapted to fermenting fruit feeding or to artificial (man-made) fermentation habitats, such as cellars and breweries. Actually, the efficient exploitation of niches with alcohols is considered one of the reasons for the worldwide success of this genus. Drosophila alcohol dehydrogenase (ADH), a member of the short-chain dehydrogenase/reductase family (SDR), is responsible for the oxidation of alcohols, but its direct involvement in fitness, including alcohol tolerance and utilization, gives rise to much controversy. Thus, it remains unclear whether ADH differentiation through evolution is somehow associated with natural adaptation to new feeding niches, and thus maybe to Drosophila speciation, or if it is a simple reflection of neutral divergence correlated with time separation between species. To build a hypothesis which could shed light on this dilemma, we analyzed the amino acid variability found in the 57 protein ADH sequences reported up to now, identified the taxon-specific residues, and localized them in a three-dimensional ADH model. Our results define three regions whose shaping has been crucial for ADH differentiation and would be compatible with a contribution of ADH to Drosophila speciation. Received: 11 August 1997 / Accepted: 30 December 1997     

Enzyme Variation, Metabolic Flux and Fitness: Alcohol Dehydrogenase in DROSOPHILA MELANOGASTER

Although there are many in vitro studies of enzyme activity of genetic variants at the Adh locus in D. melanogaster, little is known about the corresponding metabolic activity in living flies. We report here such measurements of the metabolic flux in the conversion of ethanol to the two products, CO2 and lipids, for six different active genotypes, containing the predominant naturally recurring alleles and covering a threefold range of in vitro activity. In adult flies we have found nonsignificant differences between genotypes in metabolic flux when estimates for individual genotypes had standard errors of approximately 10% of the mean value. In vitro activities are, therefore, poor predictors of the physiological consequences of enzyme variation since such determinations ignore the interactions inherent in multienzyme systems. We have no evidence that heterozygote show overdominance either at the enzyme or the flux level. Since fitness differences between genotypes must be generated by physiological differences, investigations of polymorphisms should be based on in vivo studies.     

木质素合成关键酶——肉桂醇脱氢酶的研究进展

肉桂醇脱氢酶(CAD)是木质素合成途径的关键酶之一,它作用于木质素单体生物合成的最后一步。重点综述了肉桂醇脱氢酶(CAD)的在基因家族方面,基因调控方面以及蛋白结晶方面的研究进展,讨论了存在的问题并提出了相关策略。     

Crustacean Hyperglycemic Hormone Family: Old Paradigms and New Perspectives

I present an overview of recent research on the isolation andcharacterization of members of the crustacean hyperglycemichormone (CHH) neuropeptide family. Members of this arthropod-specificfamily include CHH, molt-inhibiting hormone (MIH), vitellogenesis-inhibitinghormone (VIH), and mandibular organ-inhibiting hormone (MOIH).There are two subfamilies of this neuropeptide group, basedupon the presence or absence of a C-terminal CHH precursor-relatedpeptide. There are also sequence motif differences between thesesubfamilies. Most of the peptides comprising this neuropeptidefamily are synthesized and released by the eyestalk X-organ/sinusgland complex. Recent experiments have demonstrated the presenceof extra-eyestalk cells that produce CHH and the assignmentof additional functions to this hormone family.     

Conditional Overdominance at an Alcohol Dehydrogenase Locus in Yeast

Documented examples of heterosis attributable to overdominance at specific protein-encoding gene loci have rarely been reported, the association of sickle cell hemoglobin with malarial resistance being the best documented example of this phenomenon. Here we report an example of overdominance that is temperature- and allyl alcohol-dependent and due to heterozygosity at the ADH1 locus, involving two ADHI functional mutants. Overdominance appears to be due in part to an intermediate level of ADHI activity in the heterozygote. Unlike previous work with this this system using haploid strains, the NAD+/NADH ratios show no negative correlation with allyl alcohol resistance. This system is formally equivalent to that of sickle cell hemoglobin and shows promise as a tool for investigating the physiological basis for overdominance.     

Direct Enzymatic Assay for Alcohol Oxidase, Alcohol Dehydrogenase, and Formaldehyde Dehydrogenase in Colonies of Hansenula polymorpha

A procedure is described for the qualitative direct identification of alcohol oxidase, alcohol dehydrogenase, and formaldehyde dehydrogenase in yeast colonies. The method has been applied successfully to isolate mutants of Hansenula polymorpha with altered glucose repression of alcohol oxidase.     

Kinetics of Encapsulated Yeast Alcohol Dehydrogenase Dispersed in an Organic Solvent

Microcapsules dispersed in organic solvents provide a suitable environment for conducting enzyme reactions involving cofactors and hydrophobic substrates. Encapsulated YADH is active and stable in cyclohexane provided the pH is adjusted appropriately. Mass transfer does not influence batch reaction rates. Conversion in a fluidized-bed reactor containing encapsulated YADH/NAD⁺ and employing cyclohexane as the continuous phase depends strongly on residence time and inlet cinnamyl alcohol concentration. However, interpretation of these results is complicated by enzyme inactivation by the product, cinnamaldehyde, and interference from residual encapsulating agents.     

Kinetics of Encapsulated Yeast Alcohol Dehydrogenase Dispersed in an Organic Solvent

Microcapsules dispersed in organic solvents provide a suitable environment for conducting enzyme reactions involving cofactors and hydrophobic substrates. Encapsulated YADH is active and stable in cyclohexane provided the pH is adjusted appropriately. Mass transfer does not influence batch reaction rates. Conversion in a fluidized-bed reactor containing encapsulated YADH/NAD⁺ and employing cyclohexane as the continuous phase depends strongly on residence time and inlet cinnamyl alcohol concentration. However, interpretation of these results is complicated by enzyme inactivation by the product, cinnamaldehyde, and interference from residual encapsulating agents.     

Allyl Alcohol Selection for Lower Alcohol Dehydrogenase Activity in Nicotiana plumbaginifolia Cultured Cells

One cell strain with stable tolerance to allyl alcohol (AA^r) was selected from 6 × 10⁸ suspension cultured Nicotiana plumbaginifolia Viviani cells. The selected strain contained one-half the alcohol dehydrogenase (ADH) activity of the wild type (NP) due to the loss of two of three bands of ADH activity seen on starch gels following electrophoresis of wild-type cell extracts. Anaerobic conditions, simulated by not shaking the suspension cultures, increased the ADH specific activity to more than 3-fold the initial level in both strains but did not change the number of activity bands or the relative levels of activity. The cell strain with decreased ADH activity lost viability more rapidly than the wild type under the anaerobic conditions. The AA^r cells were 10 times more tolerant to ethanol than the NP cells and were also somewhat more tolerant to acetaldehyde and antimycin A. The substrate specificities of the ADH enzymes from both strains were very similar. Further selection of AA^r cells with allyl alcohol produced strains with even lower ADH activity and selection under anaerobic conditions produced strains with increased ADH activity. Genetic studies indicate that the N. plumbaginifolia ADH activity bands arise from subunits produced by two nonallelic genes. This is the first example of the use of allyl alcohol to select for decreased ADH using cultured plant cells.     

A New Enzymatic Microdetermination Procedure for Ethanol with Particulate Alcohol Dehydrogenase from Acetic Acid Bacteria

A new enzymatic method for microdetermination of ethanol has been established with particulate alcohol dehydrogenase from acetic acid bacteria and applied to the practical purposes. The enzyme had an optimum pH for ethanol oxidation at a fairly acidic region. Trace amounts of ethanol could be assayed by measuring the initial reaction rate as successful as by reading the end point of the reaction. Some advantages in using this enzyme for ethanol determination were pointed out comparing with NAD-linked alcohol dehydrogenase from yeast or horse liver. Impurity in the enzyme preparations, stability of reagents and coexistence of other substances in the assay mixture were not as critical as in NAD-linked enzyme. Acidic samples could also be directly determined for ethanol without preadjustment of sample pH.     

Activating p38 MAPK: New Tricks for an Old Kinase

Mitogen-activated protein kinases (MAPKs) participate in signaling initiated by a wide variety of extracellular stimuli. MAPKs are most commonly activated by a series of phosphorylation events in which one kinase phosphorylates another, the “MAPK cascade”. The cascade concludes with the dual phosphorylation of MAPKs on a conserved Thr-X-Tyr motif. In the case of the p38 MAPK, an exception to this paradigm has been found when signaling via the T cell antigen receptor (TCR). Rather than trigger the MAPK cascade, TCR-mediated stimulation activates proximal tyrosine kinases, which results in the phosphorylation of p38 on a noncanonical activating residue, Tyr-323. This phosphorylation activates p38 to phosphorylate third party substrates as well as its own Thr-X-Tyr motif. Here we discuss the structural and functional implications of this alternative p38 activation pathway, which may provide a new target for tissue-specific pharmacologic inhibition.     

Identification of New Genes Involved in the Regulation of Yeast Alcohol Dehydrogenase II

Recessive mutations in two negative control elements, CRE1 and CRE2, have been obtained that allow the glucose-repressible alcohol dehydrogenase (ADHII) of yeast to escape repression by glucose. Both the cre1 and cre2 alleles affected ADHII synthesis irrespective of the allele of the positive effector, ADR1. However, for complete derepression of ADHII synthesis, a wild-type ADR1 gene was required. Neither the cre1 nor cre2 alleles affected the expression of several other glucose-repressible enzymes. A third locus, CCR4, was identified by recessive mutations that suppressed the cre1 and cre2 phenotypes. The ccr4 allele blocked the derepression of ADHII and several other glucose-repressible enzymes, indicating that the CCR4 gene is a positive control element. The ccr4 allele had no effect on the repression of ADHII when it was combined with the ADR1-5c allele, whereas the phenotypically similar ccr1 allele, which partially suppresses ADR1-5c, did not suppress the cre1 or cre2 phenotype. Complementation studies also indicated that ccr1 and snf1 are allelic. A model of ADHII regulation is proposed in which both ADR1 and CCR4 are required for ADHII expression. CRE1 and CRE2 negatively control CCR4, whereas CCR1 is required for ADR1 function.