Optical Characteristics of Thiamine in Model Systems and in Holoenzyme

The optical properties of thiamine diphosphate-dependent enzymes change significantly on their interaction with cofactors (thiamine, bivalent metal ions) and substrates. These changes are connected with structural alterations of the active site and the mechanism of its functioning, and in some cases they reflect changes in the optical properties of the coenzyme itself within the protein. The use of optical characteristics, especially together with model systems, appeared to be a rather promising approach for investigation of the active site of thiamine diphosphate-dependent enzymes and the mechanism of its functioning. So, it seemed to be useful to summarize the literature data concerning the optical characteristics of thiamine (thiamine diphosphate) in model systems and the efficiency of their application for study of thiamine diphosphate-dependent enzymes.     

Structure,function, and biosynthesis of nickel‐dependent enzymes

Nickel enzymes, present in archaea, bacteria, plants, and primitive eukaryotes are divided into redox and nonredox enzymes and play key functions in diverse metabolic processes, such as energy metabolism and virulence. They catalyze various reactions by using active sites of diverse complexities, such as mononuclear nickel in Ni‐superoxide dismutase, glyoxylase I and acireductone dioxygenase, dinuclear nickel in urease, heteronuclear metalloclusters in [NiFe]‐carbon monoxide dehydrogenase, acetyl‐CoA decarbonylase/synthase and [NiFe]‐hydrogenase, and even more complex cofactors in methyl‐CoM reductase and lactate racemase. The presence of metalloenzymes in a cell necessitates a tight regulation of metal homeostasis, in order to maintain the appropriate intracellular concentration of nickel while avoiding its toxicity. As well, the biosynthesis and insertion of nickel active sites often require specific and elaborated maturation pathways, allowing the correct metal to be delivered and incorporated into the target enzyme. In this review, the phylogenetic distribution of nickel enzymes will be briefly described. Their tridimensional structures as well as the complexity of their active sites will be discussed. In view of the latest findings on these enzymes, a special focus will be put on the biosynthesis of their active sites and nickel activation of apo‐enzymes.     

Combining structural genomics and enzymology: completing the picture in metabolic pathways and enzyme active sites

An important goal of structural genomics is to complete the structural analysis of all the enzymes in metabolic pathways and to understand the structural similarities and differences. A preliminary glimpse of this type of analysis was achieved before structural genomics efforts with the glycolytic pathway and efforts are underway for many other pathways, including that of catecholamine metabolism. Structural enzymology necessitates a complete structural characterization, even for highly homologous proteins (greater than 80% sequence homology), as every active site has distinct structural features and it is these active site differences that distinguish one enzyme from another. Short cuts with homology modeling cannot be taken with our current knowledge base. Each enzyme structure in a pathway needs to be determined, including structures containing bound substrates, cofactors, products and transition state analogs, in order to obtain a complete structural and functional understanding of pathway-related enzymes.     

Computational active site analysis of molecular pathways to improve functional classification of enzymes

This study describes a method to computationally assess the function of homologous enzymes through small molecule binding interaction energy. Three experimentally determined X-ray structures and four enzyme models from ornithine cyclo-deaminase, alanine dehydrogenase, and mu-crystallin were used in combination with nine small molecules to derive a function score (FS) for each enzyme-model combination. While energy values varied for a single molecule-enzyme combination due to differences in the active sites, we observe that the binding energies for the entire pathway were proportional for each set of small molecules investigated. This proportionality of energies for a reaction pathway appears to be dependent on the amino acids in the active site and their direct interactions with the small molecules, which allows a function score (FS) to be calculated to assess the specificity of each enzyme. Potential of mean force (PMF) calculations were used to obtain the energies, and the resulting FS values demonstrate that a measurement of function may be obtained using differences between these PMF values. Additionally, limitations of this method are discussed based on: (a) larger substrates with significant conformational flexibility; (b) low homology enzymes; and (c) open active sites. This method should be useful in accurately predicting specificity for single enzymes that have multiple steps in their reactions and in high throughput computational methods to accurately annotate uncharacterized proteins based on active site interaction analysis.     

Calculating pKa values in enzyme active sites

The ionization properties of the active-site residues in enzymes are of considerable interest in the study of the catalytic mechanisms of enzymes. Knowledge of these ionization constants (pKa values) often allows the researcher to identify the proton donor and the catalytic nucleophile in the reaction mechanism of the enzyme. Estimates of protein residue pKa values can be obtained by applying pKa calculation algorithms to protein X-ray structures. We show that pKa values accurate enough for identifying the proton donor in an enzyme active site can be calculated by considering in detail only the active-site residues and their immediate electrostatic interaction partners, thus allowing for a large decrease in calculation time. More specifically we omit the calculation of site-site interaction energies, and the calculation of desolvation and background interaction energies for a large number of pairs of titratable groups. The method presented here is well suited to be applied on a genomic scale, and can be implemented in most pKa calculation algorithms to give significant reductions in calculation time with little or no impact on the accuracy of the results. The work presented here has implications for the understanding of enzymes in general and for the design of novel biocatalysts.     

Site-directed mutagenesis of a family 42 β-galactosidase from an antarctic bacterium

Site directed mutagenesis was used to modify the active site of a cold active beta-galactosidase taken from an Antarctic psychrotolerant Planococcus Bacterial isolate. The goal was to modify the active site such that there would be an increase in activity on certain substrates which showed little to no activity with the wild type enzyme. A total of 5 mutant enzymes were constructed with amino acid changes based on an analysis done via homology modeling. All 5 modified enzymes were assayed using 14 different nitrophenol substrates. In most cases there was a loss of activity on substrates that showed activity with the wild type enzymes. None of the expected activity was observed with any of the mutants, possibly in part due to a decrease in hydrogen bonding between the active site and the substrates. With the substrates p-nitrophenyl-β-d-galacturonide and p-nitrophenyl-α-d-glucopyranoside we saw increased activity. With one of the mutants we measured a 320% increase in activity on p-nitrophenyl-β-d-galacturonide. Two other mutants showed activity on p-nitrophenyl-α-d-glucopyranoside, which showed no activity at all with the wild type enzyme.     

Nucleic acid-binding metabolic enzymes: Living fossils of stereochemical interactions?

Recently, a series of intriguing observations expanded the list of a number of metabolic enzymes known to be associated with various forms of nucleic acids, including single- and double-stranded DNA, cognate and noncognate RNAs, and specific tRNAs. There is no clear reason why such a phenomenon should take place in contemporary cell physiology, or, further, why such a property has evolved at all. Sixteen known cases are presented in an attempt to delineate any common features of these enzymes. Apart from their ancient nature, as judged by their wide distribution and their participation in fundamental biochemical pathways, it appears that these enzymes do not share any structural or functional characteristics. Given that most of these proteins require nucleotide-based cofactors for their activity, it is proposed that they may represent genuine molecular fossils of the transition from an RNA to a protein world. Their nucleic acid-binding properties are in keeping with previously proposed hypotheses regarding the origins and evolution of nucleotide-based cofactors. The mode of interaction between these proteins and their nucleic acid substrates remains unclear, but it may represent an extended form of stereochemical interactions that have been proposed for the origins of the genetic code.Correspondence to: C.A. Ouzounis     

高效木聚糖降解酶系定制的新进展与挑战

木聚糖是植物细胞壁中含量最丰富的非纤维素多糖,大约占陆地生物质资源的20%-35%。不同物种来源的木聚糖结构因取代方式不同而具有广泛的异质性,这对生物质资源向生物燃料和其他高值产品高效转化提出了重大挑战。因此,需要开发由不同类型酶组成的最佳混合物以有效糖化木聚糖类底物。但是针对特定类型的底物设计高效降解酶系十分困难,应考虑底物的类型、底物的组成和物理性质、多糖的聚合度以及不同降解酶组分的生化性质等。本文从不同植物木聚糖的结构异质性与合成复杂性方面展示了其抗降解屏障,同时介绍了木聚糖主链降解酶系及侧链降解酶系的多样性以及协同降解作用,综述了复杂生境中微生物种群产生的混合酶系、降解菌株产生的高效酶系,以及基于特定木聚糖底物改造并定制简化高效的酶系统。随着不同种类木聚糖精细结构和木聚糖降解酶底物特异性的深入研究,针对特定底物类型进行绿色高效木聚糖酶系定制,加速木聚糖类底物的降解,从而实现木质纤维素资源的绿色高值化利用。     

Biochemical switching device: monocyclic enzyme system

The switching characteristics of a monocyclic enzyme system, in which two enzymes share substrates or co-factors in a cyclic manner, such as, --> X(1) + B + E(1) right arrow over left arrow A + E(1) + X(2) -->, --> X(3) + A + E(2) right arrow over left arrow B + E(2) + X(4) --> (E(1), E(2) are enzymes, X(1), X(3) are substrates, X(2), X(4) are products, A, B are cofactors), were demonstrated using computer simulations. The detailed mathematical models of biochemically possible cyclic enzyme systems were built up and the effects of rate constants and the effects of initial concentrations of enzymes and cofactors on switching characteristics were discussed. The cyclic enzyme system could function as a switching circuit when the initial concentrations of enzymes or cofactors are over a certain threshold value. Based on the present results, we further discuss the dynamic characteristics of a biochemical reactor system (bioreactor) involving this cyclic enzyme system as a switching controller.     

Understanding lipase stereoselectivity

Microorganisms or isolated enzymes can be applied as catalysts to create highly regio- and stereoselective conversions under mild conditions. Lipases (EC 3.1.1.3, triacylglycerol lipase) are lipid-hydrolysing enzymes, which are increasingly used in stereoselective reactions. Their industrial importance arises from the fact that they act on a variety of substrates promoting a broad range of biocatalytic reactions. Lipase stereoselectivity is exploited for the production of single enantiomers instead of racemic mixtures and will become more important in the pharmaceutical and agrochemical industry because, in most cases only one of the two enantiomers has the desired activity, whereas no activity or even undesirable side effects reside in the other enantiomer. Enantiomer differentiation is due to the various diastereomeric interactions that occur between the enantiomers and the active site of the enzyme. The stereospecificity of a lipase depends largely on the structure of the substrate, interaction at the active site and on the reaction conditions. Stereoselectivity involves a wide range of factors such as differentiation of enantiotopes, differentiation of enantiomers, type of substrate, biochemical interaction of the substrate with the enzyme, steric interaction of the substrates, competition between two different substrates, nature and availability of the active site for stereoselective action, presence of water and nature of solvents based on polarity and supercritical state. This article reviews factors responsible for lipase stereoselectivity.     

3D-QSAR with CoMFA Model of Prolylendopeptidase Substrates

Abstract

The prolylendopeptidase (PEP) is the proteolytic enzyme, which plays an essential role in the regulation of some processes in central nervous system, such as memory, learning and behavior. It was shown that PEP activity changes at different diseases, like Parkinsons or Alzheimer's diseases, and some PEP inhibitors are used in therapy. At present time the discovery of new types of PEP inhibitors are the actual task.

In this study the structure of PEP active site was analyzed by 3D-QSAR with CoMFA methods using of 12 PEP substrates. The designed pharmacophore model assumes that substrates interact with PEP active site by pyrrolidol ring of proline residue and by hydrogen bonding.

The 3-D-QSAR + CoMFA model of PEP substrates propose that the hydrophobic bonds play the essential role in substrate interaction with enzyme. This model reveals the important steric and electrostatic areas around the molecules and the presence of substituents controls the PEP activity for substrates. Analysis of obtained data allows to assume, that substrate binding in PEP active site causes essential perturbations of substrate structure. This effect mainly depends on chemical nature of the amino acid side chain, located near to proline.     

The Mechanism of Supercoiled DNA Recognition by Eukaryotic Type I Topoisomerases: II. A Comparison of the Enzyme Interaction with Specific and Nonspecific Oligonucleotides

Data on the interaction of DNA type I topoisomerases from the murine and human placenta cells with specific and nonspecific oligonucleotides of various structures and lengths are summarized. The relative contributions of various contacts between the enzymes and DNA that have previously been detected by X-ray analysis to the total affinity of the topoisomerases for DNA substrates are estimated. Factors that determine the differences in the enzyme interactions with specific and nonspecific single- and double-stranded DNAs are revealed. The results of the X-ray analysis of human DNA topoisomerase I are interpreted taking into account data on the comprehensive thermodynamic and kinetic analysis of the enzyme interaction with the specific and nonspecific DNAs.     

Structural, thermodynamic, and kinetic basis for the activities of some nucleic acid repair enzymes

X-ray structural analysis provides no quantitative estimate of the relative contribution of specific and nonspecific or strong and weak interactions to the total affinity of enzymes for nucleic acids. We have shown that the interaction between enzymes and long nucleic acids at the molecular level can be successfully analyzed by the method of stepwise increase in ligand complexity (SILC). In the present review we summarize our studies of human uracil DNA glycosylase and apurinic/apyrimidinic endonuclease, E. coli 8-oxoguanine DNA glycosylase and RecA protein using the SILC approach. The relative contribution of structural (X-ray analysis data), thermodynamic, and catalytic factors to the discrimination of specific and nonspecific DNA by these enzymes at the stages of complex formation, the following changes in DNA and enzyme conformations and especially the catalysis of the reactions is discussed.     

The mechanism of supercoiled DNA recognition by eukaryotic type I topoisomerases. II. A comparison of the enzyme interaction with specific and nonspecific oligonucleotides

Data on the interaction of DNA type I topoisomerases from the murine and human placenta cells with specific and nonspecific oligonucleotides of various structures and lengths are summarized. The relative contributions of various contacts between the enzymes and DNA that have previously been detected by X-ray analysis to the total affinity of the topoisomerases for DNA substrates are estimated. Factors that determine the differences in the enzyme interactions with specific and nonspecific single- and double-stranded DNAs are revealed. The results of the X-ray analysis of human DNA topoisomerase I are interpreted taking into account data on the comprehensive thermodynamic and kinetic analysis of the enzyme interaction with the specific and nonspecific DNAs.     

A two-domain structure for the two subunits of NAD(P)H:quinone acceptor oxidoreductase.

NAD(P)H:quinone acceptor oxidoreductase (EC 1.6.99.2) (DT-diaphorase) is a FAD-containing reductase that catalyzes a unique 2-electron reduction of quinones. It consists of 2 identical subunits. In this study, it was found that the carboxyl-terminal portion of the 2 subunits can be cleaved by various proteases, whereas the amino-terminal portion cannot. It was also found that proteolytic digestion of the enzyme can be blocked by the prosthetic group FAD, substrates NAD(P)H and menadione, and inhibitors dicoumarol and phenindione. Interestingly, chrysin and Cibacron blue, 2 additional inhibitors, cannot protect the enzyme from proteolytic digestion. The results obtained from this study indicate that the subunit of the quinone reductase has a 2-domain structure, i.e., an amino-terminal compact domain and a carboxyl-terminal flexible domain. A structural model of the quinone reductase is generated based on results obtained from amino-terminal and carboxyl-terminal protein sequence analyses and electrospray mass spectral analyses of hydrolytic products of the enzyme generated by trypsin, chymotrypsin, and Staphylococcus aureus protease. Furthermore, based on the data, it is suggested that the binding of substrates involves an interaction between 2 structural domains.     

Possible origin of life between mica sheets: does life imitate mica?

The mica hypothesis for the origin of life proposes that life originated between the sheets of muscovite mica. This paper elaborates on two ways that life resembles what might have originated between mica sheets. First, enzymes: The configurations and dynamics of enzymes, with their substrates, cofactors, and sometimes transition metal ions, often resemble mica sheets, with their open-and-shut motions, acting on small molecules between them, sometimes assisted by transition metal ions. Second, organisms: Mica world had the potential to be a community or ecosystem of prebiotic organisms in a way unlike other models for the origin of life.     

Cholesterol-Esterifying Enzymes in Developing Rat Brain

Abstract: A cholesterol-esterifying enzyme which incorporates exogenous fatty acids into cholesterol esters in the presence of ATP and coenzyme A was demonstrated in 15-day-old rat brain. This enzyme was maximally active at pH 7.4 and distinct from the cholesterol-esterifying enzyme reported earlier (Eto and Suzuki, 1971), which has a pH optimum at 5.2 and does not require cofactors. Properties of the two enzymes have been compared. Both the enzymes showed negligible esterification with acetate and were maximally active with oleic acid. The pH 5.2 enzyme esterified desmosterol, lanosterol and cholesterol at about the same rate, while the pH 7.4 enzyme was only 50% as active with lanosterol as it was with cholesterol and desmosterol. Phosphatidyl serine stimulated the pH 5.2 enzyme but not the pH 7.4 enzyme. Phosphatidyl choline and sodium taurocholate showed no effect on either of the enzymes. Both the enzymes were associated with particulate fractions, but the pH 7.4 enzyme was localized more in the microsomes. Purified myelin showed 2.6-fold and 1.5-fold higher specific activities of pH 5.2 and 7.4 enzymes respectively, when compared with homogenate. About 7–10% of total activity of both the enzymes was associated with purified myelin. Brain stem and spinal cord showed higher specific activity of pH 5.2 enzyme than cerebral cortex and cerebellum, while pH 7.4 enzyme specific activity was higher in cerebellum and brain stem than in cerebral cortex and spinal cord. Microsomal pH 7.4 activity showed progressive increase prior to the active period of myelination, reaching a maximum on the 15th day after birth and declined to 20% of the peak activity by 30 days. In contrast, pH 5.2 enzyme reached maximum activity about the 6th day after birth and remained at this level well into adulthood. In 15-day-old rat brain, pH 7.4 enzyme had five to six times higher specific activity than pH 5.2 enzyme, while in adults the activities were equal. The pH 7.4 enzyme showed a threefold higher specific activity than pH 5.2 enzyme in myelin from 15-day-old rats, but in adults the reverse was true.     

Ionogenic groups in the active site of lysostaphin. Kinetic and thermodynamic data compared with X-ray crystallographic data

The active site of lysostaphin is shown to contain a residue of glutamic acid. As judged by a pK value of 9.2 (with pentaglycine bridges in peptidoglycan of staphylococci as a substrate), another ionogenic residue could be the epsilon-amino group of a lysine. However, the pH value near a negatively charged cell is supposed to be strongly shifted to acidity as compared to the pH of the solution volume. This shifts the enzyme pH dependence curve in solution to alkalinity. Therefore, the other group might be histidine, which is consistent with the X-ray crystallographic data. A similar shift is likely to occur for lysozyme in the case of Micrococcus lysodeikticus cells. Determination of pK of ionogenic groups in the active sites of alkaline enzymes responsible for lysis of negatively charged bacterial cells gives their apparent values because the "pericellular" and "voluminous" values of pH are not coincident.     

Regional alterations of thiamine phosphate esters and of thiamine diphosphate-dependent enzymes in relation to function in experimental Wernicke's encephalopathy

Thiamine phosphate esters (thiamine monophosphate-TMP; thiamine diphosphate-TDP and thiamine triphosphate-TTP) were measured as their thiochrome derivatives by High Performance Liquid Chromatography in the brains of pyrithiamine-treated rats at various stages during the development of thiamine deficiency encephalopathy. Severe encephalopathy was accompanied by significant reductions of all three thiamine phosphate esters in brain. Neurological symptoms of thiamine deficiency appeared when brain levels of TMP and TDP fell below 15% of normal values. Activities of the TDP-dependent enzyme -ketoglutarate dehydrogenase were more severely reduced in thalamus compared to cerebral cortex, a less vulnerable brain structure. On the other hand, reductions of TTP, the non-cofactor form of thiamine, occurred to a greater extent in cerebral cortex than thalamus. Early reductions of TDP-dependent enzymes and the ensuing metabolic pertubations such as lactic acidosis impaired brain energy metabolism, and NMDA-receptor mediated excitotoxicity offer rational explanations for the selective vulnerability of brain structures such as thalamus to the deleterious effects of thiamine deficiency.     

Synthesis of a reactive ATP analog and its preliminary application as an affinity labeling reagent

A reactive ATP analog, N6-(6-bromoacetamidohexyl)-AMP.PCP, was synthesized in an attempt to covalently label the binding sites for adenine nucleotides, especially ATP, of various enzymes which utilize adenine nucleotides as substrates, cofactors, inhibitors or allosteric effectors. This reagent rapidly inactivated rabbit muscle glyceraldehyde 3-phosphate dehydrogenase (GPD), myokinase (MK), and creatine kinase (CK) under very mild conditions. Adenine nucleotide substrates prevented the inactivation. In the case of GPD, complete inactivation was observed when 1 mol of the reagent per mol of enzyme subunit was incorporated into the enzyme. These results indicate that the present ATP analog may be useful as an affinity labeling reagent for various adenine nucleotide-dependent enzymes.