Kinetic study on the reaction mechanism of pantothenase: existence of an acyl-enzyme intermediate and role of general acid catalysis.

A kinetic study was performed on the reaction mechanism of pantothenase (EC 3.5.1.22) catalyzed hydrolysis of the pantothenic acid. A nonlinear progress curve is derived if the reaction occurs at low buffer concentrations. The nonlinearity is due to partial reversibility of the reaction; an acylenzyme (pantoyl-enzyme) is formed during the reaction, and beta-alanine, the other end product, is able to react with the acyl-enzyme and return back to pantothenate. The dependence of the beta-alanine return reaction on buffer concentration and on pH suggests a general acid catalysis during the reaction. A reaction mechanism is suggested, in which the -NH3+ form of beta-alanine participates in the return reaction, and the deacylation of the acyl-enzyme is acid catalyzed.     

Multicomponent reactions in crop protection chemistry

An overview is given of the significance of multicomponent reactions in the synthesis of agrochemicals. The most important applications of multicomponent condensations, such as the Biginelli reaction, Bucherer-Bergs reaction, Hantzsch dihydropyridine synthesis, Kabachnik-Fields reaction, Mannich reaction, Passerini reaction, Petasis reaction, Strecker reaction, Ugi reaction and Willgerodt-Kindler reaction, to the synthesis of herbicidally, fungicidally and insecticidally active compounds are presented. Also the mode of action and biological activity of these multicomponent reaction products are reported.     

使用估计的反应自由能预测组成性和可变剪接位点

基因结构预测中的一个重要步骤是精确地识别剪接位点。基于剪接反应的基本物理原则,最大信息原理被应用到剪接反应的理论分析中,进而导出了反应自由能估计表达式。作为一个简化模型,这个表达式能被用来估计一个5′剪接区或者3′剪接区所参与的剪接反应中的自由能变化。它不但较全面地概括了各个碱基之间的关联,而且还考虑了基因组背景概率的影响。这个反应自由能表达式被用来预测了人类基因中的组成性和可变剪接位点,预测结果是令人满意的,其预测能力比得上当前的一些流行方法。这说明最大信息原理可以作为研究某些核酸-蛋白质相互作用系统（如剪接反应）的理论出发点,导出的反应自由能表达式较好地符合了剪接反应过程。     

Stochastic simulation of chemical reactions with spatial resolution and single molecule detail

Methods are presented for simulating chemical reaction networks with a spatial resolution that is accurate to nearly the size scale of individual molecules. Using an intuitive picture of chemical reaction systems, each molecule is treated as a point-like particle that diffuses freely in three-dimensional space. When a pair of reactive molecules collide, such as an enzyme and its substrate, a reaction occurs and the simulated reactants are replaced by products. Achieving accurate bimolecular reaction kinetics is surprisingly difficult, requiring a careful consideration of reaction processes that are often overlooked. This includes whether the rate of a reaction is at steady-state and the probability that multiple reaction products collide with each other to yield a back reaction. Inputs to the simulation are experimental reaction rates, diffusion coefficients and the simulation time step. From these are calculated the simulation parameters, including the 'binding radius' and the 'unbinding radius', where the former defines the separation for a molecular collision and the latter is the initial separation between a pair of reaction products. Analytic solutions are presented for some simulation parameters while others are calculated using look-up tables. Capabilities of these methods are demonstrated with simulations of a simple bimolecular reaction and the Lotka-Volterra system.     

A Kinetic Analysis of Coupled (or Auxiliary) Enzyme Reactions

As a case study, we consider a coupled (or auxiliary) enzyme assay of two reactions obeying the Michaelis–Menten mechanism. The coupled reaction consists of a single-substrate, single-enzyme non-observable reaction followed by another single-substrate, single-enzyme observable reaction (indicator reaction). In this assay, the product of the non-observable reaction is the substrate of the indicator reaction. A mathematical analysis of the reaction kinetics is performed, and it is found that after an initial fast transient, the coupled reaction is described by a pair of interacting Michaelis–Menten equations. Moreover, we show that when the indicator reaction is fast, the quasi-steady-state dynamics are governed by three fast variables and one slow variable. Timescales that approximate the respective lengths of the indicator and non-observable reactions, as well as conditions for the validity of the Michaelis–Menten equations, are derived. The theory can be extended to deal with more complex sequences of enzyme-catalyzed reactions.     

Unpredictable selection in a structured population leads to local genetic differentiation in evolved reaction norms

Unpredictability during development of the optimum phenotype under future selection leads to a compromise reaction norm with a slope that is shallower than the slope of the optimum reaction norm. Unpredictability of selection can lead to an evolved curved reaction norm when genetic variation for curvature is available even if the optimum reaction norm is linear. This requires asymmetry in the frequency distribution of the habitats of selection; at small population size, stochasticity in the number of individuals per selection habitat is sufficient to generate such asymmetry. Unpredictability of selection in structured populations leads to local genetic differentiation of reaction norms. The mean habitat of a subpopulation is defined as the subpopulation's focal habitat. The evolved mean reaction norm of each subpopulation is anchored at the optimum genotypic value in its focal habitat. Linear reaction norms are parallel if the conditional distribution of adults around the focal habitats is the same for each subpopulation. Adult migration and absence of zygote dispersal represents the ultimate structured population, each habitat playing the role of focal habitat. Absence of zygote dispersal requires that the flow of individuals through the habitats is used instead of the habitats’ frequencies in the prediction of the evolved reaction norm. Adult migration in absence of zygote dispersal leads to an evolved pattern of locally differentiated reaction norms with optimum genotypic value anchored in the focal habitat and, for linear reaction norms, parallel slopes.     

Effects of solvent viscosity and different guanidine salts on the kinetics of ribonuclease A chain folding

The kinetics of folding of the two forms of unfolded ribonuclease A have been measured as a function of solvent viscosity by adding either glycerol or sucrose. The aim is to find out if either reaction is rate limited by segmental motion whose rate depends on external friction. The fast folding reaction (U₂ ? N) is known to be the direct folding process, and the slow folding reaction (U₁ ? N) is known to be rate limited by an interconversion between two forms (U₁ ? U₂) which are present after unfolding in strongly denaturing conditions. No dependence on solvent viscosity is found, either for the direct folding reaction or for the interconversion reaction. Each folding reaction has also been tested to see if its rate depends on the concentration of one or more partly folded intermediates, by adding denaturants destabilize any partly folded structures. Different guanidine salts are used as denaturants to vary the denaturing effectiveness of the salt while holding the guanidinium ion concentration constant. The rates both of the direct folding reaction and of the interconversion reaction decrease in relation to the denaturing effectiveness of the salt. However, there is a basic difference between the responses of the fast and slow folding reactions to low concentrations of denaturants. Although each folding reaction produces native protein, there is an 800-fold decrease in the rate of the fast folding reaction in 1M guanidine thiocyanate and only a 13-fold decrease in the rate of the slow folding reaction. This is consistent with the fast reaction being the direct folding process and the slow reaction being rate limited by the initial conversion of the slowrefolding to the fast-refolding form. Both the lack of viscosity dependence and the effects of denaturants indicate that the formation of structure is rate limiting in the direct folding reaction, U₂ ? N. The failure to find a viscosity dependence for the interconversion reaction, U₁ ? U₂, indicates that in this reaction also friction-limited segmental motion is not the rate-limiting process. Since the U₁ ? U₂ interconversion still occurs when the polypeptide chain is completely unfolded, the surprising result is that its rate in refolding conditions depends significantly on a reaction intermediate which is “denatured” by guanidine salts.     

Interfacial versus homogeneous enzymatic cleavage of mandelonitrile by hydroxynitrile lyase in a biphasic system

The question of an interfacial versus a homogeneous reaction is carefully addressed for the enzymatic biphasic cleavage of mandelonitrile to benzaldehyde by Prunus amygdalus hydroxynitrile lyase (pa-Hnl) (Hickel et al. [1999] Biotechnol Bioeng 36:425-436). Experimental evidence, including 1) the reaction ceases when the interface is populated by previously adsorbed denatured pa-Hnl, 2) the reaction continues even after washout of the bulk enzyme from the aqueous phase, 3) highly nonpolar organic solvents initially promote fast reaction kinetics that relatively quickly decay to zero product production, and 4) the reaction rate is nonlinear in the bulk enzyme concentration, provide robust grounds for an interfacial reaction. We also model enzymatic mandelonitrile cleavage assuming a homogeneous aqueous-phase reaction. The homogeneous reaction scheme does not simultaneously account for the experimental observations of a linear dependence of the reaction rate on organic/water interfacial area, no dependence on the aqueous-phase volume, and a nonlinear dependence on pa-Hnl aqueous concentration. Further, simple calculations demonstrate that the homogeneous reaction rate is at least three orders of magnitude slower than those observed by Hickel et al. (1999). We again conclude that enzyme adsorbed at the organic solvent/water interface primarily catalyzes the biphasic mandelonitrile cleavage reaction.     

Kinetics of ATP-stimulated nuclease activity of the Escherichia coli RecBCD enzyme

The RecBCD enzyme is an ATP-dependent nuclease on both single-stranded and double-stranded DNA substrates. We have investigated the kinetics of the RecBCD-catalyzed reaction with small, single-stranded oligodeoxyribonucleotide substrates under single-turnover conditions using rapid-quench flow techniques. RecBCD-DNA complexes were allowed to form in pre-incubation mixtures. The nuclease reactions were initiated by mixing with ATP. The reaction time-courses were fit to several possible reaction mechanisms and quantitative estimates were obtained for rate constants for individual reaction steps. The relative rates of forward reaction versus dissociation from the DNA, and the fact that inclusion of excess non-radiolabeled single-stranded DNA to trap free RecBCD has no effect on the nuclease reaction, indicates that the reaction is processive. The reaction products show that the reaction begins near the 3'-end of the [5'-32P]DNA substrates and the major cleavage sites are two to four phosphodiester bonds apart. The product distribution is unchanged as the ATP concentration varies from 10 microM to 100 microM ATP, while the overall reaction rate varies by about tenfold. These observations suggest that DNA cleavage is tightly coordinated with movement of the enzyme along the DNA. The reaction time-courses at low concentrations of ATP (10 microM and 25 microM) have a significant lag before cleavage products appear. We propose that the lag represents ATP-dependent movement of the DNA from an initial binding site in the helicase domain of the RecB subunit to the nuclease active site in a separate domain of RecB. The extent of reaction of the substrate is limited (approximately 50%) under all conditions. This may indicate the formation of a non-productive RecBCD-DNA complex that does not dissociate in the 1-2 s time-scale of our experiments.     

The involvement of iron and ubiquinone in electron transfer reactions mediated by reaction centers from photosynthetic bacteria.

Reaction centers from Rhodopseudomonas sphaeroides strain R-26 were prepared with varying Fe and ubiquinone (Q) contents. The photooxidation of P-870 to P-870+ was found to occur with the same quantum yield in Fe-depleted reaction centers as in control samples. The kinetics of electron transfer from the initial electron acceptor (I) to Q also were unchanged upon Fe removal. We conclude that Fe has no measurable role in the primary photochemical reaction. The extent of secondary reaction from the first quinone acceptor (QA) to the second quinone acceptor (QB) was monitored by the decay kinetics of P-870+ after excitation of reaction centers with single flashes in the absence of electron donors, and by the amount of P-870 photooxidation that occurred on the second flash in the presence of electron donors. In reaction centers with nearly one iron and between 1 and 2 ubiquinones per reaction center, the amount of secondary electron transfer is proportional to the ubiquinone content above one per reaction center. In reaction centers treated with LiClO4 and o-phenanthroline to remove Fe, the amount of secondary reaction is decreased and is proportional to Fe content. Fe seems to be required for the secondary reaction. In reaction centers depleted of Fe by treatment with SDS and EDTA, the correlation between Fe content and secondary activity is not as good as that found using LiClO4. This is probably due in part to a loss of primary photochemical activity in samples treated with SDS; but the correlation is still not perfect after correction for this effect. The nature of the back reaction between P-870+ and Q-B was investigated using stopped flow techniques. Reaction centers in the P-870+ Q-B state decay with a 1-s half-time in both the presence and absence of o-phenanthroline, an inhibitor of electron transfer between Q-B and QB. This indicates that the back reaction between P-870+ and Q-A is direct, rather than proceeding via thermal repopulation of Q-A. The P-870+ Q-B state is calculated to lie at least 100 mV in free energy below the P-870+ Q-A state.     

Critical analysis of the use of the acrolein-Schiff method as a possible DNA reaction

Summary Histophotometric examination was carried out on nuclei of lymphocytes in human peripheral blood, which were subjected to various tests in order to assess the acrolein-Schiff method as a possible DNA specific reaction, in comparison with the traditional Feulgen reaction. Special attention was paid to the degree of difference between responses attributable to a direct Schiff reaction obtained in the fraction of nuclear proteins after treatment with acrolein. From the results obtained it appears that an acrolein-Schiff reaction, following extraction of proteins, may be considered a qualitative reaction for DNA. Our findings also show that there is no relationship between the degree of response to the acrolein-Schiff reaction and that to the Feulgen reaction, which is to be expected in view of the different mechanisms of the two reactions.     

Effects of solvent and ionic medium on the kinetics of axial ligand substitution in vitamin B12. Part IV. The reaction between aquocobalamin and the thiocyanate ion in acetonitrile-water mixtures

The rate constants for the reaction of aquocobalamin with the thiocyanate ion were measured as a function of ionic strength and solvent composition in acetonitrile-water mixtures. The reaction is described by a two-step mechanism: the ligation reaction, where the most stable isomer (S-bonded) is formed and the isomerisation reaction (S-bonded to N-bonded thiocyanate). For the ligation reaction a full quantitative analysis of solvent effects could be performed, whereas for the isomerisation reaction only qualitative observations were made. The equilibrium constant for the isomerisation (S-bonded/N-bonded) is large and does not change with the solvent composition. It is found that the transfer Gibbs energies of activation for the ligation reaction are the same as found for the ligand thiourea. The absence of a solvent effect on the isomerisation reaction is a further example of the ability of vitamin B₁₂ to create its own micro environment.     

The adenosine diphosphate–adenosine triphosphate-exchange reaction of cerebral microsomes and its relation to the sodium ion-stimulated adenosine-triphosphatase reaction

Microsomes from guinea-pig cerebral cortex contain a system capable of exchanging ADP with ATP at rates of about 20mumoles/mg. of protein/hr. The ADP-ATP-exchange reaction requires Mg(2+) for activity. The reaction is not stimulated by Na(+) or K(+) and is not inhibited by ouabain, in contrast with the Na(+)-plus-K(+)-stimulated adenosine triphosphatase. The pH optimum also differs from that of the adenosine triphosphatase. The ADP-ATP-exchange reaction is stimulated two- to three-fold by non-ionic, anionic and cationic detergents, even when these agents are inhibiting the adenosine-triphosphatase reaction. This reaction may represent a component of the Na(+)-plus-K(+)-stimulated adenosine-triphosphatase reaction but is more likely to be due to other enzyme systems present in microsomal subfractions.     

Modular decomposition of metabolic systems via null-space analysis

We describe a method by which the reactions in a metabolic system may be grouped hierarchically into sets of modules to form a metabolic reaction tree. In contrast to previous approaches, the method described here takes into account the fact that, in a viable network, reactions must be capable of sustaining a steady-state flux. In order to achieve this decomposition we introduce a new concept--the reaction correlation coefficient, phi, and show that this is a logical extension of the concept of enzyme (or reaction) subsets. In addition to their application to modular decomposition, reaction correlation coefficients have a number of other interesting properties, including a convenient means for identifying disconnected subnetworks in a system and potential applications to metabolic engineering. The method computes reaction correlation coefficients from an orthonormal basis of the null-space of the stoichiometry matrix. We show that reaction correlation coefficients are uniquely defined, even though the basis of the null-space is not. Once a complete set of reaction correlation coefficients is calculated, a metabolic reaction tree can be determined through the application of standard programming techniques. Computation of the reaction correlation coefficients, and the subsequent construction of the metabolic reaction tree is readily achievable for genome-scale models using a commodity desk-top PC.     

Feulgen nucleal reaction

Summary Electrophoretic means of separation revealed the presence of as many as five reaction products in Schiff-apurinic acid reaction at the maximum. They differed not only in their absorption maxima, but also in their ratios of apurinic acid phosphorus to fuchsin moiety. Some considerations on the reaction mechanism to account for the occurrence of these multiple reaction products have been made. The stoichiometry of Schiff-apurinic acid reaction was studied with respect to the main product responsible for the presentation of reaction color. A reaction product consisting of six or eight atom moles of apurinic acid phosphorus per mole of fuchsin moiety is to be formed, provided that the reagent of infinite concentration is used. From theoretical view point, a reaction product consisting of four atom moles of apurinic acid phosphorus per mole of fuchsin moiety is to be expected with the reagent of infinite concentration, provided that apurinic acid retains essentially the nucleotide sequence of its parent desoxyribonucleic acid except for some modification of the original purin nucleotide groups to react as aldehyde moieties, and provided that the reaction proceeds at a constant rate irrespective of the concentrations of the reagent.     

针对点突变癌基因T24－ras转录物的核酶性质研究

通过改变核酶体外反应的各种条件,对针对点突变癌基因Ｔ２４－ｒａｓ转录物的核酶Ｒ８的性质进行了系统研究,结果表明：Ｒ８切割底物反应的最适ｐＨ值约为８．２,最适温度为５０℃,反应必须有镁离子参加,生理环境中常见的阴离子对反应没有影响,一些变性剂能够促进反应的进行,Ｒ８切割底物的反应为二级反应。     

Utilization of peroxide and its relevance in oxygen insertion reactions catalyzed by chloroperoxidase.

Chloroperoxidase (CPO) catalyzed oxygen insertions are highly enantioselective and hence of immense biotechnological potential. A peroxide activation step is required to give rise to the compound I species that catalyzes this chiral reaction. A side reaction, a catalase type peroxide dismutation, is another feature of CPO's versatility. This work systematically investigates the utilization of different peroxides for the two reactions, i.e. the catalase type reaction and the oxygen insertion reaction. For the oxygen insertion reaction, indene and phenylethyl sulfide were chosen as substrate models for epoxidation and sulfoxidation respectively. The results clearly show that CPO is stable towards hydrogen peroxide and has a total number of turnovers near one million prior to deactivation. The epoxidation reactions terminate before completion because the enzyme functioning in its catalatic mode quickly removes all of the hydrogen peroxide from the reaction mixture. Sulfoxidation reactions are much faster than epoxidation reactions and thus are better able to compete with the catalase reaction for hydrogen peroxide utilization. A preliminary study towards optimizing the reaction system components for a laboratory scale synthetic epoxidation is reported.     

Expanding the Scope of Native Chemical Ligation in Glycopeptide Synthesis

Glycoprotein is one of the important biopolymer in a biological system. In order to understand the complex correlation between the exact oligosaccharide structure of the glycoprotein and its function, preparation of homogeneous glycoprotein is to be essential. For such a purpose, chemical synthesis is one of the most promising methods to obtain homogeneous glycoproteins. Glycopolypeptide, which is a backbone of glycoprotein and an essential intermediate for glycoprotein synthesis, can be obtained through coupling of peptide and glycopeptide segments because straightforward synthesis of such a long glycopolypeptide is still a challenging task. Native chemical ligation (NCL) is one of the powerful methods for the coupling reaction of peptides, however, despite extensive investigation, NCL has site limitation for the coupling. In this context, we discovered NCL at serine site, where is a highly conserved amino acid residue in glycoproteins. This reaction strategy is owed to conversion reaction of cysteine residue to serine residue after conventional NCL. This conversion reaction is consisted of three steps; S-methylation of cysteine, CNBr reaction to afford O-ester linked peptide, and O to N acyl shift to get native peptide linkage with serine residue. During extensive investigation of the strategy, we found new reaction media for CNBr reaction, which is the key reaction in the strategy. This enabled us to synthesize not only N-linked glycopeptides but also O-linked sialyl glycopeptides. Thus we could demonstrate the usefulness of this new glycopeptide ligation strategy. In this short review, we will introduce our newly developed cysteine to serine conversion reaction which will expand the application of NCL in peptide as well as glycopeptide synthesis.     

Is hexaamminecobalt(III/II) electron self-exchange spin-forbidden? Analogy to photochemical processes

The hypothesis that the electron self-exchange reaction of hexaamminecobalt(III/II) is spin-allowed and adiabatic is presented and compared to previous treatments of the reaction which considered it spin-forbidden. The hypothesis is based on the concept that since the reactant and product have the same spin, it is unnecessary to invoke interaction with other spin states to ‘allow’ the reaction. To justify the hypothesis, an analogy is drawn between the cobalt self-exchange reaction and the photochemical processes of triplet-triplet annihilation and triplet-triplet exchange.     

alpha-Chymotrypsin in plastein synthesis: influence of substrate concentration on enzyme activity.

The role of alpha-chymotrypsin in the plastein reaction was studied using a peptic hydrolysate of albumin as substrate. Study of this reaction simultaneously by different methods showed that the plastein reaction is enzyme catalyzed and is highly dependent on environmental conditions. A gel permeation chromatography study of the plastein reaction showed simultaneous increases in the high- and low-molecular-weight oligopeptide fractions; a transpeptidation mechanism may be involved in the reaction. A study of the effect of substrate concentration on the plastein reaction catalyzed by alpha-chymotrypsin showed a profile with both hydrolytic and synthetic activities. This effect was also observed when the reaction course was followed by quantification of the free amino groups at different substrate concentrations, showing that a condensation mechanism is responsible for the synthetic activity when the substrate concentration is very high. These results have led us to conclude that the plastein reaction involves a transpeptidation and/or condensation mechanism, which is a function of the substrate concentration.