Kinetic coupling of folding and prolyl isomerization of beta2-microglobulin studied by mutational analysis

β₂-Microglobulin (β2-m), a protein responsible for dialysis-related amyloidosis, adopts a typical immunoglobulin domain fold with the N-terminal peptide bond of Pro32 in a cis isomer. The refolding of β2-m is limited by the slow trans-to-cis isomerization of Pro32, implying that intermediates with a non-native trans-Pro32 isomer are precursors for the formation of amyloid fibrils. To obtain further insight into the Pro-limited folding of β2-m, we studied the Gdn-HCl-dependent unfolding/refolding kinetics using two mutants (W39 and P32V β2-ms) as well as the wild-type β2-m. W39 β2-m is a triple mutant in which both of the authentic Trp residues (Trp60 and Trp95) are replaced by Phe and a buried Trp common to other immunoglobulin domains is introduced at the position of Leu39 (i.e., L39W/W60F/W95F). W39 β2-m exhibits a dramatic quenching of fluorescence upon folding, enabling a detailed analysis of Pro-limited unfolding/refolding. On the other hand, P32V β2-m is a mutant in which Pro32 is replaced by Val, useful for probing the kinetic role of the trans-to-cis isomerization of Pro32. A comparative analysis of the unfolding/refolding kinetics of these mutants including three types of double-jump experiments revealed the prolyl isomerization to be coupled with the conformational transitions, leading to apparently unusual kinetics, particularly for the unfolding. We suggest that careful consideration of the kinetic coupling of unfolding/refolding and prolyl isomerization, which has tended to be neglected in recent studies, is essential for clarifying the mechanism of protein folding and, moreover, its biological significance.     

Kinetic behaviour and specificity of β-fructosidases in the hydrolysis of plant and microbial fructans

Fructosidases, in particular exo-β-fructosidases, may act on fructans such as inulins and levans of plant and bacterial origin to produce fructose. In this paper, the kinetic properties of a commercial preparation (Fructozyme L) and a recombinant exoinulinase (BfrA) from Thermotoga maritima, were studied using fructan polymer substrates from various sources. Both enzymatic preparations preferentially hydrolyzed β2-1 linkages and low molecular weight fructans. We show that chicory inulin is degraded most efficiently by both preparations, followed by bacterial inulin, in spite of its high molecular weight and branching in β2-6 positions. All bacterial levans were more slowly hydrolyzed. Michaelis–Menten kinetics describe the hydrolysis of sucrose and low molecular weight fructans (≤8.3 kDa) by both enzyme preparations, while first order kinetics were observed with respect to bacterial fructans due to the high molecular weight and, therefore, low molar concentrations. Comparison of second order rate constants indicates that bacterial inulin (Leuconostoc citreum CW28) is hydrolyzed more slowly with both enzyme preparations than chicory inulin by approximately one order of magnitude. For Leuconostoc mesenteroides NRRL B-512F levan, the second order rate constant for Fructozyme L is 200-fold lower than for chicory inulin. However, the second order rate constant for BfrA is only 22-fold lower than for chicory inulin. Taken together, our studies characterize the kinetics of fructan hydrolysis and also suggest that the kinetic parameters may be used to differentiate between fructan structures.     

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.     

Rapid analysis of human fecal bile acids

A rapid, accurate, precise method for determining human fecal bile acids is reported. Feces are homogenized and then briefly extracted with boiling absolute ethanol. A portion of the extract is evaporated to dryness and the residue heated with mild alkali to hydrolyze bile acid 3α-hydroxyl esters. Aliquots of hydrolyzed crude extract are treated with resazurin reagent which effects a series of enzyme catalyzed reactions in which bile acid free 3α-hydroxyls are first oxidized to 3-oxo-groups in a reaction catalyzed by 3α-hydroxysteroid dehydrogenase. Resulting protons are transferred to β-nicotinamide adenine dinucleotide, yielding reduced β-nicotinamide adenine dinucleotide (β-NADH). β-NADH then reduces nonfluorescent resazurin to fluorescent resorufin in a reaction catalyzed by diaphorase. Developed fluorescence, which is proportional to the extract aliquots bile acid content, is excited at 565 nm and read at 580 nm, wavelengths which lie in a spectral region in which there is minimal fecal pigment absorption. 3-Oxo-bile acids and bile acid 3α-sulfates are extracted in the procedure but reduction and/or solvolysis is necessary before quantification.     

Irreversible kinetics of β-N-acetyl-d-glucosaminidase from prawn (Penaeus vannamei) inactivated by mercuric ion

Cysteine residues in prawn (Penaeus vannamei) β-N-acetyl-d-glucosaminidase (NAGase, EC 3.2.1.52) have been modified by p-chloromercuribenzoate (PCMB). The results show that sulfhydryl group is essential for the activity of the enzyme. Inactivation kinetics of the enzyme by mercuric chloride (HgCl₂) has been studied using the kinetic method of the substrate reaction during inactivation of enzyme previously described by Tsou. The kinetic results show that the inactivation of the enzyme is an irreversible reaction. The microscopic rate constants for the reaction of Hg²⁺ with free enzyme and with the enzyme-substrate complex are determined. Comparison of these rate constants indicates that the presence of substrate offers marked protection of this enzyme against inactivation by Hg²⁺. The above results suggest that the cysteine residue is essential for activity.     

Metabolism of L-beta-lysine in a Pseudomonas: conversion of 6-N-acetyl-L-beta-lysine to 3-keto-6-acetamidohexanoate and of 4-aminobutyrate to succinic semialdehyde by different transaminases.

Some kinetic properties of two new species of transaminase found in extracts of a β-lysine-utilizing Pseudomonas are reported. Transaminase A catalyzes transamination between 6-N-acetyl-l-β-lysine (3-amino-6-acetamidohexanoate) and α-ketoglutarate to form 3-keto-6-acetamidohexanoate and glutamate. Transaminase B catalyzes a reaction between 4-aminobutyrate and pyruvate to form succinic semialdehyde and alanine. The formation of both transaminases is induced by growth of the bacteria on l-β-lysine, although transaminase B is also produced in the absence of this substrate. Transaminase A requires pyridoxal phosphate for activity. The β-keto acid formed from acetyl-β-lysine by transaminase A has been purified and characterized by decarboxylation, conversion to a formazan, reduction to a stable β-hydroxy acid, and conversion of the latter to its methyl ester. Transaminase B, unlike previously reported transaminases utilizing 4-aminobutyrate, cannot use α-ketoglutarate as an amino group acceptor. This enzyme is not stimulated by addition of pyridoxal phosphate, but is inhibited by hydroxylamine or cyanide. Both transaminases appear to function in the main pathway of β-lysine degradation.     

Role of -NADH for microsomal ethanol oxidation

α-NADH¹ was found to serve as electron donor for microsomal ethanol oxidation of rat liver. Almost no ethanol oxidation was observed with β-NADH. The α-NADH-dependent ethanol oxidation was almost completely inhibited by 0.1 mM cyanide or azide and strongly abolished in the presence of formate. α-NADH-dependent ethanol oxidation was increased by 1 mM SKF-525A, an inhibitor of microsomal mixed-function oxidase, to about 200%.These results suggested that hydrogen peroxide generated from α-NADH and molecular oxygen in microsomes might be a prerequisite step in the over-all reaction, eventually leading to the peroxidatic ethanol oxidation by catalase to acetaldehyde.     

Mathematical Model of the Firefly Luciferase Complementation Assay Reveals a Non-Linear Relationship between the Detected Luminescence and the Affinity of the Protein Pair Being Analyzed

The firefly luciferase complementation assay is widely used as a bioluminescent reporter technology to detect protein-protein interactions in vitro, in cellulo, and in vivo. Upon the interaction of a protein pair, complemented firefly luciferase emits light through the adenylation and oxidation of its substrate, luciferin. Although it has been suggested that kinetics of light production in the firefly luciferase complementation assay is different from that in full length luciferase, the mechanism behind this is still not understood. To quantitatively understand the different kinetics and how changes in affinity of a protein pair affect the light emission in the assay, a mathematical model of the in vitro firefly luciferase complementation assay was constructed. Analysis of the model finds that the change in kinetics is caused by rapid dissociation of the protein pair, low adenylation rate of luciferin, and increased affinity of adenylated luciferin to the enzyme. The model suggests that the affinity of the protein pair has an exponential relationship with the light detected in the assay. This relationship causes the change of affinity in a protein pair to be underestimated. This study underlines the importance of understanding the molecular mechanism of the firefly luciferase complementation assay in order to analyze protein pair affinities quantitatively.     

Reverse direction substrate kinetics and inhibition studies on the first enzyme of histidine biosynthesis, adenosine triphosphate phosphoribosyltransferase.

Initial velocity steady-state substrate kinetics for ATP phosphoribosyltransferase were determined in the direction reverse to the biosynthetic reaction and are consistent with a sequential kinetic mechanism. Histidine inhibited the reverse reaction cooperatively and completely. Product and alternate product inhibition studies were conducted to elucidate binding order. The alternate product β,γ-methylene ATP was competitive with respect to N¹-phosphoribosyl-ATP and noncompetitive with respect to pyrophosphate. Phosphoribosylpyrophosphate was noncompetitive with respect to both substrates. These data and those of the biosynthetic direction reaction are in satisfactory quantitative agreement with the ordered Bi-Bi kinetic mechanism with ATP or phosphoribosyl-ATP binding to free enzyme.     

Production of lactobionic acid and sorbitol from lactose/fructose substrate using GFOR/GL enzymes from Zymomonas mobilis cells: a kinetic study

In this work, we have investigated the kinetics of the biotechnological production of lactobionic acid (LBA) and sorbitol by the catalytic action of glucose-fructose oxidoreductase (GFOR) and glucono-δ-lactonase (GL) enzymes. The cells of bacterium Zymomonas mobilis ATCC 29191 containing this enzymatic complex were submitted to permeabilization and reticulation procedures. The effect of the concentration of substrates on the rate of product formation using a mobilized cell system was investigated. The application of higher fructose concentration seems to not affect the initial rate of formation of the bionic acid. Under conditions of low initial concentration of lactose, the experimental kinetic data of the bi-substrate reaction were modelled by assuming a rate equation of the classical ping-pong mechanism. The found kinetic parameters displayed a low affinity of the GFOR enzyme for both substrates. The enzymatic system did not exhibit normal Michaelis-Menten kinetics in response to a change of concentration of lactose, when fructose was held constant, presenting a sigmoid relationship between initial velocity and substrate concentration. A rate equation based on Hill kinetics was used to describe the kinetic behaviour of this enzyme-substituted reaction at higher lactose concentrations. The results from batch experiments using immobilized cells within Ca-alginate beads revealed that there is no pronounced occurrence of mass transfer limitations on LBA production for beads with 1.2 mm in average diameter. This discussion aids for defining the best operating conditions to maximize the productivity for LBA and sorbitol in this bioconversion and also for reducing the complexity of downstream separation processes.     

Binding of porcine pancreatic secretory trypsin inhibitor to bovine beta-trypsin: a kinetic study

The kinetics of the formation of the complex between bovine β-trypsin and the porcine pancreatic secretory trypsin inhibitor (PSTI; Kazal-type inhibitor) was investigated following the spectral changes associated with the displacement of proflavine from the enzyme, upon inhibitor binding, between pH 3.5 and 8.0 (I = 0.1M) at 21 ± 0.5°C. With inhibitor in excess over the enzyme ([PSTI] ≥ 5 × [bovine β-trypsin]), the time course of the reaction corresponds to a pseudo-first-order process. Over the whole pH range explored, the concentration dependence of the rate is second order at low PSTI concentrations but tends to first order at high inhibitor concentrations. This behavior may be explained by a relatively fast pre-equilibrium followed by a limiting first-order process. Values of kinetic parameters for PSTI binding to bovine β-trypsin depend, between pH 3.5 and 8.0, on the acid–base equilibrium of a single ionizing group (probably His-57 of bovine β-trypsin) that undergoes an acidic pK_a shift from 7.0 in the free bovine β-trypsin to 5.5 in the enzyme:PSTI complex. Kinetics of the bovine β-trypsin:PSTI adduct formation has been analyzed and compared with that of other (pro)enzyme:inhibitor reactions. Considering the known molecular structures of free serine (pro)enzymes, of Kazal- and Kunitz-type inhibitors, as well as of their complexes, the binding behavior of PSTI to bovine β-trypsin has been related to the inferred stereochemistry of the proteinase:inhibitor contact region.     

A new, sensitive method for enzyme kinetic studies of scarce glucosides

The maize β-glucosidase Zm-p60.1 is important for the regulation of plant development through its role in the targeted release of free cytokinins from cytokinin-O-glucosides, their inactive storage forms. Enzyme kinetics studies using these scarce substrates close to physiological concentrations are difficult due to two reasons: (a) Available methods are mainly suited for end-point kinetics. (b) These methods are not sufficiently sensitive when using scarce glucoside substrates.We developed a glucose assay using a system comprising three enzymes β-glucosidase, glucose oxidase and horseradish peroxidase, with the new substrate N-acetyl-3,7-dihydroxyphenoxazine-Amplex Ultra Red reagent (Molecular Probes). A calibration curve was constructed for resorufin and validation was carried out by comparing our method with the standard spectrophotometric method using p-nitrophenyl-β-d-glucopyranoside. In comparison with the other methods, this method is more sensitive, precise and accurate. The assay is rapid and hence suited for continuous kinetics, it is readily adapted to suit automated procedures, and potential applications include its use in studying the physiological role(s) of enzymes that cleave scarce glucoside substrates.     

Analysis of the lysozyme-catalyzed hydrolysis and transglycosylation of N-acetyl-d-glucosamine oligomers by high-pressure liquid chromatography

Although the enzyme lysozyme is one of the most thoroughly studied enzymes, quantitative kinetic studies of the lysozyme-catalyzed hydrolysis can only be achieved in a limited set of circumstances. The use of chromophoric substrates is beset by a number of difficulties and no low molecular weight substrate has gained acceptance in a standard assay. This report describes an efficient and rapid technique for monitoring the lysozyme-catalyzed hydrolysis and transglycosylation of β(1 → 4)-linked N-acetyl-d-glucosamine oligomers that utilizes high-pressure liquid chromatography to separate the products and liquid scintillation counting to ascertain their concentrations.     

Biopolymer - Surfactant Interaction: 4 Kinetics of Binding of Cetyltrimethyl Ammonium Bromide with Gelatin,Hemoglobin, β-lactoglobulin and Lysozyme

Abstract

The binding of CTAB with the proteins, gelatin, hemoglobin, β-lactoglobulin and lysozyme follow first order kinetics and occurs either in two or three distinct stages. The number of stages depends on the overall configuration of the biopolymers. The denatured protein, gelatin has shown three-stage kinetics under all conditions, whereas the native proteins, hemoglobinn, β-lactoglobulin and lysozyme have exhibited two stage kinetics. Heat treated lysozyme in 8 mol dm-³ urea medium has also shown a two-stage kinetics. On the basis of non interacting binding sites on the proteins and independent sequential binding, the rates of reaction have been observed to increase with temperature and follow the trend k₁ >> k₂ > k₃. The interaction of CTA⁺ with the proteins is both electrostatic and hydrophobic. Hemoglobin has shown maximum reaction rate whereas, β-lactoglobulin has shown a minimum. The activation parameters for the kinetic process have exhibited almost non-variant Δ G? and Δ H? < T Δ S? The formation of activation complex in the Eyring model is entropy controlled so also the overall kinetics. An isokinetic entropy-enthalpy compensation phenomenon has been observed for the respective kinetic stages.     

An assay procedure to investigate the transformation of toxic heme into inert hemozoin via plasmodial heme detoxification protein

Most antimalarial therapeutics, including chloroquine and artemisinin, induce free heme-mediated toxicity in Plasmodium. This cytotoxic heme is produced as a by-product during the large-scale digestion of host hemoglobin. Conversion of this host-derived heme into inert crystalline hemozoin is the only defense mechanism in Plasmodium against heme-induced cytotoxicity. Heme detoxification protein (HDP), a highly conserved plasmodial protein, is reported to be the most efficient biological mediator for heme to hemozoin transformation. Despite its significance, HDP has never been extensively studied for heme transformation into hemozoin. Therefore, we wish to develop a method to study the HDP-mediated transformation of heme into hemozoin. We have adopted, modified, and optimized the pyridine hemochrome assay to study HDP catalysis and use substrate and time kinetics to study the HDP-mediated transformation of heme into hemozoin. In contrast to the previously reported assay for HDP, we found that the new assay is more precise, accurate, and handy, making it more suitable for kinetic studies. HDP-mediated transformation of heme into hemozoin is not a single-step process, and involves a transient intermediate, most likely a cyclic heme dimer. The kinetics and the manner of HDP-mediated hemozoin production are dependent on the substrate concentration, and a small fraction of substrate remains untransformed to hemozoin irrespective of reaction time. Combining HDP as a catalyst and the pyridine hemochrome assay will facilitate the efficient screening of future antimalarials.     

Effect of cyclodextrins on the reactivity of fenitrothion

The hydrolysis reaction of fenitrothion was studied in water containing 2% dioxane and in the presence of native cyclodextrins (α-, β- and γ-CD) and two commercially available modified derivatives, namely, permethylated β- and α-cyclodextrin (TRIMEB and TRIMEA, respectively). The kinetics of the reaction in the presence of TRIMEA could not be measured because the complex formed is insoluble and precipitated even at low concentration. On the other hand, the reaction is only weakly affected by the presence of α-CD. The hydrolysis reaction is inhibited by all the other cyclodextrins. From the kinetic data the association equilibrium constants for the formation of the 1:1 inclusion complexes were determined as 417, 511 and 99 M⁻¹ for β-CD, TRIMEB and γ-CD, respectively. Despite the differences in the association constants for β- and γ-CD, the observed inhibition effect is about the same and this is due to the fact that the rate of hydrolysis in the cavity of γ-CD is smaller than that in the cavity of β-CD. The strongest inhibitor is TRIMEB and this result is consistent with the known structure of the complex in the solid state.     

Biochemical and Proteomic Characterization of a Novel Extracellular β-Glucosidase from Trichoderma citrinoviride

β-Glucosidases are of pivotal importance in bioconversion of carbonic biomass into fermentable and other useful metabolites, food industry, biotransformation, glyco-trimming of metabolome, etc. Trichoderma citrinoviride when grown on delignified Lantana camara produced a β-glucosidase and secreted it out in the medium. The extracellularly secreted β-glucosidase of T. citrinoviride was homogeneity purified and then characterized for its kinetic properties and proteomic characteristics. The 90 kDa enzyme was monomeric in nature, optimally active at pH 5.5 and the catalytic reaction rate was highest at 55°C. Uniquely, the enzyme was insensitive to inhibition by glucose (up to 5 mM). It also possessed catalytic ability of transglycosylation, as it could catalyze conversion of geraniol into its glucoside. MALDI-TOF assisted proteomic analysis revealed its high degree of sequence similarity with family 3 glycoside hydrolases.     

Characterization of β-lactamase activity using isothermal titration calorimetry

BackgroundHydrolysis of β-lactam antibiotic by β-lactamase is the most common mechanism of β-lactam resistance in clinical isolates. Timely detection and characterization of β-lactamases are therefore of utmost biomedical importance. Conventional spectrophotometric method is time-consuming and cannot provide thermodynamic information on β-lactamases.MethodsA new assay was developed for the study of β-lactamase activity in protein solutions (Metallo-β-lactamase L1) and in clinical bacterial cells, based on heat-flow changes derived from enzymatic hydrolysis of β-lactams using isothermal titration calorimetry.Results(1) The thermokinetic parameters of three antibiotics (penicillin G, cefazolin and imipenem) and the inhibition constant of an azolylthioacetamide inhibitor were determined using the calorimetric assay. The results from the calorimetric assays were consistent with the data from the spectrophotometric assay. (2) The values of heat change in the calorimetric assay using two clinical Escherichia coli strains correlated well with their antibiotic susceptibility results from the broth dilution experiment. The subtypes of β-lactamase were also determined in the calorimetric assay.ConclusionsThe ITC assay is a reliable and fast method to study β-lactamase enzyme kinetics and inhibition. It can also provide thermodynamic information on antibiotic hydrolysis, which has been taken advantage of in this work to study β-lactamase activity in two clinical Escherichia coli isolates.General significanceAs the first calorimetric study of β-lactamase activity, it may provide a new assay to assist biomedical validation of new β-lactamase inhibitors, and also has potential applications on rapid antibiotic susceptibility testing and screening β-lactamase producing bacteria.     

The characterization of phenylalanine ammonia-lyase from several plant species

Inhibition of the enzyme phenylalanine ammonia-lyase is considered as a target for the design of herbicides. A reliable and simple assay for the enzyme has been used and the kinetics of the enzyme from several sources compared. Purification of the enzyme from the grass green foxtail (Setaria glauca) did not change its kinetic behavior. The distribution of phenylalanine ammonia-lyase and tyrosine ammonia-lyase activity in various plant species was determined.     

Kinetic mechanism of the molecular forms of chicken liver mitochondrial malate dehydrogenase

• 1.1. The reaction kinetic mechanism (pH 7.4) of the molecular forms of chicken liver m-MDH is of the ordered bi-bi ternary complex type with the existence of the E-oxaloacetate, E-L-malate, E-NAD⁺ oxaloacetate, E-NADH-l-malate, E-NAD⁺-NADH, E-NAD⁺-NAD⁺, E-NADH-NAD⁺ and E-NADH-NADH abortive complexes.
• 2.2. The saturating concentration values of the substrates are notably modified, in certain cases, in the presence of the reaction products.