A semi-integrated method for the determination of enzyme kinetic parameters and graphical representation of the Michaelis-Menten equation

A semi-integrated method for the determination of the enzyme kinetics parameters (Km and V) and graphical representation of the Michaelis-Menten equation is proposed as a variation of determination of initial reaction rate (v) as a function of initial substrate concentration ([S]0). The method is based on the determination of the time required to exhaust half of the initial substrate concentration as a function of the initial substrate concentration. The advantages and limitations of this method are discussed.     

A Procedure for gluconic acid synthesis with bacteria made continuous by means of an auxiliary substrate

A method is introduced which makes a continuous oxidation of glucose to glucose acid possible. This method is based on the auxiliary-substrate concept and co-metabolism, respectively. Micro-organisms (e.g. Acinetobacter calcoaceticus), which cannot assimilate glucose, but merely oxidize it, are grown continuously on a heterotrophic substrate (e.g. acetate). While growing they simultaneously synthesize gluconic acid. The productivity of the gluconic acid synthesis with a given strain depends on the dilution rate and the mixing proportion. Since growth and product synthesis are closely connected and growth yield is very much higher due to an auxiliary substrate effect in the presence of glucose than on the heterotrophic substrate alone, this method is suitable for SCP production as well. The productivity of gluconic acid production is controlled at a certain dilution rate by the mixing proportion of the growth substrate and glucose.     

The Michaelis constants of a nonchromogenic substrate may be determined using a chromogenic substrate

A general method is presented for the determination of the KM and Vmax for a nonchromogenic substrate in an experimental system where a chromogenic and a nonchromogenic substrate compete for the active site of a single enzyme. Entire progress curves of absorbance versus time for the transformation of the chromogenic substrate must be obtained in the absence and presence of the nonchromgenic substrate. Two quantities may then be extracted from the entire kinetic curves: the value of a delta Area, the area bounded by the kinetic traces of absorbance versus time in the presence and absence of the nonchromogenic substrate; and the value of delta t(5%), the time required to transform 5% of the chromogenic substrate in the presence of the nonchromogenic substrate minus the corresponding time required in its absence. The values of KM and Vmax for the nonchromogenic substrate may be obtained from the dependencies of delta Area and delta t(5%) upon the concentration of the nonchromogenic substrate. The ability of this procedure to yield the correct values of KM and Vmax was demonstrated using beta-lactamase, beta-galactosidase, alkaline phosphatase, and 19 chromogenic/nonchromogenic substrate pairs. This method is equally valid in the absence or presence of competitive product inhibition and should be applicable to any enzyme-catalyzed, strongly exergonic reaction.     

Comparison of methods for following alkaline phosphatase catalysis: spectrophotometric versus amperometric detection

An amperometric method for alkaline phosphatase is described and compared to the most widely used spectrophotometric method. Catalytic hydrogenation of 4-nitrophenylphosphate (the substrate in the spectrophotometric method) gives 4-aminophenylphosphate (the substrate in the amperometric method). The latter substrate has the formula C6H6NO4PNa2.5H2O and a Mr of 323. The Michaelis constant for 4-aminophenylphosphate in 0.10 M, pH 9.0. Tris buffer is 56 microM, while it is 82 microM for 4-nitrophenyl phosphate. The amperometric method has a detection limit of 7 nM for the product of the enzyme reaction, which is almost 20 times better than the spectrophotometric method. Similarly, with a 15-min reaction at room temperature and in a reaction volume of 1.1 ml, 0.05 microgram/l alkaline phosphatase can be detected by electrochemistry, almost an order of magnitude better than by absorption spectrophotometry. Amperometric detection is ideally suited for small-volume and trace immunoassay.     

Fluorescence-based high-throughput assay for human DNA (cytosine-5)-methyltransferase 1

We have developed the first economical and rapid nonradioactive assay method that is suitable for high-throughput screening of the important pharmacological target human DNA (cytosine-5)-methyltransferase 1 (DNMT1). The method combines three key innovations: the use of a truncated form of the enzyme that is highly active on a 26-bp hemimethylated DNA duplex substrate, the introduction of the methylation site into the recognition sequence of a restriction endonuclease, and the use of a fluorogenic read-out method. The extent of DNMT1 methylation is reflected in the protection of the DNA substrate from endonuclease cleavage that would otherwise result in a large fluorescence increase. The assay has been validated in a high-throughput format, and trivial changes in the substrate sequence and endonuclease allow adaptation of the method to any bacterial or human DNA methyltransferase.     

Radioactive-electrophoretic assay of adenosine 5'-triphosphate sulfurylase activity in crude extracts with sulfate or selenate as a substrate

An assay method for ATP sulfurylase is presented which employs Na2(35)SO4 as a substrate and measures the production of labeled adenosine 5'-phosphosulfate and 3'-phosphoadenosine 5'-phosphosulfate by low-voltage, hanging paper strip electrophoresis. The method is applicable to crude bacterial or mammalian extracts and accurately measures picomole amounts of product(s). Na2(75SeO4 can also be employed as a substrate, if the unstable radioactive product, adenosine 5'-phosphoselenate, is converted to elemental 75Se degrees by inclusion of reduced glutathione in the reaction mixture. The same paper strip electrophoretic technique can then be used to separate 75Se degrees from the radiolabeled substrate. The method also has utility for measuring any direct reduction by crude microbial extracts of radioactive selenate to selenite, independent of ATP sulfurylase.     

Internal thermodynamics of enzymes determined by equilibrium quench: values of Kint for enolase and creatine kinase

The equilibrium constant (Kint) for the enzyme-bound substrate and product of a one substrate/one product enzyme (enolase) and for those of a two substrate/two product enzyme (creatine kinase) have been determined. The values of Kint were determined by the rapid quenching of equilibrium mixtures of enzyme and radiolabeled substrate and product, under conditions where all of the marker substrate and product are bound. The scope and limitations of this method are discussed. Values of Kint have been collected from the literature, and it is shown that these data are consistent with the theory for kinetically optimized enzymes that is developed in the preceding paper.     

A microassay for the peptidase activity of enzymes utilizing ribonuclease S peptide as a substrate

A microassay for the peptidase activity of proteins obtained in minute amounts was devised. The method uses ribonuclease S peptide as a substrate. The substrate when cleaved is unable to reconstitute an active ribonuclease S complex. Therefore the loss in activity of the reconstituted complex is a measure of the peptidase activity. The method was previously tested with known peptidases such as clastase (9), chymotrypsin (8), and trypsin. In this work the peptidase activity of a protein related to a sperm-decapitating factor (1) is evidenced.     

High-throughput kinase assay based on surface plasmon resonance suitable for native protein substrates

We report a novel in vitro high-throughput (HTP) kinase assay using surface plasmon resonance (SPR). In vitro tyrosine phosphorylation was performed in a microtiter plate, after which the substrate was captured with an antibody on a sensor chip and phosphotyrosine (pTyr) was detected with an anti-pTyr antibody. The capture and pTyr detection steps were performed using a Biacore A100, which is a sensitive and high-performance flow-cell-based SPR biosensor. This system allowed multiple sample processing (1000 samples/day) and high-quality data sampling. We compared the abilities of the HTP-SPR method and a standard radioisotope assay by measuring the phosphorylation of several substrate proteins by the Fyn tyrosine kinase. Similar results were obtained with both methods, suggesting that the HTP-SPR method is reliable. Therefore, the HTP-SPR method described in this study can be a powerful tool for a variety of screening analyses, such as kinase activity screening, kinase substrate profiling, and kinase HTP screening of kinase inhibitors.     

Accurate automatic determination of acid phosphatase substrate saturation curves

An automatic method for the determination of acid phosphatase substrate saturation curves is described; the curves are recorded continuously in a Technicon AuteAnalyzer in which the enzyme, at a constant pH, reacts with a gradient of substrate made using the equalized continuous flow rate technique in a closed vessel. A slightly modified method for the determination of the substrate saturation curves on the same enzyme in cell suspension, by continuous dialysis, is also reported. The method is highly accurate and makes it possible to evaluate very small kinetic variations.     

Determination of peptidylglycine alpha-amidating monooxygenase activity in human serum by thin-layer chromatography

We developed a simple assay system for the quantitative evaluation of peptidylglycine alpha-amidating monooxygenase activity using as substrate a 125I-labeled synthetic tripeptide, 125I-D-Tyr-Val-Gly, thin-layer chromatography, and a radiochromatoscanner. The basic principle of this method is that thin-layer chromatography separates the reaction product, 125I-D-Tyr-Val-NH2, from the substrate in an assay mixture. The 125I activities of both substrate and product separated from each other on a thin-layer chromatography plate were quantified with a radiochromatoscanner and the rate of conversion of the substrate to the product was calculated from their counts. Human serum was used as an enzyme source and the values of alpha-amidation activity obtained by our method under optimal conditions were almost identical to those of the published method using ion-exchange chromatography (sulphopropyl-Sephadex C-50 column) and a gamma-counter. Our method makes it possible to estimate the 10-pmol level of the product using 10 microliters of human serum and to assay a large number of samples rapidly and easily. It is therefore thought to be very useful for screening various tissues for alpha-amidation activity.     

Calculation of Km and Vmax from Substrate Concentration Versus Time Plot

A simple method for the calculation of kinetic parameters (K_m, V_max) under conditions of changing substrate concentrations is presented. An application of the method to detect shifts in groups involved in the utilization of a substrate in a mixed microbial culture is given.     

Intrinsic kinetic parameters of substrate utilization by immobilized anaerobic sludge

This article presents a method for evaluating the intrinsic kinetic parameters of the specific substrate utilization rate (r) equation and discusses the results obtained for anaerobic sludge-bed samples taken from a horizontal-flow anaerobic immobilized sludge (HAIS) reactor. This method utilizes a differential reactor filled with polyurethane foam matrices containing immobilized anaerobic sludge which is subjected to a range of feeding substrate flow rates. The range of liquid superficial velocities thus obtained are used for generating data of observed specific substrate utilization rates (r(obs)) under a diversity of external mass transfer resistance conditions. The r(obs) curves are then adjusted to permit their extrapolation for the condition of no external mass transfer resistance, and the values determined are used as a test for the condition of absence of limitation of internal mass transfer. The intrinsic parameters r(max), the maximum specific substrate utilization rate, and K(s), the half-velocity coefficient, are evaluated from the r values under no external mass transfer resistance and no internal mass transfer limitation. The application of such a method for anaerobic sludge immobilized in polyurethane foam particles treating a glucose substrate at 30 degrees C resulted in intrinsic r(max) and K(s), respectively, of 0.330 mg chemical oxygen demand (COD) . mg(-1) volatile suspended solids (VSS) . h(-1) and 72 mg COD . L(-1). In comparison with the values found in the literature, intrinsic r(max) is significantly high and intrinsic K(s) is relatively low. (c) 1997 John Wiley & Sons, Inc.     

Specific small nuclear RNAs are associated with yeast spliceosomes

Two different methods have been devised for the analysis and purification of spliceosomes formed in a yeast in vitro splicing system. The first method relies on the electrophoretic separation of ribonucleoprotein particles in composite acrylamide-agarose gels. A large fraction of added substrate is located in spliceosomes, the formation of which can be shown to be dependent on the presence of both a yeast 5' splice junction and a TACTAAC box on the RNA substrate. The second method relies on oligo(dT)-cellulose chromatography of spliceosomes formed with a polyadenylated substrate. Purification of spliceosomes by either method indicates that at least three small nuclear RNAs, approximately 160, 185, and 215 nucleotides in length, are specifically associated with yeast spliceosomes.     

Enzyme kinetics: partial and complete uncompetitive inhibition

A graphical method for analysing enzyme data to obtain kinetic parameters, to identify the types of inhibition and the enzyme mechanisms is described. The method consists of plotting experimental data as v/(V(0)-v) versus 1/(I) at different substrate concentrations. I is the inhibitor concentration; V(0) and v are the initial rates of enzyme reaction attained by the system in the presence of a fixed amount of substrate and in the absence and presence of inhibitor respectively. Complete inhibition gives straight lines that pass through the origin while partial inhibition gives straight lines that converge on the 1/I-axis at a point away from the origin. With uncompetitive inhibition the slopes of the lines decrease with increasing substrate concentration. The kinetic parameters K(m), K'(i) and beta (degree of partiality) can best be determined from respective secondary plots of slope and intercept versus reciprocal of substrate concentration.     

β-Galactosidase activity assay using far-red-shifted fluorescent substrate DDAOG

β-Galactosidase (β-gal) is commonly used as a reporter gene in biological research, and a wide variety of substrates have been developed to assay its activity. One substrate, 9H-(1,3-dichloro-9,9-dimethylacridin-2-one-7-yl) β-d-galactopyranoside (DDAOG), can be cleaved by β-gal to produce 7-hydroxy-9H(I,3-dichloro-9,9-dimethylacridin-2-one) (DDAO). On excitation, DDAO generates a far-red-shifted fluorescent signal. Using this substrate, we developed a β-gal activity assay method. The DDAO signal was stable for at least 18 h. The signal intensity was linearly related to both the enzyme amount and substrate concentration. An optimized buffer for the β-gal/DDAOG assay was also formulated. When compared with the colorimetric substrate o-nitrophenyl-β-d-galactopyranoside (ONPG), the signal-to-background ratio of the DDAOG method was approximately 12-fold higher. The β-gal/DDAOG assay method was also tested in transiently transfected cells employing both pharmacologically and genetically inducible gene expression systems. The ability to detect signal induction is comparable to a similar assay using luciferase as the signal generating moiety. The β-gal/DDAOG assay method should provide a fluorescent reporter assay system for the wide variety of β-gal systems currently in use.     

Investigation of soluble mitochondrial ATPase by the reacting enzyme sedimentation method.

Soluble mitochondrial ATPase from bovine heart (factor F1) loses its activity during ATP hydrolyses. The inactivation is accelerated by moderate pressure, which is generated in an ultracentrifuge cell. The rate of inactivation slows down if the concentration of the substrate (MgATP) is diminished. ATP hydrolysis proceeds at an almost constant rate if the substrate concentration is as low as 0.05 mM. One intersubunit cross-link formed by dimethylsuberimidate per molecule of factor F1, prevents its inactivation during the ATPase reaction both without pressure and in an ultracentrifuge. Sedimentation coefficients measured by the reacting enzyme centrifugation method of both unmodified factor F1 at a low (about 0.05 mM MgATP) substrate concentration and of its dimethylsuberimidate cross-linked form in the presence of 10 mM MgATP, were determined to be s20, w = 12.4 +/- 0.4 S. The value is the same as that obtained by the conventional boundary sedimentation method in the absence of the substrate. This result testifies to the fact that the conformation of reacting factor F1 in solution is similar to that of the enzyme in the absence of the substrate.     

A rapid purification method for neurogranin, a brain specific calmodulin-binding protein kinase C substrate

A rapid purification method is reported for bovine brain neurogranin, a calmodulin-binding protein kinase C (PKC) substrate. This method takes advantage of the fact that the protein remains soluble in 2.5% perchloric acid (PCA) and that it binds to a calmodulin-Sepharose column in the absence of calcium: Other PKC substrate proteins that remain to be identified were also found to share these two properties, suggesting that a class of calmodulin-binding PKC substrates may exist in the brain.     

A colorimetric assay for S-adenosylhomocysteine hydrolase

A colorimetric method for S-adenosyl-L-homocysteine hydrolase (SAHase) which uses S-adenosyl-L-homocysteine (SAH) as substrate is described. This method involves the hydrolytic conversion of SAH into adenosine (ADO) and L-homocysteine (HCY). The formation of HCY is quantified using Ellman's reagent and spectrophotometrical measured at 412 nm. Under these assay conditions, the product was followed continuously in a facile and quantitative manner until substrate conversion was complete. This method is an easy, cheap and shorter alternative to more complex methods and it is applicable to routine clinical analysis and in the assay and development of new S-nucleosidylhomocysteines to be used as therapeutic compounds.     

HPLC and LC-MS studies of hydroxylation of phenylalanine as an assay for hydroxyl radicals generated from Udenfriend's reagent

An HPLC assay method and an LC-MS method were used to study the Udenfriend reaction and its variations by using phenylalanine as the hydroxylation substrate. The results indicate that (1). citric acid can replace EDTA as the promoter for the production of hydroxyl radicals in the Undenfriend reaction, albeit in a somewhat less efficient way, (2). dihydroxylation of the hydroxylation substrate, phenylalanine, readily occurs with the Udenfriend systems (with either EDTA or citric acid), and (3). a novel oxidative degradation pathway may exist for o-tyrosine. It is cautioned that dihydroxylation needs to be accounted for when interpreting hydroxylation results in HPLC-based HO(z.rad;) assay systems with phenylalanine as the substrate.