Determination of inorganic phosphate by flow injection method with immobilized enzymes and chemiluminescence detection

A flow injection method with chemiluminescence detection has been developed for the enzymatic determination of inorganic phosphate. Purine nucleoside phosphorylase, xanthine oxidase, and urate oxidase were immobilized on controlled-pore glass beads. Hydrogen peroxide released by the enzymatic reactions of phosphate and inosine in carrier buffer was detected by the luminol-microperoxidase system in a flow cell. The calibration graph was linear over the range of 5 to 250 pmol, and reproducibility was 1.75% at 10 pmol. The detection limit was 500 fmol of phosphate in 50 microliters of sample injected. The phosphate content in deoxyribonucleic acid was measured by this method.     

A generic assay for phosphate-consuming or -releasing enzymes coupled on-line to liquid chromatography for lead finding in natural products

A generic continuous-flow assay for phosphate-consuming or -releasing enzymes coupled on-line to liquid chromatography (LC) has been developed. Operating the LC-biochemical assay in combination with mass spectrometry allows the fast detection and identification of inhibitors of these enzymes in complex mixtures. The assay is based on the detection of phosphate, released by the on-line continuous-flow enzymatic reaction, using a fluorescent probe. The probe consists of fluorophore-labeled phosphate-binding protein, which shows a strong fluorescence enhancement upon binding to inorganic phosphate. To detect very small changes of the phosphate concentration in a postcolumn enzymatic reaction medium, the enzymatic removal of phosphate impurities from solvents, reagents, and samples was optimized for application in continuous flow. The potential of the phosphate probe is demonstrated by monitoring the enzymatic activity, i.e., the phosphate release, from alkaline phosphatase. The selectivity of the phosphate readout, necessary to distinguish between phosphate containing substrate or product and free inorganic phosphate released after enzymatic conversion, is shown. The applicability of LC coupled to the enzymatic assay using the phosphate readout was demonstrated by detection of tetramisole in a plant extract as inhibitor of alkaline phosphatase. Parallel mass spectrometry allowed the simultaneous confirmation of the identity of the inhibitor.     

Simultaneous determination of bile acids in rat liver tissue by high-performance liquid chromatography

A method for the simultaneous determination of bile acids in rat liver tissue by high-performance liquid chromatography was developed. Without prior fractionation and alkaline hydrolysis, 30 unconjugated, glycine- and taurine-conjugated bile acids were detected by post-column enzymatic reaction and fluorescence detection. They were separated on a reversed-phase column using a linear gradient solvent system of 10 mM tribasic ammonium phosphate–acetonitrile–methanol (44:12:5, v/v/v) and 20 mM dibasic ammonium phosphate–acetonitrile–methanol (2:1:2, v/v/v). The limits of detection were 1–5 pmol, and calibration curves were linear for concentrations ranging between 10 and 4000 pmol per 10 μl injection. This rapid and reliable method is effective for measuring bile acid levels in liver tissue not only of rats but also of patients with hepatobiliary and other diseases.     

Determination of in-vivo cytoplasmic orthophosphate concentration in yeast

Summary To investigate in-vivo concentrations of cytoplasmic phosphate, especially during dynamic conditions, a method has been developed that enables reproducible determination of cytoplasmic phosphate from 5 M up to 30 M. The method involves fast sampling, spontaneous inactivation of cell metabolism and differential extraction procedure to gain porosity of the outer cell membrane exclusively. To determine very low cytoplasmic phosphate concentrations, an enzymatic assay was linked to a sensitive spectrophotometric cycling method to increase the detection limit.     

Development and validation of a capillary electrophoresis method for the characterization of herpes simplex virus type 1 (HSV-1) thymidine kinase substrates and inhibitors

A fast, convenient capillary electrophoresis (CE) method was developed for monitoring the enzymatic reaction of herpes simplex virus type 1 thymidine kinase (HSV-1 TK). The reaction was performed in a test tube followed by quantitative analysis of the products. The optimized CE conditions were as follows: polyacrylamide-coated capillary (20 cm effective length x 50 microm), electrokinetic injection for 30s, 50 mM phosphate buffer at pH 6.5, constant current of -60 microA, UV detection at 210 nm, UMP or cAMP were used as internal standards. Phosphorylated products eluted within less than 7 min. The limits of detection were 0.36 microM for dTMP and 0.86 microM for GMP. The method was used to study enzyme kinetics, and to investigate alternative substrates and inhibitors.     

The biosensor based on the pyruvate oxidase modified conducting polymer for phosphate ions determinations

An enzymatic biosensor was fabricated by the covalent immobilization of pyruvate oxidase (PyO) onto the nano-particle comprised poly-5,2':5',2'-terthiophene-3'-carboxylic acid, poly-TTCA (nano-CP) layers on a glassy carbon electrode (GCE) for the amperometric detection of the phosphate ions. The direct electron transfer reaction of the immobilized PyO onto the nano-CP layers was investigated and the electron transfer rate constant was determined to be 0.65 s(-1). The electrochemically prepared nano-CP lowered the oxidation potential (+0.40 V versus Ag/AgCl) of an enzymatically generated H(2)O(2) by PyO in a phosphate solution. Experimental parameters affecting the sensitivity of the biosensors, such as amounts of the cofactors, the pH, the applied potential, and the temperature were optimized. A linear response for the detection of the phosphate ion was observed between 1.0 microM and 100 microM and the detection limit was determined to be about 0.3 microM. The response time of the biosensors was about 6s. The biosensor showed good selectivity towards other interfering anions. The long-term storage stability of the phosphate biosensor was studied and the sensor was applied in a human serum sample for the phosphate ions detection.     

An enzymatic fluorescent assay for the quantification of phosphite in a microtiter plate format

A sensitive fluorometric assay for the quantification of phosphite has been developed. The assay uses the enzymatic oxidation of phosphite to phosphate by a recombinant phosphite dehydrogenase with NAD⁺ as cosubstrate to produce the highly fluorescent reaction product resorufin. The optimized assay can be carried out in a 96-well microtiter plate format for high-throughput screening purposes and has a detection limit of 0.25 nmol phosphite. We used the method to quantify phosphite levels in plant tissue extracts and to determine phosphite dehydrogenase activity in transgenic plants. The assay is suitable for other biological or environmental samples. Because phosphite is a widely used fungicide to protect plants from pathogenic oomycetes, the assay provides a cost-effective and easy-to-use method to monitor the fate of phosphite following application.     

A new enzymatic method for the determination of inorganic phosphate and its application to the nucleoside diphosphatase assay

A new enzymatic method has been developed for the determination of inorganic phosphate, in which purine nucleoside phosphorylase and xanthine oxidase are used as indicator enzymes. This method has been applied to the assay of nucleoside diphosphatase. Incidental to this work, the apparent Michaelis constant of phosphate for calf spleen purine nucleoside phosphorylase was determined to be 0.25 mm, and the extinction coefficient of uric acid at 293 nm and pH 7.4 was found to be 13.0 × 10³m^?1 cm^?1.     

Non-chromogenic peptide substrates for detection of enzymes by means of capacitance changes at metal electrodes

A new type of substrate for enzyme detection has been developed. The substrate is non-chromogenic and is used in an assay method based on electrode adsorption. The rate of change in the electric capacitance of the electrode is monitored and taken as a measure of the substrate adsorption. Substrate adsorption is in turn proportional to substrate bulk concentration and thus subject to changes by enzymes. The new substrate introduces a new concept in enzyme detection: as it is non-chromogenic it may contain appropriate amino acids on both sides of the bond subject to enzymatic cleavage.     

A high-resolution, fluorescence-based method for localization of endogenous alkaline phosphatase activity.

We describe a high-resolution, fluorescence-based method for localizing endogenous alkaline phosphatase in tissues and cultured cells. This method utilizes ELF (Enzyme-Labeled Fluorescence)-97 phosphate, which yields an intensely fluorescent yellow-green precipitate at the site of enzymatic activity. We compared zebrafish intestine, ovary, and kidney cryosections stained for endogenous alkaline phosphatase using four histochemical techniques: ELF-97 phosphate, Gomori method, BCIP/NBT, and naphthol AS-MX phosphate coupled with Fast Blue BB (colored) and Fast Red TR (fluorescent) diazonium salts. Each method localized endogenous alkaline phosphatase to the same specific sample regions. However, we found that sections labeled using ELF-97 phosphate exhibited significantly better resolution than the other samples. The enzymatic product remained highly localized to the site of enzymatic activity, whereas signals generated using the other methods diffused. We found that the ELF-97 precipitate was more photostable than the Fast Red TR azo dye adduct. Using ELF-97 phosphate in cultured cells, we detected an intracellular activity that was only weakly labeled with the other methods, but co-localized with an antibody against alkaline phosphatase, suggesting that the ELF-97 phosphate provided greater sensitivity. Finally, we found that detecting endogenous alkaline phosphatase with ELF-97 phosphate was compatible with the use of antibodies and lectins. (J Histochem Cytochem 47:1443-1455, 1999)     

Enzymatic Treatment to Eliminate the Extracellular ATP for Improving the Detectability of Bacterial Intracellular ATP

A novel and effective treatment of biological samples with a combination of adenosine phosphate deaminase and apyrase was developed for reducing extracellular ATP, which has been a major problem encountered in improving the sensitivity of assays for intracellular ATP by the firefly luciferin–luciferase (L-L) method. Under the enzymatic reaction conditions, ATP and the related adenosine derivatives were converted to IMP, which are not active to the L-L system. In the model system (3.2 × 10⁻⁸mATP in 1% yeast extract solution) the treatment with adenosine phosphate deaminase resulted in the reduction of ATP to 1.3 × 10⁻¹¹m, and the concomitant use of apyrase lowered the concentration to 3.3 × 10⁻¹³m. The treatment (0.05 U/ml of adenosine phosphate deaminase and apyrase) was applied to the detection of bacteria in broth by the L-L method, affording the detection of 42 colony-forming unit (CFU)/ml ofEscherichia coliand 10 CFU/ml ofStaphylococcus aureusin the broth.     

Amperometric flow-injection determination of sucrose with a mediated tri-enzyme electrode based on sucrose phosphorylase and electrocatalytic oxidation of NADH

A new sucrose electrode is described for the determination of sucrose without interference from glucose or fructose. The sucrose electrode is based on the tri-enzymatic system of sucrose phosphorylase, phosphoglucomutase and glucose-6-phosphate 1-dehydrogenase, where NAD(P)H is produced from the last enzymatic reaction and recycled into NAD(P)+ through its electrocatalytic oxidation by Os(4,4'-dimethyl-2,2-bypyridine)2(1,10-phenanthroline-5,6-dione). The electrodes were optimised with respect to the various construction parameters and carrier composition in a FIA system and their response as a function of the pH and flow-rate was examined. The electrodes were suitable for operation in a FIA system and the analysis of real samples showed good agreement with the reference method. Typical optimised electrodes showed detection limits of 1 mM sucrose, response time of 5 min, sensitivity 1.010 nA mM(-1), and current density of 8.38 microA cm(-2), using 200 mM PIPES pH 7.25 with 10 mM phosphate and 5 mM MgCl2 as carrier.     

Rapid and selective enzymatic assay for l-methionine based on a pyrophosphate detection system

An enzymatic assay for l-methionine was developed by coupling adenosylmethionine synthetase (AdoMetS) to a pyrophosphate (PP_i) detection system, which was constructed using pyruvate, phosphate dikinase. To expand the use of this assay, the PP_i detection system was embodied as three different forms, which allowed PP_i to be measured by UV, visible, and fluorescent light detectors. The assay system was robust and could tolerate the addition of inorganic phosphate and ATP to the assay mixtures. l-Methionine could be accurately determined by coupling the PP_i detection system and AdoMetS. This AdoMetS coupling assay was highly selective to l-methionine and exhibited no significant activity to other proteinaceous amino acids, ammonia, or urea, unlike conventional enzymatic assays for l-methionine. Spike and recovery tests showed that the AdoMetS assay could accurately and reproducibly determine increases in l-methionine in human plasma samples without any pretreatment to remove proteins and potentially interfering low-molecular-weight molecules. The high selectivity and robustness of the AdoMetS assay provide rapid and high-throughput analysis of l-methionine in various kinds of analytes.     

A microassay for ATPase

A newly developed microtechnique for quantitating activity of myosin ATPase (EC 3.6.1.32) is more sensitive and less time-consuming than existing spectrophotometric methods. Measurement of ATPase activity using the new method can be accomplished in a final volume of 0.25 ml, allowing the assay to be conducted in individual wells of 96-well microplates commonly used for the enzyme-linked immunosorbent assay (ELISA). The microassay is performed by adding purified myosin to microplate wells followed by addition of ATP to initiate the enzymatic reaction. The reaction is subsequently terminated by addition of an acidic solution containing malachite green and ammonium molybdate. The level of inorganic phosphate produced by enzymatic hydrolysis of ATP is measured by scanning the microplates using a microELISA plate reader. An entire 96-well microplate can be scanned in less than 2 min, and data from the microassay can be transferred directly to a microprocessor for statistical analysis. The microassay is capable of detecting between 0.2 and 3 nmol of inorganic phosphate in a reaction volume of 50 microliter, and the ATPase activity of as little as 10 ng of rat cardiac myosin can be measured. The increased sensitivity compared with that of other spectrophotometric assays and ease of performing the microassay enable a detailed analysis of the enzymatic properties of cardiac myosin to be conducted on large numbers of small tissue specimens. Several kinetic properties of rat cardiac myosin were determined using this technique.     

Light microscopical demonstration of non-specific alkaline phosphatase activity with an incubation medium containing cerium and two calcium as the capturing agents. The cerium/calcium-hydrogen peroxide-P-phenylenediamine/pyrocatechol (Ce/Ca-H2O2-PPD/PC) double capture technique.

A new method for the light microscopical demonstration of alPase activity in cryotome sections by using simultaneously cerium and calcium as capturing agents (double capture technique) is described. This method has an increased sensitivity compared with the single cerium-based and the Gomori based-cerium (single calcium and cerium converted) with techniques described previously. Presuming that the enzymatic activity during incubation of sections in the presence of a defined capturing agent is constant, the increased sensitivity after employment of the double capture method could be attributed to a decrease of enzyme inhibition by cerium through the presence of calcium. Based on model experiments it is assumed that calcium phosphate and cerium phosphate are the primary reaction products, the former converting into cerium phosphate already during incubation. The remaining calcium phosphate is converted completely by treatment with cerium citrate solution (conversion reaction). After oxidation with H2O2 the cerium perhydroxyphosphate was visualized in a paraphenylenediamine/pyrocatechol (Hanker-Yates reagent) solution without H2O2 to give a black reaction product. This visualization procedure is superior to the DAB or DAB-Ni mode as published earlier. Some results concerning the mode of inhibition of the pseudoperoxidase activity of the hemoglobin are presented.     

AC voltammetric carbon paste-based enzyme immunosensors

Carbon paste electrodes, previously anodised in a basic media, are the basis for the development of a new voltammetric immunosensor device. Passive adsorption of the appropriate immunochemical reagent was performed onto the electrode surface. Alkaline Phosphatase labelled immunoglobulin was the tracer used in this work, 3-indoxyl phosphate being a very suitable enzymatic substrate for the electrochemical detection of the corresponding affinity reaction. The hydrolysis of this molecule generates indigo dimmer. This product was detected by alternating current voltammetry taking advantage of the adsorptive and inherent electrodic properties that it exhibits. The same electrochemical anodisation was used at the end of one assay to remove the entire protein layer attached to the carbon paste surface, allowing the formation of a new sensing phase and the use of the same support in several consecutive experiments. The methodology was applied to the design of two different immunoassays for the determination of human IgG. Good reproducibility of the electrodic signal and a limit of detection around 10⁻¹⁰ M were achieved.     

Non-radioactive labeling and detection of nucleic acids. I. A novel DNA labeling and detection system based on digoxigenin: anti-digoxigenin ELISA principle (digoxigenin system)

A novel highly sensitive non-radioactive DNA labeling and detection system based on the ELISA principle has been developed. DNA is modified with the cardenolide-hapten digoxigenin by enzymatic incorporation of digoxigenin-labeled deoxyuridine-triphosphate with Klenow enzyme. Digoxigenin is linked to dUTP via an 11-atom linear spacer (Dig-[11]-dUTP). Following hybridization of membrane-bound target-DNA with a digoxigenin-labeled probe, the hybrids are detected by an ELISA reaction using digoxigenin-specific antibodies covalently coupled to the marker enzyme alkaline phosphatase [(Dig):CIAP]. This binding of antibody: marker enzyme-conjugate is followed by an enzyme-catalysed coupled redox reaction with the colour substrates 5-bromo-4-chloro-3-indolyl phosphate (BCIP) and nitroblue tetrazolium salt (NBT) giving rise to a deep-blue coloured, water-insoluble precipitate directly adhering to the membrane. The digoxigenin system allows the detection of 0.1 pg homologous DNA within 16 h in dot- and Southern-blots on nitrocellulose or nylon membranes avoiding any significant background even after a prolonged period of color development. Due to its high sensitivity and specificity, the new system is appropriate for detection of single-copy genes in genomic blots as well as for Northern, slot, colony, plaque and in situ hybridizations.     

Concentrated,digestible DNA after hydroxylapatite chromatography with cetylpyridinium bromide precipitation

A method for the direct extraction of the DNA from the unfavorable phosphate eluant of hydroxylapatite chromatography is described. The DNA—reversibly precipitated with the cationic detergent cetylpyridinium bromide—can be subjected to further enzymatic manipulations within minutes. This method is applied to the rapid separation of pBR322 plasmid from the chromosomal DNA.     

Towards the protein phosphatase-based biosensor for microcystin detection

A colorimetric test for the detection of microcystins based on immobilised protein phosphatase (PP) has been developed. A PP2A produced by molecular engineering has been used and its performance has been compared to those of commercial PP2A and PP1. Covalent immobilisation of the enzyme using glutaraldehyde, encapsulation by sol-gel and entrapment with photocrosslinkable poly(vinyl alcohol) bearing styrylpyridinium groups (PVA-SbQ) have been compared, the latter method providing the highest immobilisation yields. Screen-printed carbon electrodes (SPEs), Maxisorp microtiter wells and Ultrabind modified polyethersulfone affinity membranes have been used as immobilisation supports. Whilst the highest immobilisation yields were obtained with microtiter wells, the highest operational and storage stabilities were achieved with carbon SPEs and membranes, respectively. The immobilisation of PP by PVA-SbQ provided a means to preserve the enzymatic activity, which decreased at fast rates when the enzyme was kept in solution. The colorimetric test using p-nitrophenyl phosphate has demonstrated that the immobilised enzyme is able to recognise both microcystin variants (MC-LR and MC-RR), although optimisation work should be performed to achieve appropriate limits of detection. With the purpose to develop an electrochemical biosensor, several phosphorylated substrates have been used. Promising results have been achieved with the commercial enzymes and alpha-naphtyl phosphate, p-aminophenol phosphate and catechol monophosphate as enzyme substrates, guaranteeing the viability of the electrochemical approach.     

A coupled optical enzyme assay for phosphopentomutase

Published assays for phosphopentomutase activity are based on acid lability differences between ribose 1-phosphate and ribose 5-phosphate. The present work describes a new method in which the isomerization of ribose 5-phosphate to ribose 1-phosphate is followed spectrophotometrically at 265 nm by coupling it with the following two-stage enzymatic conversion: ribose 1-phosphate + adenine ? phosphate + adenosine (adenosine phosphorylase); adenosine + H₂O → inosine + NH₃ (adenosine deaminase). The method has been used to show some properties of Escherichia coli phosphopentomutase.