Application of a bioluminescence ATP assay in brewery wastewater treatment studies

The importance of having a rapid method for determining the viable biomass in activated-sludge wastewater treatment plants (WWTP) for process control and development is well recognized. The firefly bioluminescence ATP assay has been proposed for this purpose. Such an assay using partially purified firefly luciferase and synthetic firefly luciferin for the bioluminescence reaction, a liquid scintillation counter in the out-of-coincidence mode as luminescence detector, and a sludge ATP extraction technique involving dimethyl sulfoxide at room temperature is described. Experiments with several pure bacteria cultures were done to demonstrate the feasibility of applying this assay to activated sludge to activated sludge WWTP investigation and control. The ATP content of samples taken from various points in a 350000 gal/day brewery activated-sludge WWTP was monitored for 4.5 months. Good linear correlation between ATP and mixed-liquor suspended solids, return sludge suspended solids, and effluent suspended solids were observed. Percentage viabilities of the various sludge samples were derived from the ATP results.     

DNA glycosylase activity assay based on streptavidin paramagnetic bead substrate capture.

A method to detect DNA glycosylase activity is described. The substrate used was an oligodeoxyribonucleotide with a unique hypoxanthine base, but has general application to any DNA glycosylase or endonuclease. The oligodeoxyribonucleotide was labeled at the 5' end with 32P and at the 3' end with a biotin linkage and annealed to a complementary oligodeoxyribonucleotide. The hypoxanthine base was excised in solution using the MPG protein, a human DNA glycosylase. Following cleavage of the phosphodiester linkage by NaOH, the oligodeoxyribonucleotide was attached to streptavidin-coated, paramagnetic beads. Binding of the labeled oligodeoxyribonucleotide to the beads was indicative of the kinetics of the reaction. As a control, half of the reaction products were loaded on to a denaturing polyacrylamide gel. Comparable values for steady-state kinetic constants were obtained using both methods. This nonelectrophoretic technique is a rapid assay of DNA glycosylase activity for both purified proteins and crude extracts. This method can be directly adapted for high-throughput techniques.     

Firefly luciferase luminescence assays using scintillation counters for quantitation in transfected mammalian cells

The firefly enzyme luciferase catalyzes the luminescent reaction of luciferin with ATP and oxygen. The luciferase gene has recently been cloned and proposed as a reporter gene in procaryotic and eucaryotic cells. We present here a luciferase activity assay which relies on luminescence detection using a standard scintillation counter. This technique is simple, fast, inexpensive, and still very sensitive: as little as 0.02 pg (250,000 molecules) of enzyme is readily detected. The technique is optimized for the luciferase assay in mammalian cell lysates. Thus, the luciferase gene may become a very useful tool for gene regulation studies.     

Effects of divalent ions on vesicle-vesicle fusion studied by a new luminescence assay for fusion

Summary A new assay has been developed for vesicle-vesicle fusion based upon the mixing of intravesicular contents of two sets of vesicles. Purified firefly luciferase and MgCl₂ were incorporated into one set of vesicles (LV) and ATP into the other (AV). Vesicles were prepared from soybean phospholipids. The luminescence that resulted from hydrolysis of ATP by luciferase was measured to determine the extent of mixing of the intravesicular contents. In the absence of divalent ions, incubation of a mixture of LV and AV did not produce luminescence. However, if Ca⁺⁺ or other divalent ions were present at millimolar concentrations, luminescence occurred. The luminescence did not result from extravesicular reaction of vesicle contents that had leaked into the medium. Instead, luminescence resulted from the mixing of intravesicular spaces of AV and LV in fused vesicles. Optical density changes and negative stain electron microscopy indicated that Ca⁺⁺ induced extensive aggregation of vesicles. However, quantitation of the maximum possible luminescence indicates that only a small percentage (less than 1%) of the vesicles actually fused in a fusion experiment.Addition of EDTA to chelate Ca⁺⁺ after luminescence had been induced resulted in a two-to threefoldincrease in light emission which then rapidly decayed. These results suggest that the sudden removal of Ca⁺⁺ caused a transient increase in fusion after which subsequent fusion was inhibited. It was also found that the vesicles were relatively stable to hypotonic solutions.     

A chromism-based assay (CHROBA) technique for in situ detection of protein kinase activity

A unique chromism-based assay technique (CHROBA) using photochromic spiropyran-containing peptides has been firstly established for detection of protein kinase A-catalyzed phosphorylation. The alternative method has advantages that avoid isolation and/or immobilization of kinase substrates to remove excess reagents including nonreactive isotope-labeled ATP or fluorescently-labeled anti-phosphoamino acid antibodies from the reaction mixture. Such a novel protocol based on thermocoloration of the spiropyran moiety in the peptide can offer not only an efficient screening method of potent kinase substrates but also a versatile analytical tool for monitoring other post-translational modification activities.     

Solvent comparison in the isolation, solubilization, and toxicity of Stachybotrys chartarum spore trichothecene mycotoxins in an established in vitro luminescence protein translation inhibition assay

It is well known that non-viable mold contaminants such as macrocyclic trichothecene mycotoxins of Stachybotrys chartarum are highly toxinigenic to humans. However, the method of recovering native mycotoxin has been without consensus. Inconsistencies occur in the methods of isolation, suspension, preparation, and quantitation of the mycotoxin from the spores. The purpose of this study was to provide quantitatively comparative data on three concurrent preparations of 10(6)S. chartarum spores. The experiments were designed to specifically evaluate a novel method of mycotoxin extraction, solubilization, and the subsequent inhibitory effect in an established in vitro luminescence protein translation assay from 30 day-old spores. The mycotoxin-containing spores swabbed from wallboard cultures were milled with and without glass beads in 100% methanol, 95% ethanol, or water. Milled spore lysates were cleared of cell debris by filter centrifugation followed by a second centrifugation through a 5000 MWCO filter to remove interfering proteins and RNases. Cleared lysate was concentrated by centrivap and suspended in either alcohol or water as described. The suspensions were used immediately in the in vitro luminescence protein translation assay with the trichothecene, T-2 toxin, as a control. Although, mycotoxin is reported to be alcohol soluble, the level of translation inhibition was not reliably satisfactory for either the methanol or ethanol preparations. In fact, the methanol and ethanol control reactions were not significantly different than the alcohol prepared spore samples. In addition, we observed that increasing amounts of either alcohol inhibited the reaction in a dose dependent manner. This suggests that although alcohol isolation of mycotoxin is desirable in terms of time and labor, the presence of alcohol in the luminescence protein translation reaction was not acceptable. Conversely, water extraction of mycotoxin demonstrated a dose dependent response, and there was significant difference between the water controls and the water extracted mycotoxin reactions. In our hands, water was the best extraction agent for mycotoxin when using this specific luminescence protein translation assay kit.     

A multienzyme bioluminescent time-resolved pyrophosphate assay

We have developed a high-sensitivity assay for measurement of inorganic pyrophosphate (PPi) in adenosine 5'-triphosphate (ATP)-contaminated samples. The assay is based on time-resolved measurements of the luminescence kinetics and implements multiple enzymes to convert PPi to ATP that is, in turn, utilized to produce light and to hydrolyze PPi for measurement of the steady state background luminescence. A theoretical model for describing luminescence kinetics and optimizing composition of the assay detection mixture is presented. We found that the model is in excellent agreement with the experimental results. We have developed and evaluated two algorithms for PPi measurement from luminescence kinetics acquired from ATP-contaminated samples. The first algorithm is considered to be the method of choice for analysis of long, i.e., 3-5 min, kinetics. The activity of enzymes is controlled during the experiment; the sensitivity of PPi detection is about 7 pg/ml or 15 pM of PPi in ATP-contaminated samples. The second algorithm is designed for analysis of short, i.e., less than 1-min, luminescence kinetics. It has about 20 pM PPi detection sensitivity and may be the better choice for assays in microplate format, where a short measurement time is required. The PPi assay is primarily developed for RNA expression analysis, but it also can be used in various applications that require high-sensitivity PPi detection in ATP-contaminated samples.     

Luminescent immobilized enzyme test systems for inorganic pyrophosphate: assays using firefly luciferase and nicotinamide-mononucleotide adenylyl transferase or adenosine-5'-triphosphate sulfurylase.

Inorganic pyrophosphate was measured by luminescence produced by a pyrophosphatase (NAD adenylyl-transferase or ATP sulfurylase) coimmobilized with firefly luciferase on Sepharose beads, with continuous flow of saturating concentrations of substrates (NAD plus luciferin or adenylophosphosulfate plus luciferin, respectively) and intermittent injections of samples containing pyrophosphate. In this scheme, the limiting substrate (pyrophosphate) is regenerated, a situation that is well suited to a bioluminescent assay. The instrumentation allowed for automation with a through-put of approximately one sample every 4 min. With standard solutions or samples that do not contain ATP, the sensitivity of the assay permits detection of less than 1 pmol pyrophosphate in a volume of 20 microliters (50 nmol/liter) with a coefficient of variation approximately equal to 4%. To assay biological samples, it was shown that endogenous ATP can be inactivated by oxidation with sodium periodate. Periodate treatment and quenching engenders dilution that limits the sensitivity to approximately 600 nmol/liter pyrophosphate in the starting material. The assay has been applied to the determination of intracellular pyrophosphate in human lymphocytes and to the measurement of nucleoside-triphosphate pyrophosphohydrolase in human fibroblasts. The variability of the assay was greater with biological samples than with standard samples, with a coefficient of variation of 15.3% in a series of determinations of intracellular pyrophosphate in a series of replicate lymphocyte lysates. Bioluminescent systems of coupled coimmobilized enzymes offer great promise for sensitive, safe, automated assaying of metabolites.     

Characterization of an intracellular ATP assay for evaluating the viability of live attenuated mycobacterial vaccine preparations

The viability of BCG vaccine has traditionally been monitored using a colony-forming unit (CFU) assay. Despite its widespread use, results from the CFU assay can be highly variable because of the characteristic clumping of mycobacteria, their requirement for complex growth media, and the three week incubation period needed to cultivate slow-growing mycobacteria. In this study, we evaluated whether an ATP luminescence assay (which measures intracellular ATP content) could be used to rapidly estimate the viability of lyophilized and/or frozen preparations of six different BCG vaccine preparations - Danish, Tokyo, Russia, Brazil, Tice, and Pasteur - and two live attenuated mycobacterial vaccine candidates - a ΔlysAΔpanCD M. tuberculosis strain and a ΔmmaA4 BCG vaccine mutant. For every vaccine tested, a significant correlation was observed between intracellular ATP concentrations and the number of viable attenuated bacilli. However, the extractable intracellular ATP levels detected per cell among the different live vaccines varied suggesting that validated ATP luminescence assays with specific appropriate standards must be developed for each individual live attenuated vaccine preparation. Overall, these data indicate that the ATP luminescence assay is a rapid, sensitive, and reliable alternative method for quantifying the viability of varying live attenuated mycobacterial vaccine preparations.     

利用ATP扩增反应与生物发光法结合检测微量微生物

摘要:【目的】腺苷酸激酶（adenylate kinase, ADK）和多聚磷酸盐激酶（polyphosphate kinase, PPK）偶联催化的ATP扩增反应结合生物发光检测法能够对微量微生物进行检测。但是PPK当中结合的内源性的ADP会产生背景干扰,影响测定。本文旨在融合表达ADK和PPK,并建立一种方便有效的内源性ADP的去除方法,降低背景,使之与传统生物发光法结合,实现高灵敏生物发光法检测微量ATP及微生物。【方法】PCR扩增得到PPK、ADK基因,插入表达载体pET28a (+)中构建重组表达质粒pET28a (+)-PPKADK,表达PPK-ADK融合蛋白。利用表面包裹聚胺醇（Polyurethane）的磁珠（magnetic beads）,通过化学反应将腺苷酸双磷酸酶（apyrase）固定于磁珠表面,制备固相腺苷酸双磷酸酶（Beads-apyrase）,用于除去与融合蛋白结合的内源性ADP,降低ATP扩增反应的背景,从而使之与生物发光反应相结合,测定微量外源ATP及细菌菌落数。【结果】表达的融合蛋白具有PPK和ADK的活性,利用Beads-apyrase可以方便而有效的去除内源性ADP,显著地降低反应背景,从而实现了利用ATP扩增反应与传统生物发光反应结合,测定了小于1 fmol的外源微量ATP,使生物发光法检测ATP及微生物的灵敏度提高至少100倍。【结论】利用Beads-apyrase能够方便、有效地降低PPK-ADK中的ADP背景,从而使PPK-ADK催化的ATP扩增反应能够与传统生物发光法相结合,极大地提高了生物发光法的灵敏度。     

An enzymatic cycling method using pyruvate orthophosphate dikinase and firefly luciferase for the simultaneous determination of ATP and AMP (RNA)

A novel bioluminescent enzymatic cycling assay for ATP and AMP with concomitant use of firefly luciferase and pyruvate orthophosphate dikinase (PPDK) was developed. In this system, AMP and pyrophosphate produced from ATP by firefly luciferase were converted back into ATP by PPDK. This resulted in constant luminescence once the stable phase had been reached. Background luminescence of the reagent was reduced with adenosine phosphate deaminase by degrading ATP and AMP in the reagent. The maximum recycling ratio calculated from the integrated luminescence value was 2.64 cycles/min. The measurable ranges for ATP and AMP were equal and were between 4 x 10(-13) and 4 x 10(-17) mol/assay. The amount of yeast RNA could be estimated in the range of 1 x 10(-8) to 1 x 10(-12) g/assay by estimating the amount of AMP resulting from the degradation of RNA with nuclease P1. Various food samples were subjected to measurement of the amount of ATP + AMP + RNA to provide an index for hygiene monitoring. For beef extract, sensitivity was improved by more than 20 million compared to the previous methods relying only on the amount of ATP as an index.     

Affinity-tagged phosphorylation assay by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (ATPA-MALDI): application to calcium/calmodulin-dependent protein kinase

A matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS)-based kinase assay using a peptide substrate tagged with a biotinyl group has been developed. The peptide moiety was designed to serve as an efficient substrate for calcium/calmodulin-dependent protein kinase II, based on the in vivo phosphorylation site of phosrestin I, a Drosophila homolog of arrestin. In the assay, the quantitative relationship was determined from the ratio of the peak areas between the two peaks respectively representing the unphosphorylated and the phosphorylated substrate. Attempts to assay phosphorylated peptides directly from the reaction mixture, gave inaccurate results because of the high noise level caused by the presence of salts and detergents. In contrast, after purifying the substrate peptides with the biotin affinity tag using streptavidin-coated magnetic beads, peak areas accurately represented the ratio between the unphosphorylated and phosphorylated peptide. By changing the substrate peptide to a peptide sequence that serves as a kinase substrate, it is expected that an efficient non-radioactive protein kinase assay using MALDI-TOF MS can be developed for any type of protein kinase. We call this technique "Affinity-Tagged Phosphorylation Assay by MALDI-TOF MS (ATPA-MALDI)." ATPA-MALDI should serve as a quick and efficient non-radioactive protein kinase assay by MALDI-TOF MS.     

Assay of adenosine 3', 5' cyclic monophosphate by stimulation of protein kinase: a method not involving radioactivity

In order to meet a need for a cAMP assay which is not subject to interference by compounds in plant extracts, and which is suitable for use on occasions separated by many ³²P half-lives, an assay based on cAMP-dependent protein kinase has been developed which does not require the use of [γ-³²P]ATP. Instead of measuring the cAMP-stimulated increase in the rate of transfer of [γ-³²P] phosphate from [γ-³²P]ATP to protein, the rate of loss of ATP from the reaction mixture is determined. The ATP remaining after the protein kinase reaction is assayed by ATP-dependent chemiluminescence of the firefly luciferin-luciferase system. Under conditions of the protein kinase reaction in which a readily measurable decrease in ATP concentration occurs, the logarithm of the concentration of ATP decreases in proportion to the cAMP concentration, i.e., the reaction can be described by the equation: [ATP] = [ATP]₀ e^?[cAMP]kt. The assay based on this relationship can detect less than 1 pmol of cAMP. The levels of cAMP found with this assay after partial purification of the cAMP from rat tissue, algal cells, and the media in which the cells were grown agreed with measurements made by the cAMP binding-competition assay of Gilman, and the protein kinase stimulation assay based on transfer of [³²P] phosphate from [γ-³²P]ATP to protein. All of the enzymes and chemicals required for the assay of cAMP by protein kinase catalyzed loss of ATP can be stored frozen for months, making the assay suitable for occasional use.     

Cyclic 3′,5′-nucleotide phosphodiesterase: A continuous titrimetric assay

A direct and continuous assay for cyclic 3′,5′-nucleotide phosphodiesterase has been developed. This method is based on the fact that the phosphate group of adenosine 3′,5′-phosphate has one titratable species whereas that of 5′-adenosine monophosphate has two. Hydrolysis of cyclic AMP to 5′-AMP by phosphodiesterase is accompanied by a stoichiometric generation of protons. The rate of addition of an alkaline solution to the reaction mixture to maintain a constant pH with a pH stat is thus stoichiometrically related to the rate of cyclic AMP hydrolysis. A reaction producing 10 mμmoles of H⁺ or more per minute in 1.5 ml of reaction mixture is accurately measured by this technique. Duplicates are usually within 5% of each other. Results obtained by the titrimetric method correlate well with those obtained by conventional methods. This technique has been successfully used to assay phosphodiesterase of bovine brain in the purified as well as the crude stage.     

Structures of manganese(II) complexes with ATP, ADP, and phosphocreatine in the reactive central complexes with creatine kinase: electron paramagnetic resonance studies with oxygen-17-labeled ligands

Coordination of Mn(II) to the phosphate groups of the substrates and products in the central complexes of the creatine kinase reaction mixture has been investigated by electron paramagnetic resonance (EPR) spectroscopy with regiospecifically 17O-labeled substrates. The EPR pattern for the equilibrium mixture is a superposition of spectra for the two central complexes, and this pattern differs from those observed for the ternary enzyme-Mn(II)-nucleotide complexes and from that for the dead-end complex enzyme-Mn(II)ADP-creatine. In order to identify those signals that are associated with each of the central complexes of the equilibrium mixture, spectra were obtained for a complex of enzyme, Mn(II)ATP, and a nonreactive analogue of creatine, 1-(carboxymethyl)-2-iminoimidazolidin-4-one, which is a newly synthesized competitive inhibitor. This inhibitor permits an unobstructed view of the EPR spectrum for Mn(II)ATP in the closed conformation of the active site. The EPR spectrum for this nonreactive complex with Mn(II)ATP matches one subset of signals in the spectrum for the equilibrium mixture, i.e., those due to the enzyme-Mn(II)-ATP-creatine complex. Chemical quenching of the samples followed by chromatographic assays for both ATP and ADP indicates that the enzyme-Mn(II)ADP-phosphocreatine and the enzyme-Mn(II)ATP-creatine complexes are present in a ratio of approximately 0.7 to 1. A similar value for the equilibrium constant for enzyme-bound substrates is obtained directly from the EPR spectrum for the equilibrium mixture.(ABSTRACT TRUNCATED AT 250 WORDS)     

Exponential ATP amplification through simultaneous regeneration from AMP and pyrophosphate for luminescence detection of bacteria

Bacteria monitoring is essential for many industrial manufacturing processes, particularly those involving in food, biopharmaceuticals, and semiconductor production. Firefly luciferase ATP luminescence assay is a rapid and simple bacteria detection method. However, the detection limit of this assay for Escherichia coli is approximately 10⁴ colony-forming units (CFU), which is insufficient for many applications. This study aims to improve the assay sensitivity by simultaneous conversion of PP_i and AMP, two products of the luciferase reaction, back to ATP to form two chain-reaction loops. Because each consumed ATP continuously produces two new ATP molecules, this approach can achieve exponential amplification of ATP. Two consecutive enzyme reactions were employed to regenerate AMP into ATP: adenylate kinase converting AMP into ADP using UTP as the energy source, and acetate kinase catalyzing acetyl phosphate and ADP into ATP. The PP_i-recycling loop was completed using ATP sulfurylase and adenosine 5′ phosphosulfate. The modification maintains good quantification linearity in the ATP luminescence assay and greatly increases its bacteria detection sensitivity. This improved method can detect bacteria concentrations of fewer than 10 CFU. This exponential ATP amplification assay will benefit bacteria monitoring in public health and manufacturing processes that require high-quality water.     

Assay of enzymes forming AMP+PPi by the pyrophosphate determination based on the formation of 18-molybdopyrophosphate

The formation of 18-molybdopyrophosphate anion has been studied to develop a simple and rapid assay of the enzymatic reaction involving ATP→AMP+PPi(P(2)O(7)(4-)). By the addition of P(2)O(7)(4-) anion to an acidic acetonitrile-water solution containing MoO(4)(2-) anion, the colorless Mo(VI) solution immediately became yellow due to the formation of 18-molybdopyrophosphate anion. The absorbance of the P(2)O(7)(4-)-Mo(VI) mixture at, for example, 450nm was proportional to the analytical concentration of P(2)O(7)(4-) anion. Although the test Mo(VI) solution remained colorless by the addition of AMP, it gradually turned to yellow by ATP. The undesired color development is attributed to the formation of a yellow molybdophosphate species accompanied by the dissociation of PO(4)(3-) from the unstable ATP molecule. However, the color development became much slower when ethylenediaminetetraacetic acid was added into an assay mixture, where ATP may form a kinetically stable species. Thus, P(2)O(7)(4-) anion can be determined spectrophotometrically in the enzymatic reaction mixture containing ATP. By the addition of ascorbic acid, the yellow P(2)O(7)(4-)-Mo(VI) mixture turned to blue due to the reduction of the molybdopyrophosphate anion. Thus, P(2)O(7)(4-) anion can be detected colorimetrically by the blueness. The spectrophotometric and colorimetric methods could be applied advantageously to the assay of acetyl-CoA synthetase.     

Homogeneous proximity tyrosine kinase assays: scintillation proximity assay versus homogeneous time-resolved fluorescence

Two homogeneous proximity assays for tyrosine kinases, scintillation proximity assay (SPA) and homogeneous time-resolved fluorescence (HTRF), have been developed and compared. In both formats, the kinase assay was performed using biotinylated peptide substrate, ATP ([33P]ATP in the case of SPA), and tyrosine kinase in a 96-well assay format. After the kinase reaction was stopped, streptavidin-coated SPA beads or europium cryptate-labeled anti-phosphotyrosine antibody and streptavidin-labeled allophycocyanin were added as detection reagents for SPA or HTRF assays, respectively. Since the assay signal was detected only when the energy donor (radioactivity for SPA, Eu for HTRF) and the energy acceptor molecules (SPA beads for SPA, allophycocyanin for HTRF) were in close proximity, both assays required no wash or liquid transfer steps. This homogeneous ("mix-and-measure") nature allows these assays to be much simpler, more robust, and easier to automate than traditional protein kinase assays, such as a filter binding assay or ELISA. Both assays have been miniaturized to a 384-well format to reduce the assay volume, thereby saving the valuable screening samples as well as assay reagents, and automated using automated pipetting stations to increase the assay throughput. Several advantages and disadvantages for each assay are described.