Studies of the control of luminescence in Beneckea harveyi: properties of the NADH and NADPH:FMN oxidoreductases.

Highly purified NADH and NADPH:FMN oxidoreductases from Beneckea harveyi have been characterized with regard to kinetic parameters, association with luciferase, activity with artificial electron acceptors, and the effects of inhibitors. The NADH:FMN oxidoreductase exhibits single displacement kinetics while the NADPH:FMN oxidoreductase exhibits double displacement or ping-pong kinetics. This is consistent with the formation of a reduced enzyme as an intermediate in the reaction of catalyzed by the NADPH:FMN oxidoreductase. Coupling of either of the oxidoreductases to the luciferase reaction decreases the apparent Kms for NADH, NADPH, and FMN, supporting the suggestion of a complex between the oxidoreductases and luciferase. The soluble oxidoreductases are more efficient in producing light with luciferase than is a NADH dehydrogenase preparation obtained from the membranes of these bacteria. The soluble enzymes use either FMN or FAD as substrates for the oxidation of reduced pyridine nucleotides while the membrane NADH dehydrogenase is much more active with artificial electron acceptors such as ferricyanide and methylene blue. FMN and FAD are very poor acceptors. The evidence indicates that neither of the soluble oxidoreductases is derived from the membranes. Both enzymes are constitutive and do not depend on the synthesis of luciferase.     

The effect of luciferase and NADH:FMN oxidoreductase concentrations on the light kinetics of bacterial bioluminescence

The effects of NADH:FMN oxidoreductase and luciferase concentrations on the light kinetics of the bacterial bioluminescent reaction were investigated. Light emission with low decay rates was obtained by regulating the conversion of NADH to NAD+ by controlling oxidoreductase activity. Constant light emission can be obtained when the oxidoreductase activity is below 2.5 U/1 in the assay system. The luciferase concentration affects the light intensity but it has no effect on the decay rate of light emission. The substrate decanal and the end-products NAD+ and capric acid had no effect on the light kinetics. The Michaelis constants of bacterial luciferase for FMNH2 and decanal were 3 X 10(-6) M and 8 X 10(-7) M, respectively, and those of oxidoreductase for FMN and NADH were 6.1 X 10(-6) M and 1.6 X 10(-5) M, respectively.     

Photokinetic microanalysis of NADP+, using bacterial luciferase

Summary Bioluminescence photokinetic assay of NADP⁺ is described, using the glucose-6-phosphate dehydrogenase reaction for conversion to its reduced form and subsequent measurement of this with luciferase extracts of Vibria fisherii. The analyses were applied to the determination of the activity of minute amounts of glutathione reductase using NADP⁺ as measurable product and for nucleotide assay in cell samples of 0.5–10 g dry weight. The sensitivity was sufficient for determining 0.5 picomoles NADP⁺.Previously, FMN, NADH, NAD⁺ and NADH have been analysed with the bacterial luciferase system. Its applicability has now been extended by the assay of NADP⁺.     

Chemiluminescent assay of co-factors

Bioluminescent methods are widely used for the assay of the co-factors, NADH and ATP. Although the bioluminescent method is highly sensitive, the enzymes used are unstable and expensive. Therefore a chemiluminescent method would be valuable in clinical routine assay. We have developed a chemiluminescent method for the assay of NADH using the 1-methoxy-5-methylphenazinium methyl sulphate (1-MPMS)/isoluminol(IL)/microperox-idase(m-POD) system. In order to increase the sensitivity of this method, enzymatic cycling system was coupled to the chemiluminescent assay of NADH. Alcohol dehydrogenase and malate dehydrogenase were used as the cycling enzyme. The standard curve was obtained in the range from 3 × 10^?14 to 5 × 10^?12mol/assay. The detection limit of NADH was 30fmol/assay which was comparable to that of the bioluminescent method using bacterial luciferase. Two chemiluminescent methods for the assay of ATP have been developed. Method 1 is the system using hexokinase/G6PDH and 1-PMS/IL/m-POD, and method 2 is the system based on the enzymatic cycling reaction of ATP using hexokinase/pyruvate kinase. Method 2 is 1000/fold more sensitive than the method 1. The detection limit of ATP was 10 fmol/assay.     

Bioluminescent method of determining picomolar amounts of nicotinamide-adenine dinucleotide using an immobilized extract of the luminescent bacterium Beneckea harveyi

The luminous bacteria Beneckea Harveyi were immobilized on BrCN-sepharose and cellulose films activated with cyanuric chloride. Preparations with high luciferase and FMN-reductase activities were obtained, which showed no background luminescence without NADH being added. The storage conditions for the preparations obtained were optimized, and their kinetic parameters and thermostability were studied. Standard curves for NADH determining within the concentration range 1 nM-1 microM were plotted with the detection level of 1 picomol NADH. The preparations are very promising for bioluminescent assay due to their high activity, simple production, high stability during storage and a possibility for the repeated use.     

A sensitive bioluminescent immunoassay for dinitrophenol and trinitrotoluene

A bioluminescent immunoassay for measuring dinitrophenol and trinitrotoluene (TNT) has been developed. The DNP and TNT were covalently linked to firefly luciferase, resulting in a conjugate containing 1 mol of DNP or trinitrophenyl (TNP) per mole of luciferase. The conjugate retained 90% of its original catalytic activity. When the conjugate was incubated with immobillzed anti-TNT or anti-DNP and varying concentrations of free TNT or DNP-leucine, the amount of conjugate bound was inversely proportional to the concentration of the free compound. Using this procedure it is possible to detect 2.5 pmol of DNP-leucine and 1.0 pmol of TNT. If the TNP or DNP is linked to glucose-6-phosphate dehydrogenase instead of luciferase, much lower quantities of antigen can be detected. This is due to the fact that this enzyme has a large turnover number so that amplification is possible. The NADH produced is measured using immobilized bacterial NADH:FMN oxidoreductase and luciferase. With this procedure, 10 amol (10^?17 mol) of antigen can be measured. These procedures should be suitable for measuring any antigen.     

Purification and properties of a NAD(P)H:flavin oxidoreductase from the luminous bacterium, Beneckea harveyi.

A NAD(P)H:flavin oxidoreductase, which produces FMNH2, one of the substrates for the luciferase reaction in bioluminescent bacteria, has been purified with the aid of affinity chromatography on epsilon-aminohexanoyl-FMN-Sepharose. The purified enzyme, isolated from Beneckea harveyi, had a specific activity of 89 mumol of NADH oxidized/min/mg of protein at 23 degrees in the presence of saturating FMN and NADH and appeared homogeneous by several criteria on polyacrylamide gel electrophoresis. A molecular weight of 24,000 was estimated both by gel filtration and and sodium dodecyl sulfate gel electrophoresis indicating that the enzyme is composed of a single polypeptide chain. Kinetic studies showed that the higher specificity of the enzyme for NADH than NADPH and for riboflavin and FMN than FAD was primarily due to variations in the Michaelis constants for the different substrates. Initial velocity studies with all pairs of substrates gave intersecting patterns supporting a sequential mechanism for the NAD(P)H:flavin oxidoreductase.     

Specific immobilization of in vivo biotinylated bacterial luciferase and FMN:NAD(P)H oxidoreductase.

Bacterial bioluminescence, catalyzed by FMN:NAD(P)H oxidoreductase and luciferase, has been used as an analytical tool for quantitating the substrates of NAD(P)H-dependent enzymes. The development of inexpensive and sensitive biosensors based on bacterial bioluminescence would benefit from a method to immobilize the oxidoreductase and luciferase with high specific activity. Toward this end, oxidoreductase and luciferase were fused with a segment of biotin carboxy carrier protein and produced in Escherichia coli. The in vivo biotinylated luciferase and oxidoreductase were immobilized on avidin-conjugated agarose beads with little loss of activity. Coimmobilized enzymes had eight times higher bioluminescence activity than the free enzymes at low enzyme concentration and high NADH concentration. In addition, the immobilized enzymes were more stable than the free enzymes. This immobilization method is also useful to control enzyme orientation, which could increase the efficiency of sequentially operating enzymes like the oxidoreductase-luciferase system.     

A Bioluminescent γ-Aminobutyrate Assay for Monitoring Its Release from Inhibitory Nerve Endings

Abstract: A bioluminescent GABA assay is described. The principle of the procedure is based on the action of GABASE (GABA-aminotransferase plus succinic semialdehyde dehydrogenase), coupled to the detection of succinic semialdehyde and NADH, using Photobacterium luciferase. The method was used for monitoring GABA release from depolarized brain slices.     

Simultaneous extraction and combined bioluminescent assay of NAD+ and NADH

A new method for extracting pyridine nucleotides from tissue samples at room temperature that allows the simultaneous extraction of both the oxidized and reduced nucleotide when using a 70% buffered ethanol solution as the extractant has been developed. The extraction efficiencies for NAD⁺ and NADH were 91 and 102%, respectively. The extraction method was followed by a combined bioluminescent assay of both nucleotides. A bacterial bioluminescent system, which included luciferase and low levels of a NADH-specific oxidoreductase, was used to produce a constant light intensity directly proportional to the amount of NADH in the tissue extract sample. When the NADH had been measured, the NAD⁺ present in the extract was enzymatically converted to NADH by the addition of alcohol dehydrogenase, after which the second increase in light level was recorded. The sensitivity of the bioluminescent assay presented here is 5 × 10^?14 mol NADH or NAD⁺ per assay.     

The determination of reduced nicotinamide-adenine dinucleotide and metabolic intermediates in picomole amounts with bacterial luciferase.

Methods that use bacterial luciferase for the assay of NADH in the range from 1 pmol to 1 nmol are described. Optimal conditions for the assay of glycolytic intermediates, tricarboxylic acid-cycle intermediates and related amino acids from milligram amounts of tissue are presented. The whole spectrum of these intermediates can be determined on about 10 mg of liver tissue. The methods are simple, are suitable for routine use, and the instrumentation is inexpensive. The concentrations of glycolytic intermediates in rat livers were determined by conventional spectrometric methods and with luciferase, and the results found to be in good agreement.     

CHO cell enlargement oscillates with a temperature-compensated period of 24 min

The rate of increase in cell area of CHO cells when measured at intervals of 1 min using a light microscope equipped with a video measurement system, oscillated with a minimum period of about 24 min. The pattern of oscillations paralleled those of the 24 min period observed with the oxidation of NADH by an external cell surface or plasma membrane NADH oxidase. The increase in cell area was non-linear. Intervals of rapid increase in area alternated with intervals of rapid decrease in area. The length of the 24 min period was temperature-compensated (approximately the same when measured at 14 degrees C, 24 degrees C or 34 degrees C) while the rate of cell enlargement increased with temperature over this same range of temperatures.     

An NADH-linked luciferase assay for glycogen: the preparation of glycogen-free, viable human eccrine sweat glands

A glycogen assay based on bacterial NADH luciferase is described. It is free of tissue interference. The detection limit is 0.12 nmol glycogen, and the coefficient of variation is 5.5%. A method of depleting human eccrine sweat glands while retaining their viability is described. This depends on their incubation in 10(-5) M acetylcholine and 1 mM pyruvate. This method may be applicable to other tissues. The evidence for the viability of glycogen-depleted human eccrine sweat glands is reported and includes tissue contents of ATP and the rates of oxidation of glucose, pyruvate, beta-hydroxybutyrate, and palmitate.     

Determination of hydrogen peroxide generated by reduced nicotinamide adenine dinucleotide oxidase

Hydrogen peroxide can be conveniently determined using horseradish peroxidase (HRP) and 2,2'-azino-bis(3-ethylbenzthiazoline-6-sulfonic acid). However, interference occurs among assay components in the presence of reduced nicotinamide adenine dinucleotide (NADH) that is also a substrate of NADH oxidase. So, depletion of NADH is required before using the HRP method. Here, we report simple and rapid procedures to accurately determine hydrogen peroxide generated by NADH oxidase. All procedures developed were based on the extreme acid lability of NADH and the stability of hydrogen peroxide, because NADH was decomposed at pH 2.0 or 3.0 for 10 min, while hydrogen peroxide was stable at pH 2.0 or 3.0 for at least 60 min. Acidification and neutralization were carried out by adjusting sample containing NADH up to 30 microM to pH 2.0 for 10 min before neutralizing it back to pH 7.0. Then, hydrogen peroxide in the sample was measured using the HRP method and its determination limit was found to be about 0.3 microM. Alternatively, hydrogen peroxide in samples containing NADH up to 100 microM could be quantitated using a modified HRP method that required an acidification step only, which was found to have a determination limit of about 3 microM hydrogen peroxide in original samples.     

Flavin mononucleotide reductase of luminous bacteria

NAD(P)H: FMN oxidoreductase (flavin reductase) couples in vitro to bacterial luciferase. This reductase, which is also postulated to supply reduced flavin mononucleotide in vivo as a substrate for the bioluminescent reaction, has been partially purified and characterized from two species of luminous bacterial. From Photobacterium fischeri the enzyme has a M. W. determined by Sephadex gel filtration, of 43,000 and may have a subunit structure. The turnover number at 20 degrees C, based on a purity estimate of 20 percent, is 1.7 times 10-4 moles of NADH oxidized per min per mole of reductase. The reductase isolated from Beneckea harveyi has an apparent molecular weight of 23,000; its purity was too low to permit estimation of specific activity. Using a spectrophotometric assay at 340 nm with the P. fischeri reductase, both NADH (Km, 8 times 10-5 M) and NADPH (Km, 4 times 10-4 M) were enzymatically oxidized, the Vmax with NADH being approximately twice that of NADPH. Of the flavins tested in this assay, only FMN (Km, 7.3 times 10-5 M) and FAD (Km, 1.4 times 10-4 M) were effective, FMN having a Vmax three times that of FAD. In the coupled assay, i.e., measuring the bioluminescence intensity of the reaction with added luciferase, the optimum FMN concentration was nearly 100 times less than in the spectrophotometric assay. The studies reported suggest the existence of a functional reductase-luciferase complex.     

Soybean cell enlargement oscillates with a temperature-compensated period length of CA. 24 min

Summary Rate of enlargement of epidermal cells from soybean, when measured at intervals of 1 min using a light microscope equipped with a video measurement system, oscillated with a period length of about 24 min. This oscillation parallels the 24-min periodicity observed for the oxidation of NADH by the external plasma membrane NADH oxidase. The increase in length was not only non-linear but intervals of rapid increase in area alternated with intervals of rapid decrease in area. The length of the period was temperature compensated, and was approximately the same when measured at 14, 24 and 34°C even though the rate of cell enlargement varied over this same range of temperatures. These observations represent the first demonstration of an oscillatory growth behavior correlated with a biochemical activity where the period length of both is independent of temperature (temperature compensated) as is the hallmark of clock-related biological phenomena.     

Endotoxin assay by bioluminescence using mutant firefly luciferase

The Limulus reaction is an application of the defense mechanism of horseshoe crab for endotoxin detection. Endotoxin is a component of the cell wall in the outer membrane of gram-negative bacteria, and causes fever or shock when it enters the human blood stream. For endotoxin detection, gel formation or turbidity of the coagulation factor chromogen or fluorescence-modified peptide is used. However, these conventional methods have problems with regard to their measurement time or sensitivity. We recently obtained a mutant firefly luciferase that has a luminescence intensity over 10-fold higher than that of the wild type. Therefore, we developed a new endotoxin detection method that combines the Limulus reaction and bioluminescence using mutant luciferase. The new method detects 0.0005 EU/ml of endotoxin within 15 min.     

Addition of glucose enables determination of luciferase activity in carbon-starved, stationary phase Lactococcus lactis cells

We describe a simple method for measuring luciferase activity in the stationary phase of Lactococcus lactis. Due to large fluctuations in the energy and redox pools of stationary phase bacterial cells, measurement of luciferase activities does not yield reliable results. Upon addition of relatively small amounts of glucose, the pools are restored and measurement of luciferase becomes possible. Since luciferase activities are easily measured, our method allows to apply this simple analytical tool in stationary phase cells.     

Cell surface NADH oxidase activity of brine shrimp oscillates with a period of 25 min and is entrained by light

Plants have a surface NADH oxidase that measures time by oscillating with a 24-min period. The period is synchronized by light. With plants, a new maximum is observed exactly 12 min after the beginning of the light exposure. These experiments were to determine if animals exhibited a cell surface NADH oxidase having a similar periodicity and to answer the question, does the periodicity in animals respond to light? Using brine shrimp as a model, the findings show that plants and animals exhibit similar oscillating NADH oxidase activity and that the periodicity in this invertebrate animal does respond to light. Brine shrimp were grown for two to three days and transferred to darkness for 45 min. After return to light for one min, NADH was added and measurements of NADH oxidation were recorded over 50 min. The brine shrimp exhibited a cell surface NADH oxidase that oscillated with a period of 25 min. After being subjected to light, the brine shrimp showed a new maximum in NADH oxidation between 12 to 13 min after the beginning of the light exposure and again at 37 min and at 25 min intervals thereafter. The findings demonstrate that the periodic oscillations in NADH oxidation of brine shrimp are light entrainable.     

An improved microfluorometric enzymatic assay for the determination of ammonia.

A simple, rapid microfluorometric enzymatic method for the determination of ammonia is described. The basis for the assay is the enzymatic conversion of ammonia and α-ketoglutarate to glutamate by glutamate dehydrogenase and the measurement of disappearance of NADH. The assay sensitivity is 1–50 nmol of ammonia.