New approaches to the preparation and application of firefly luciferase

Allowing for the lipid nature of firefly luciferase we have developed a new method for obtaining high-activity and high-stability enzyme preparations for bioluminescent microassay. The method includes the step of differential centrifugation in presence of stabilizing additives which entails a partial purification of the enzyme and its essential stabilization likely due to the fact that luciferase retains its lipid environment which plays an important role in catalysis. The resultant luciferase preparation is stable in solution at 4 °C for 2-3 months and allows the detection of down to 10^?11M ATP. A new method has been offered for luciferase immobilization on film carriers precoated with a phospholipid layer. By sorption of the enzyme on such carriers, the samples of immobilized luciferase have been obtained suitable for constructing chemiluminescent biosensors, in the form of luciferase-containing films. There are many-fold applications for detection of ATP micro-quantities.     

Collagen strip with immobilized luciferase for ATP bioluminescent determination

Firefly luciferase from Photinus pyralis has been covalently bound to a collagen strip via an acylazide activation process. Immobilization performed in the presence of both substrates ATP and luciferin allows to increase the activity retained on the strip. The best activity exhibited by immobilized luciferase was obtained in a 0.05M Tris-acetate buffer, pH 7.75. The pH optimum and the activation energy of luciferase have been found unchanged after immobilization. In the chosen stirring conditions, no diffusional limitations of substrates appear. ATP measurements can be performed with collagen-bound luciferase in the range 1.10(-11) M-3.10(-6) M. It was possible to store the strips at 4 degrees C in a dehydrated form; then, the bound enzyme retains 20% of its initial activity after eight months. Human blood ATP was measured with this collagen-bound luciferase and the results were found in good agreement with those obtained by soluble luciferase.     

Continuous-flow bioluminescent dtermination of ATP in platelets using firefly luciferase immobilized on epoxy methacrylate

Firefly luciferase was immobilized on epoxy methacrylate beads and used for a continuous-flow assay of ATP extracted from platelets. The immobilized luciferase had a half-life of 3 days at 25°C; there was a 25% recovery of luciferase activity upon immobilization, and ca 50 reactors were made from 1 mg of commercial enzyme. The sensitivity of the assay was 0.3 pmol of ATP, and the response was linear between 1 and 500 pmol of ATP. The content of platelets obtained with the present method correlated well with those obtained using soluble luciferase.     

Continuous monitoring of adenosine 5'-triphosphate in the microenvironment of immobilized enzymes by firefly luciferase

The study of enzymes sequestered in artificial or biological systems is generally conducted by indirect methodology with macroscopic measurements of reactants in the bulk medium. This paper describes a new approach with firefly luciferase to monitor ATP concentration directly in the microenvironment of enzymes producing or consuming ATP. Upon addition of ATP to immobilized firefly luciferase, the onset of light production is slower than that observed with the soluble enzyme, due to a slower diffusion of ATP to the immobilized enzyme. With immobilized pyruvate kinase, a relative accumulation of ATP inside the beads is demonstrated, as measured with coimmobilized firefly luciferase. The accumulation of product (ATP) is enhanced when the bead suspension is not stirred. This ATP in the beads is relatively inaccessible to soluble hexokinase added to the bulk medium. Similarly, a rapid ATP depletion in the microenvironment of immobilized hexokinase is demonstrated. This microscopic event is kinetically distinguishable from the slower macroscopic depletion of substrate in the bulk medium. The rate of depletion in the microenvironment depends on the local activity of the immobilized enzyme but not on the total amount of enzyme in suspension, as does the macroscopic phenomenon. The theoretical principles for the interaction of diffusion and catalysis in these systems are briefly summarized and discussed. These results are relevant to various molecular mechanisms proposed for membrane-bound enzyme action and regulation, derived from macroscopic kinetic measurements assuming a negligible diffusion control.     

Choice of buffer anion for the assay of adenosine 5′-triphosphate using firefly luciferase

Anions inhibit firefly luciferase. We have compared the extent of inhibition of luciferase by the anions from various acids used to adjust Tris buffer solutions to pH 7.75, the optimum pH for enzyme activity. Acetate and succinate were the least inhibitory of the anions tested. Tris-acetate buffers are recommended for maximum sensitivity of ATP assays with firefly luciferase.     

The effect of detergents on firefly luciferase reactions

The reaction rate of ATP-limited firefly luciferase-catalysed reactions, is affected by the presence of detergents. Anionic detergents inhibit luciferase activity without causing significant enzyme inactivation during the reaction. Cationic detergents increase reaction rate several-fold with a sharply defined optimum concentration of detergent for the effect. However, cationic detergents inactivate firefly luciferase during the reaction, resulting in a continuously decreasing reaction rate. Under such conditions, peak light intensity must be used as an indication of initial reaction rate. The inactivation rate increases with increasing detergent concentration. Non-ionic and zwitterionic detergents increase reaction rate over a broad range of detergent concentrations. Enzyme stability during the reaction is not affected by non-ionic detergents and only affected by zwitterionic detergents at high detergent concentration. Cyclodextrins, which can increase reaction rates of some chemiluminescent reactions, have little effect on firefly luciferase activity. Assays for ATP using firefly luciferase must be internally standardized by the constant addition technique in which a known amount of ATP is added to the test sample, since external calibration of such assays, by reference to a previously prepared standard curve, can lead to imprecision when detergents are present.     

Luciferase of Luciola mingrelica fireflies. Kinetics and regulation mechanism

Biochemical properties, spectral parameters of bioluminescence and reaction kinetics for Luciola mingrelica firefly luciferase are described and analysed. The kinetic scheme of the enzymatic process is proposed and discussed. Allosteric regulation of luciferase activity by ATP and its analogues is considered and binding Mg²⁺ to luciferase shown to increase its activity. Regulation mechanism of luciferase activity by phospholipids is analysed and choline-containing phospholipids shown to be specific luciferase activators. Some properties of firefly luciferae and the luciferase synthesized during firefly mRNA translation in frog oocytes are compared.     

Structural basis for the inhibition of firefly luciferase by a general anesthetic.

The firefly luciferase enzyme from Photinus pyralis is probably the best-characterized model system for studying anesthetic-protein interactions. It binds a diverse range of general anesthetics over a large potency range, displays a sensitivity to anesthetics that is very similar to that found in animals, and has an anesthetic sensitivity that can be modulated by one of its substrates (ATP). In this paper we describe the properties of bromoform acting as a general anesthetic (in Rana temporaria tadpoles) and as an inhibitor of the firefly luciferase enzyme at high and low ATP concentrations. In addition, we describe the crystal structure of the low-ATP form of the luciferase enzyme in the presence of bromoform at 2.2-A resolution. These results provide a structural basis for understanding the anesthetic inhibition of the enzyme, as well as an explanation for the ATP modulation of its anesthetic sensitivity.     

Immobilization of inulinase obtained by solid-state fermentation using spray-drying technology

Abstract

This work focuses on the immobilization of a crude inulinase extract obtained by solid-state fermentation using spray-drying technology. Maltodextrin and arabic gum were used as immobilizing agents. The effects of inlet air temperature, maltodextrin/arabic gum ratio and mass fraction of crude enzyme extract on the activity of immobilized inulinase were assessed using a central composite rotatable design (CCRD) (2³). The optimum operational conditions for the immobilization of inulinase by spray-drying was obtained at an inlet air temperature of 200°C, mass fraction of crude enzyme extract of 0.5 wt% and using only arabic gum as immobilizing agent. The immobilized enzyme had good thermostability, comparable with other inulinases obtained from different microorganisms. The method used gave good enzyme activity after immobilization and could be applied to other enzymes which have good thermal stability.     

Effect of ATP concentration and temperature on firefly luciferase activity

The dependence of luciferase activity in the homogenate of leaves of transgenic tobacco plants with chimeric firefly luciferase gene on ATP concentration and temperature was studied. The optimum ATP concentration was between 0.625 mM and 2.5 mM. The activity rapidly decreased if the homogenate was kept in 25°C and is completely lost during 30 min.     

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.     

A bioluminescence method for direct measurement of phosphodiesterase activity

We have adapted bioluminescence methods to be able to measure phosphodiesterase (PDE) activity in a one-step technique. The method employs a four-enzyme system (PDE, adenylate kinase (AK) using excess CTP instead of ATP as substrate, pyruvate kinase (PK), and firefly luciferase) to generate ATP, with measurement of the concomitant luciferase-light emission. Since AK, PK, and luciferase reactions are coupled to recur in a cyclic manner, AMP recycling maintains a constant rate of ATP formation, proportional to the steady-state AMP concentration. The cycle can be initiated by the PDE reaction that yields AMP. As long as the PDE reaction is rate limiting, the system is effectively at steady state and the bioluminescence kinetics progresses at a constant rate proportional to the PDE activity. In the absence of cAMP and PDE, low concentrations of AMP trigger the AMP cycling, which allows standardizing the system. The sensitivity of the method enables detection of <1 μU (pmol/min) of PDE activity in cell extracts containing 0.25–10 μg protein. Assays utilizing pure enzyme showed that 0.2 mM IBMX completely inhibited PDE activity. This single-step enzyme- and substrate-coupled cyclic-reaction system yields a simplified, sensitive, reproducible, and accurate method for quantifying PDE activities in small biological samples.     

Enhancement of firefly luciferase activity by cytidine nucleotides.

The temporal pattern of light production by firefly luciferase depends on the ATP concentration. With low concentrations of ATP a constant production of light occurred while at high concentrations of ATP (greater than 10 microM) there was a flash of light followed by a decline in light production. This time course of light production with high ATP concentrations was changed from the flash pattern to a pattern with a constant production of light by several cytidine nucleotides. CTP, CDP, dCTP, dCDP, dideoxyCTP, periodate-oxidized CTP and CDP, and the etheno derivatives of CTP and CDP produced that change. CMP, cytidine, CDP-glycerol, CDP-glucose, CDP-ethanolamine, and benzoylbenzoylCTP either were inhibitory to firefly luciferase or were not effective in changing the flash time course. Coenzyme A and related compounds also changed the time course of light production. The changes in time course produced by either cytidine nucleotides or CoA were inhibited by desulfoCoA. These compounds apparently enhanced light production by promoting the dissociation of the inhibitory product, oxidized luciferin, from the enzyme. When the activating compounds were used with high concentrations of ATP, the sensitivity of assay for firefly luciferase was increased. This increased sensitivity is important when using the firefly luciferase gene as a reporter.     

The effect of substrates on stability of firefly luciferase, embedded in phosphatidylcholine liposomes]

The effects of substrates (ATP and luciferin) on stability of firefly luciferase embedded into phosphatidylcholine liposomes have been studied. Luciferin did not exert any appreciable influence on enzyme inactivation. Minor concentrations of adenosine 5'-triphosphate destabilized the enzyme; however, the increase in ATP concentration markedly stabilized the enzyme entrapped into liposomes. A kinetic scheme of ATP action on enzyme inactivation is proposed. According to this scheme, the enzyme has two ATP-binding sites.     

Atypical kinetics of immobilized firefly luciferase

The kinetic properties of collagen-bound firefly luciferase have been investigated. Under definite hydrodynamic conditions with low agitation in the reaction medium, the observed behavior is modified compared to the enzyme free in solution: reducing the stirring rate decreases the observed enzymatic activity. But diffusional resistances alone cannot account for these atypical kinetics though mass transfer may certainly play an important role during the transient state of the bioluminescent reaction. After immobilization, the time necessary to reach the steady state increased from 300 ms to 3 min and the two substrates, luciferin and ATP, behave differently with respect to the enzyme: The nature of the saturating substrate first in contact with the bound enzyme is not indifferent suggesting that immobilization can reveal behaviors or mechanisms which are not visualized with the free enzyme.     

New application of firefly luciferase--it can catalyze the enantioselective thioester formation of 2-arylpropanoic acid

We introduce a new application of firefly luciferase (EC 1.13.12.7). The firefly luciferases belong to a large superfamily that includes rat liver long-chain acyl-CoA synthetase (LACS1). LACS1 is the enzyme that is involved in the deracemization process of 2-arylpropanoic acid and catalyzes the enantioselective thioester formation of R-acids. Based on the similarity of the reaction mechanisms and the sequences between firefly luciferase and LACS1, we predicted that firefly luciferase also has thioesterification activity toward 2-arylpropanoic acid. From an investigation using three kinds of luciferases from North American firefly and Japanese fireflies, we have confirmed that these luciferases exhibit an enantioselective thioester formation activity and the R-form is transformed to a thioester in preference to the S-form in the presence of ATP, Mg(2+), and CoASH. The enantiomeric excesses of unreacted recovered acid and thioester were determined by chiral phase HPLC analysis and the resulting 2-arylpropanoyl-CoAs were identified by high resolution mass spectroscopy. The K(m) and k(cat) values of thermostable luciferase from Luciola lateralis (LUC-H) toward ketoprofen were determined as 0.22 mM and 0.11 s(-1), respectively. The affinity of ketoprofen was almost the same of d-luciferin. In addition, the calculated E-value toward ketoprofen was approximately 20. These results suggest that LUC-H could catalyze the kinetic resolution of 2-arylpropanoic acid efficiently and would be a new option for the preparation of optically active 2-substituted carboxylic acids.     

Enzymatic method for continuous monitoring of inorganic pyrophosphate synthesis

A sensitive method for the analysis of inorganic pyrophosphate (PPi) which utilizes the enzymes ATP sulfurylase and firefly luciferase is described. The assay is based on continuous monitoring of the ATP formed in the ATP sulfurylase reaction using purified firefly luciferase. The assay can be completed in less than 2 s and is not affected by inorganic phosphate. The method has been used for continuous monitoring of formation of PPi in Rhodospirillum rubrum chromatophores. The assay is extremely sensitive, the linear range of the assay being 1 X 10(-9) - 5 X 10(-7) M PPi. It is suitable for routine applications. It is also possible to use the method for determination of low amounts of adenosine 5'-phosphosulfate.     

Method for real-time detection of inorganic pyrophosphatase activity

A sensitive and simple method for real-time detection of inorganic pyrophosphatase (PPase) (EC 3.6.1.1) activity has been developed. The method is based on PPase-induced activation of the firefly luciferase activity in the presence of inorganic pyrophosphate (PPi). PPi inhibits the luciferase activity, but in the presence of PPase the luciferase activity is restored and the luminescence output increases. The assay yields linear responses between 8 and 500 mU. The detection limit was found to be 8 mU PPase. The method was used to detect the hydrolytic activity of PPases from Saccharomyces cerevisiae, Escherichia coli, and Bacillus stearothermophilus. As substrate for the luciferase, adenosine 5'-phosphosulfate can replace ATP, which is an advantage for detection of PPase activity in crude extracts containing ATP-hydrolyzing activities. The method can be used for kinetic and inhibition studies as well as for detection of PPase activity during different purification procedures.     

Firefly luciferase is a bifunctional enzyme: ATP-dependent monooxygenase and a long chain fatty acyl-CoA synthetase

Firefly luciferase can catalyze the formation of fatty acyl-CoA via fatty acyl-adenylate from fatty acid in the presence of ATP, Mg²⁺ and coenzyme A (CoA). A long chain fatty acyl-CoA (C₁₆–C₂₀), produced by luciferase from a North American firefly (Photinus pyralis) and a Japanese firefly (Luciola cruciata), was isolated and identified by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry analysis. Of a number of substrates tested, linolenic acid (C_18:3) and arachidonic acid (C_20:4) appear to be suitable for acyl-CoA synthesis. This evidence suggests that firefly luciferase within peroxisomes of the cells in the photogenic organ may be a bifunctional enzyme, catalyzing not only the bioluminescence reaction but also the fatty acyl-CoA synthetic reaction.     

Real-time detection and quantification of adenosine triphosphate sulfurylase activity by a bioluminometric approach.

A real-time, sensitive, and simple assay for detection and quantification of adenosine triphosphate sulfurylase (ATP:sulfate adenylytransferase, EC 2.7.7.4) activity has been developed. The method is based on detection of ATP generated in the ATP sulfurylase reaction between APS and PPi by the firefly luciferase system. For the Saccharomyces cerevisiae ATP sulfurylase, the concentrations of APS and PPi at the half-maximal rate were found to be about 0.5 and 7 microM, respectively. The assay is sensitive and yields linear response between 0.1 microU and 50 mU. The method can be used for monitoring and quantification of recombinant ATP sulfurylase activity in Escherichia coli lysate, as well as for detection of the activity during different purification procedures.