The influence of Ala243 (Gly247), Arg215 and Thr226 (Asn230) on the bioluminescence spectra and pH-sensitivity of railroad worm,click beetle and firefly luciferases

Among beetle luciferases, the pH-sensitive firefly luciferases have been studied extensively. Much less is known about pH-insensitive luciferases, which include click beetle and railroad worm luciferases. Previously, we found that the residues R215 and T226 (N230) are important for green light emission. Here we show that the conserved residue A243 in pH-insensitive luciferases and the corresponding G247 in pH-sensitive luciferases affect the emission spectrum and influence pH-sensitivity. In contrast to railroad worm green light-emitting (PxvGR) and firefly luciferases, the substitution of R215 in Pyrearinus termitilluminans click beetle luciferase (Pte) had no effect on the spectrum, showing that R215 is not essential for green light emission in all beetle luciferases. A homology-based model of Pte luciferase shows that R215 and T226 are close enough to interact. To investigate if there was an interaction between these conserved residues, double mutants were constructed. The double substitution R215S/T226N in Pte luciferase abolished the activity. In PxvGR luciferase the same double mutant resulted in a redshift (lambda(max) = 595 nm), whose magnitude was lower than the value expected for an additive effect. These results suggest that the effects of R215S and T226N are partially interdependent. The double substitution T226N/A243G had an additive redshift effect on the spectrum of PxvGR luciferase, whereas it had a smaller effect on the spectrum of Pte luciferase. Altogether, these results suggest that the above substitutions have different effects on the active site of click beetle and railroad worm luciferases.     

A new firefly luciferase with bimodal spectrum: identification of structural determinants of spectral pH-sensitivity in firefly luciferases

Fireflies emit flashes in the green-yellow region of the spectrum for the purpose of sexual attraction. The bioluminescence color is determined by the luciferases. It is well known that the in vitro bioluminescence color of firefly luciferases can be shifted toward the red by lower pH and higher temperature; for this reason they are classified as pH-sensitive luciferases. However, the mechanism and structural origin of pH sensitivity in fireflies remains unknown. Here we report the cloning of a new luciferase from the Brazilian twilight active firefly Macrolampis sp2, which displays an unusual bimodal spectrum. The recombinant luciferase displays a sensitive spectrum with the peak at 569 nm and a shoulder in the red region. Comparison of the bioluminescence spectra of Macrolampis, Photinus and Cratomorphus firefly luciferases shows that the distinct colors are determined by the ratio between green and red emitters under luciferase influence. Comparison of Macrolampis luciferase with the highly similar North American Photinus pyralis luciferase (91%) showed few substitutions potentially involved with the higher spectral sensitivity in Macrolampis luciferase. Site-directed mutagenesis showed that the natural substitution E354N determines the appearance of the shoulder in the red region of Macrolampis luciferase bioluminescence spectrum, helping to identify important interactions and residues involved in the pH-sensing mechanism in firefly luciferases.     

Aequorin mutants with increased thermostability

Bioluminescent labels can be especially useful for in vivo and live animal studies due to the negligible bioluminescence background in cells and most animals, and the non-toxicity of bioluminescent reporter systems. Significant thermal stability of bioluminescent labels is essential, however, due to the longitudinal nature and physiological temperature conditions of many bioluminescent-based studies. To improve the thermostability of the bioluminescent protein aequorin, we employed random and rational mutagenesis strategies to create two thermostable double mutants, S32T/E156V and M36I/E146K, and a particularly thermostable quadruple mutant, S32T/E156V/Q168R/L170I. The double aequorin mutants, S32T/E156V and M36I/E146K, retained 4 and 2.75 times more of their initial bioluminescence activity than wild-type aequorin during thermostability studies at 37 °C. Moreover, the quadruple aequorin mutant, S32T/E156V/Q168R/L170I, exhibited more thermostability at a variety of temperatures than either double mutant alone, producing the most thermostable aequorin mutant identified thus far.     

The Effect of Surface Charge Saturation on Heat‐induced Aggregation of Firefly Luciferase

We present here the effect of firefly luciferase surface charge saturation and the presence of some additives on its thermal‐induced aggregation. Three mutants of firefly luciferase prepared by introduction of surface Arg residues named as 2R, 3R and 5R have two, three and five additional arginine residues substituted at their surface compared to native luciferase; respectively. Turbidimetric study of heat‐induced aggregation indicates that all three mutants were reproducibly aggregated at higher rates relative to wild type in spite of their higher thermostability. Among them, 2R had most evaluated propensity to heat‐induced aggregation. Therefore, the hydrophilization followed by appearing of more substituted arginine residues with positive charge on the firefly luciferase surface was not reduced its thermal aggregation. Nevertheless, at the same condition in the presence of charged amino acids, e.g. Arg, Lys and Glu, as well as a hydrophobic amino acid, e.g. Val, the heat‐induced aggregation of wild type and mutants of firefly luciferases was markedly decelerated than those in the absence of additives. On the basis of obtained results it seems, relinquishment of variety in charge of amino acid side chains, they via local interactions with proteins cause to decrease rate and extent of their thermal aggregation.     

Stabilization of <Emphasis Type="Italic">Luciola mingrelica</Emphasis> firefly luciferase by genetic engineering methods

The results of Luciola mingrelica firefly luciferase stabilization by genetic engineering methods are reviewed. The Cys62, Cys146, and Cys164 to Ser mutant enzymes with an enhanced thermostability and lower sensitivity to dithiothreitol were obtained by site-directed mutagenesis. The double mutant G216N, A217L was obtained, which displayed a higher thermostability and resistance to DMSO in comparison with WT luciferase. Random mutagenesis of the gene region encoding residues 1–225 and subsequent screening of the mutants resulted in the production of the mutant MT8 with a higher thermostability, as well as mutants MT3 and MT4 with higher resistance to dimethyl sulfoxide. The mutant 4TS was obtained by the method of directed evolution of the gene site encoding residues 130–390, which was shown to contain eight replacements after four cycles of mutagenesis and had two-fold higher specific activity, eight-fold lower K _m value for ATP, and stability at 42°C, which was 65-fold higher that of WT luciferase. The stabilization mechanism of this mutant is discussed.     

Effects of Sucrose and Trehalose on Stability,Kinetic Properties,and Thermal Aggregation of Firefly Luciferase

In this study, we used sugars as stabilizing additives to improve the thermostability and to inhibit aggregation of firefly luciferase. The combination of sucrose and trehalose has a strong stabilizing effect on firefly luciferase activity and prevents its thermoinactivation. These additives can also increase optimum temperature. It has been shown that the presence of both sucrose and trehalose can inhibit thermal aggregation of firefly luciferase and decrease bioluminescence decay rate. In order to understand the molecular mechanism of thermostabilization, we investigated the effects of sucrose and trehalose combination on the secondary structure of luciferase by Fourier transform infrared spectroscopy. Minor changes in content of secondary structure of firefly luciferase are observed upon treatment with additives.     

Surface Arginine Saturation Effect on Unfolding Reaction of Firefly Luciferase: A Thermodynamic and Kinetic Perspective

Replacement of some hydrophobic solvent‐exposed residues in Lampyris turkestanicus luciferase with arginine increases thermostability of this enzyme. Herein, thermodynamic and kinetic of unfolding reactions of wild type (WT), E354R/356R, E354R/356R‐I232R and E354R/356R‐Q35R/L182R/I232R variants, has been investigated. Fluorescence and Far‐UV circular dichroism measurements using urea as a chemical denaturant indicated that the value of for all variants is greater than that of WT enzyme. Analysis of m‐values, as a measure of difference in the solvent accessible surface area between the native and denatured states of protein, revealed that higher stability of mutants is related to their higher degree of compactness in the folded state. Results of unfolding kinetic experiments showed that all variants have three‐exponential behavior in which they unfolded with three rate constants and corresponding amplitudes. Increasing the rate constants of fast unfolding phase in mutants relative to WT protein may be attributed to more compactness and more kinetic sensitivity of their folded state to urea. However, more population of WT protein was unfolded from fast unfolding phase. Results of this investigation highlight kinetic stability of luciferase via a slow rate of unfolding.     

A fusion protein of <Emphasis Type="Italic">Luciola mingrelica</Emphasis> luciferase with a biotin-binding domain: Production,properties, and application

A plasmid encoding a fusion protein (4TS-bccp87) composed of a thermostable mutant of the Luciola mingrelica firefly luciferase (4TS) and 87 carboxy-terminal amino acid residues of the biotin-binding domain (bccp87) from E. coli was constructed using genetic-engineering techniques. It was established that fusion-protein expression in BL21(DE3) E. coli resulted in 60% of the biotinylated form. The catalytic properties, thermostability, and bioluminescence spectra of the fusion protein were shown to be similar to that of the initial luciferase. The possibility of using the streptavidin-biotinylated luciferase complex for defining the Salmonella typhimurium cell concentration in the range from 10⁴ to 5 × 10⁶ CFU/ml by enzyme immunoassay was shown.     

Purification and partial spectral characterization of a novel luciferin from the luminous enchytraeid Fridericia heliota

A homogeneous luciferin preparation has been obtained from the luminous soil enchytraeid Fridericia heliota, which has an ATP-dependent luminescent system. A procedure for luciferin purification without losing fractions of active luciferase has been developed. The luciferin specific activity is 4000 times increased; its UV absorption spectrum maximum is 294 nm with a local minimum at 262 nm. The luciferin of the enchytraeid F. heliota is significantly different from firefly luciferin, whose luminescent reaction also requires ATP, and it also appears to have no similarities to other known luciferins.     

Enhancement of thermostability of the Luciola mingrelica firefly luciferase by site-directed mutagenesis of nonconservative cysteine residues Cys62 and Cys146

Mutant forms of the firefly (Luciola mingrela) luciferase with point mutations Cys62Ser and Cys146Ser were obtained by site-directed mutagenesis. The mutations did not affect the catalytic activity and fluorescence spectra of the enzyme. The rate constants of the fast (k ₁) and slow (k ₂) stages of thermoinactivation of the wild-type and mutant enzymes were determined at 37°C in the absence and presence of 12 mM dithiothreitol (DTT). The thermostability of the mutant forms of luciferase increased several times compared to the wild-type enzyme. In the presence of DTT, k ₂ of the wild-type enzyme decreased three times whereas neither k ₁ nor k ₂ of the mutant forms changed. It was concluded that amino acid residues Cys62 and Cys146 play a major role in luciferase inactivation and that their substitution with Ser stabilizes the enzyme.     

Development of a thermostable firefly luciferase

Firefly luciferase forms the basis of a wide range of analytical techniques. However, the enzyme is unstable and rapidly loses activity even at room temperature. This leads to losses in sensitivity and precision in analytical applications and also severely limits the fieldability of devices incorporating luciferase-based technologies. A number of point mutations have previously been identified that significantly increase the thermostability of the enzyme. We show here that when such mutations are combined they can have an additive effect on the stabilisation of the enzyme. As such, we have constructed a luciferase mutant containing four point mutations, relative to the wildtype enzyme, resulting in remarkably greater thermostability.     

Designing split reporter proteins for analytical tools

A current focus of biological research is to quantify and image cellular processes in living cells and animals. To detect such cellular processes, genetically-encoded reporters have been extensively used. The most common reporters include firefly luciferase, renilla luciferase, green fluorescent protein (GFP) and its variants with various spectral properties. This review describes novel design of split-GFP and luciferase reporters based on protein splicing, and highlights some potential applications with the reporters to study protein-protein interactions, protein localization, intracellular protein dynamics, and protein activity in living cells and animals.     

Luciferin‐Regenerating Enzyme Mediates Firefly Luciferase Activation Through Direct Effects of D‐Cysteine on Luciferase Structure and Activity

Luciferin‐regenerating enzyme (LRE) contributes to in vitro recycling of D‐luciferin. In this study, reinvestigation of the luciferase‐based LRE assay is reported. Here, using quick change site‐directed mutagenesis seven T‐LRE (Lampyris turkestanicusLRE) mutants were constructed and the most functional mutant of T‐LRE (T⁶⁹R) was selected for this research and the effects of D‐ and L‐cysteine on T⁶⁹R T‐LRE‐luciferase‐coupled assay are examined. Our results demonstrate that bioluminescent signal of T⁶⁹R T‐LRE‐luciferase‐coupled assay increases and then reach equilibrium state in the presence of 5 mm D‐cysteine. In addition, results reveal that 5 mm D‐ and L‐cysteine in the absence of T⁶⁹R T‐LRE cause a significant increase in bioluminescence intensity of luciferase over a long time as well as decrease in decay rate. Based on activity measurements, far‐UV CD analysis, ANS fluorescence and DLS (Dynamic light scattering) results, D‐cysteine increases the activity of luciferase due to weak redox potential, antiaggregatory effects, induction of changes in conformational structure and kinetics properties. In conclusion, in spite of previous reports on the effect of LRE on luciferase bioluminescent intensity, the majority of increase in luciferase light output and time‐course originate from the direct effects of D‐cysteine on structure and activity of firefly luciferase.     

Luciferins, bioluminescent substances

The bioluminescence of the American firefly Photinus is due to the reaction of 2-(6-hydroxybenzothiazol-2-yl)-Δ²-1,3-thiazoline-4-carboxylic acid (“firefly luciferin”) with the enzyme luciferase in the presence of ATP and magnesium ion. In the crustacean Cypridina, on the other hand, the bioluminescence is due to the reaction of a luciferase with 8-(3-guanidinopropyl)-6-indol-3-yl-2-(1-methylpropyl)-3,7-dihydroimidazo[1,2-a]-pyrazin-3-one (“Cypridina luciferin”). The luciferin in Latia is 1,3,3-trimethyl-2-(4-formyloxy-3-methyl-3-butenyl)-1-cyclohexene and that in Renilla is a tryptamine derivative that has not yet been accurately identified; the luciferins of other luminescent organisms are not yet known. A review is given of the investigations which have been carried out on the above luciferins and the course of the luciferin-luciferase reaction is examined. Numerous spectral data obtained during the examination of these compounds are included in the text.     

Pyrosequencing trade mark technology at elevated temperature

To date, the Pyrosequencing trade mark technology has been performed at 28 degrees C due to the low thermostability of the firefly luciferase. In this study, firefly luciferase was stabilized in the presence of glycine betaine, allowing DNA sequencing at 37 degrees C. By increasing the temperature to 37 degrees C, false signals due to primer-dimers and loop-structures were decreased significantly. In addition, a combination of (i) replacing the natural dGTP with 7'deaza-dGTP in the polymerase chain reaction (PCR), (ii) 1.6 M glycine betaine, and (iii) an increase of the temperature to 37 degrees C enabled us to sequence a DNA template with the initial sequence 3'-ATGGCCCGGGGGGGAGCTCCA em leader 5'. Furthermore, we describe a method to analyze if a primer forms a primer-dimer with extendable 3'-ends.     

Influence of amino acid side chain packing on Fe-methionine coordination in thermostable cytochrome C

Paramagnetic NMR and optical studies of the oxidized forms of mesophile Pseudomonas aeruginosa cytochrome c(551) and its quintuple mutant (F7A/V13M/F34Y/E43Y/V78I), and thermophile Hydrogenobacter thermophilus cytochrome c(552) demonstrated that the amino acid side chain packings in the protein interior influence the coordination bond between the heme iron and the axial methionine in the proteins. The strength of heme axial coordinations was found to correlate with the overall protein thermostability.     

A point mutant of apolipoprotein A-I, V156K, exhibited potent anti-oxidant and anti-atherosclerotic activity in hypercholesterolemic C57BL/6 mice

In our previous study, two point mutants of apolipoprotein A-I, designated V156K and A158E, revealed peculiar characteristics in their lipid-free and lipid-bound states. In order to determine the putative therapeutic potential of these mutants, several in vitro and in vivo evaluations were conducted. In the lipid-free state, V156K showed more profound antioxidant activity against LDL oxidation than did the wildtype (WT) or A158E variants in an in vitro assay. In the lipid-bound state, V156K-rHDL showed an enhanced cholesterol delivery activity to HepG2 cells in a time-dependent manner, as compared to WT-rHDL, A158E-rHDL, and R173C-rHDL. We assessed the physiological activities of the mutants in circulation, using hypercholesterolemic mice (C57BL6/J). Palmitoyloleoyl phosphatidylcholine (POPC)-rHDL preparations containing each of the apoA-I variants were injected into the mice at a dosage of 30 mg of apoA-I/kg of body weight. Forty eight hours after injection, the sera of the V156K-rHDL injected group showed the most potent antioxidant abilities in the ferric acid removal assay. The V156K-rHDL- or R173C-rHDL-injected mice showed no atherosclerotic lesions and manifested striking increases in their serum apo-E levels, as compared to the mice injected with WT-rHDL or A158E-rHDL. In conclusion, V156K-rHDL exhibited the most pronounced antioxidant activity and anti-atherosclerotic activity, both in vitro and in vivo. These results support the notion that HDL-therapy may prove beneficial due to its capacity to induce accelerated cholesterol excretion, as well as its enhanced antioxidant and anti-inflammatory effects and lesion regression effect.     

Firefly Luciferase‐based Fusion Proteins and their Applications in Bioanalysis

Firefly luciferase is widely used in molecular biology and bioanalytical systems as a reporter molecule due to the high quantum yield of the bioluminescence, availability of stable mutant forms of the enzyme with prescribed spectral characteristics and abundance of bacterial expression systems suitable for production of recombinant proteins in limitless quantities. In this review, we described fusion proteins of luciferase with biotin‐binding domain and streptavidin, with proteins A and G, antibodies, with DNA‐ and RNA‐binding proteins, as well as fusion proteins designed for BRET systems. The firefly luciferase‐based fusion proteins are represented as an effective tool for the development of different bioanalytical systems such as (1) systems in which luciferase is attached to the surface of the target and the bioluminescence signal is detected from the specific complexes formed; (2) BRET‐based systems, in which the specific interaction induces changes in the bioluminescence spectrum; and (3) systems that use modified or split luciferases, in which the luciferase activity changes under the action of the analyte. All these systems have wide application in biochemical analysis of physiologically important compounds, for the detection of pathogenic bacteria and viruses, for evaluation of protein–protein interactions, assaying of metabolites involved in cell communication and cell signaling.     

MECHANISM OF BIOLUMINESCENCE, CHEMI-LUMINESCENCE AND ENZYME FUNCTION IN THE OXIDATION OF FIREFLY LUCIFERIN*,†

Abstract— The chemical steps and the products of the bioluminescent and chemiluminescent oxidations of firefly luciferin are elucidated. The colors of firefly bioluminescence can be explained in terms of different ionic excited states and spectral shifts due to changes in molecular environment. Firefly luciferase undergoes conformational changes during catalysis. There are two sites for light production per 100,000 mW. A regulatory mechanism involving dehydro-luciferin is proposed for control of firefly flashing.