Bioluminescence reaction catalyzed by membrane-bound luciferase in the “firefly squid,” Watasenia scintillans

The small Japanese “firefly squid,” Watasenia scintillans, emits a bluish luminescence from dermal photogenic organs distributed along the ventral aspects of the head, mantle, funnel, arms and eyes. The brightest light is emitted by a cluster of three tiny organs located at the tip of each of the fourth pair of arms. Studies of extracts of the arm organs show that the light is due to a luciferin-luciferase reaction in which the luciferase is membrane-bound. The other components of the reaction are coelenterazine disulfate (luciferin), ATP, Mg²⁺, and molecular oxygen. Based on the results, a reaction scheme is proposed which involves a rapid base/luciferase-catalyzed enolization of the keto group of the C-3 carbon of luciferin, followed by an adenylation of the enol group by ATP. The AMP serves as a recognition moiety for docking the substrate molecule to a luciferase bound to membrane, after which AMP is cleaved and a four-membered dioxetanone intermediate is formed by the addition of molecular oxygen. The intermediate then spontaneously decomposes to yield CO₂ and coelenteramide disulfate (oxyluciferin) in the excited state, which serves as the light emitter in the reaction.     

Biosynthesis-inspired deracemizative production of d-luciferin by combining luciferase and thioesterase

Due to the strict enantioselectivity of firefly luciferase, only d-luciferin can be used as a substrate for bioluminescence reactions. Unfortunately, luciferin racemizes easily and accumulation of nonluminous l-luciferin has negative influences on the light emitting reaction. Thus, maintaining the enantiopurity of luciferin in the reaction mixture is one of the most important demands in bioluminescence applications using firefly luciferase. In fireflies, however, l-luciferin is the biosynthetic precursor of d-luciferin, which is produced from the L-form undergoing deracemization. This deracemization consists of three successive reactions: l-enantioselective thioesterification by luciferase, in situ epimerization, and hydrolysis by thioesterase. In this work, we introduce a deracemizative luminescence system inspired by the biosynthetic pathway of d-luciferin using a combination of firefly luciferase from Luciola cruciata (LUC-G) and fatty acyl-CoA thioesterase II from Escherichia coli (TESB). The enzymatic reaction property analysis indicated the importance of the concentration balance between LUC-G and TESB for efficient d-luciferin production and light emission. Using this deracemizative luminescence system, a highly sensitive quantitative analysis method for l-cysteine was constructed. This LUC-G-TESB combination system can improve bioanalysis applications using the firefly bioluminescence reaction by efficient deracemization of D-luciferin.     

Biochemical and morphological changes accompanying light organ development in the firefly, Photuris pennsylvanica

The larval light organs of the firefly, Photuris pennsylvanica, regress and are replaced by the adult lantern during metamorphosis. Larval and adult light organs are present and capable of periodic light emission during the latter stages of pupation and the early adult. The whole pupa emits a continuous, low level, glow throughout pupation.During pupation levels of luciferase and luciferin, the enzyme and substrate required in the light reaction, were found to remain constant in the posterior half of the pupa and to show an initial increase followed by a decrease in the anterior half. Levels of luciferase and luciferin in anterior halves were not affected by ablation of the larval light organs. The ratio of luciferase to luciferin concentrations changed from less than 1, in larval and pupal stages, to greater than 1, in the adult. Changes in the concentration and the localization of luciferase and luciferin were correlated with observed light organ development.     

Biosynthesis of Firefly Luciferin in Adult Lantern: Decarboxylation of ?-Cysteine is a Key Step for Benzothiazole Ring Formation in Firefly Luciferin Synthesis

Background

Bioluminescence in fireflies and click beetles is produced by a luciferase-luciferin reaction. The luminescence property and protein structure of firefly luciferase have been investigated, and its cDNA has been used for various assay systems. The chemical structure of firefly luciferin was identified as the ᴅ-form in 1963 and studies on the biosynthesis of firefly luciferin began early in the 1970’s. Incorporation experiments using ¹⁴C-labeled compounds were performed, and cysteine and benzoquinone/hydroquinone were proposed to be biosynthetic component for firefly luciferin. However, there have been no clear conclusions regarding the biosynthetic components of firefly luciferin over 30 years.

Methodology/Principal Findings

Incorporation studies were performed by injecting stable isotope-labeled compounds, including ʟ-[U-¹³C₃]-cysteine, ʟ-[1-¹³C]-cysteine, ʟ-[3-¹³C]-cysteine, 1,4-[D₆]-hydroquinone, and p-[2,3,5,6-D]-benzoquinone, into the adult lantern of the living Japanese firefly Luciola lateralis. After extracting firefly luciferin from the lantern, the incorporation of stable isotope-labeled compounds into firefly luciferin was identified by LC/ESI-TOF-MS. The positions of the stable isotope atoms in firefly luciferin were determined by the mass fragmentation of firefly luciferin.

Conclusions

We demonstrated for the first time that ᴅ- and ʟ-firefly luciferins are biosynthesized in the lantern of the adult firefly from two ʟ-cysteine molecules with p-benzoquinone/1,4-hydroquinone, accompanied by the decarboxylation of ʟ-cysteine.     

Specific protein-binding reactions monitored with ligand-ATP conjugates and firefly luciferase

A new method was developed to monitor specific protein binding reactions with an ATP-labeled ligand and firefly luciferase. The ligand, 2,4-dinitrobenzene, was covalently coupled to four ATP derivatives and three of these conjugates were measured quantitatively at nanomolar levels with firefly luciferase. Incubation of the conjugates with antibody to the 2,4-dinitrophenyl residue diminished the peak light intensities produced in the bioluminescent assay, whereas incubation with immunoglobulin from a nonimmunized rabbit did not affect light production. Therefore, the antibody-bound ligand-ATP conjugates were inactive in the bioluminescent assay and levels of unbound conjugate could be measured in the presence of the bound form. The firefly luciferase was used to monitor competitive binding reactions between the antibody, the conjugates, and N(2,4-dinitrophenyl)-β-alanine.     

New Analysis Method for Protein Phosphatase Type 2A Inhibitors Using the Firefly Bioluminescence System

A new analysis method for protein phosphatase type 2A inhibitors was established that uses the firefly bioluminescence system for detection. Thus, firefly luciferin phosphate was used as a substrate, and the liberated free luciferin was determined from the amount of light emitted from the immobilized luciferase. This method was successfully used to determine the activities of known inhibitors, i.e., okadaic acid, calyculin A, microcystin-LR and tautomycin using less than 10 pmol of a sample.     

Development of near-infrared firefly luciferin analogue reacted with wild-type and mutant luciferases

Interestingly, only the D-form of firefly luciferin produces light by luciferin–luciferase (L–L) reaction. Certain firefly luciferin analogues with modified structures maintain bioluminescence (BL) activity; however, all L-form luciferin analogues show no BL activity. To this date, our group has developed luciferin analogues with moderate BL activity that produce light of various wavelengths. For in vivo bioluminescence imaging, one of the important factors for detection sensitivity is tissue permeability of the number of photons emitted by L–L reaction, and the wavelengths of light in the near-infrared (NIR) range (700–900 nm) are most appropriate for the purpose. Some NIR luciferin analogues by us had performance for in vivo experiments to make it possible to detect photons from deep target tissues in mice with high sensitivity, whereas only a few of them can produce NIR light by the L–L reactions with wild-type luciferase and/or mutant luciferase. Based on the structure–activity relationships, we designed and synthesized here a luciferin analogue with the 5-allyl-6-dimethylamino-2-naphthylethenyl moiety. This analogue exhibited NIR BL emissions with wild-type luciferase (λ_max = 705 nm) and mutant luciferase AlaLuc (λ_max = 655 nm).     

Bioluminescence of the arm light organs of the luminous squid Watasenia scintillans

The squid Watasenia scintillans emits blue light from numerous photophores. According to Tsuji [F.I. Tsuji, Bioluminescence reaction catalyzed by membrane-bound luciferase in the “firefly squid”, Watasenia scintillans, Biochim. Biophys. Acta 1564 (2002) 189–197.], the luminescence from arm light organs is caused by an ATP-dependent reaction involving Mg²⁺, coelenterazine disulfate (luciferin), and an unstable membrane-bound luciferase. We stabilized and partially purified the luciferase in the presence of high concentrations of sucrose, and obtained it as particulates (average size 0.6–2 µm). The ATP-dependent luminescence reaction of coelenterazine disulfate catalyzed by the particulate luciferase was investigated in detail. Optimum temperature of the luminescence reaction is about 5 °C. Coelenterazine disulfate is a strictly specific substrate in this luminescence system; any modification of its structure resulted in a very heavy loss in its light emission capability. The light emitter is the excited state of the amide anion form of coelenteramide disulfate. The quantum yield of coelenterazine disulfate is calculated at 0.36. ATP could be replaced by ATP-γ-S, but not by any other analogues tested. The amount of AMP produced in the luminescence reaction was much smaller than that of coelenteramide disulfate, suggesting that the reaction mechanism of the Watasenia bioluminescence does not involve the formation of adenyl luciferin as an intermediate.     

2-S-cysteinylhydroquinone is an intermediate for the firefly luciferin biosynthesis that occurs in the pupal stage of the Japanese firefly,Luciola lateralis

Firefly luciferin is a natural product that is well-known to function as the substrate of the bioluminescence reaction in luminous beetles. However, the details of the biosynthetic system are still unclear. In this study, we showed by LC-MS/MS analysis that stable isotope-labeled 2-S-cysteinylhydroquinone was incorporated into firefly luciferin in living firefly specimens. Comparison of the incorporation efficiency among the developmental stages suggested that firefly luciferin is biosynthesized predominantly in the pupal stage. We also accomplished the in vitro biosynthesis of firefly luciferin using 2-S-cysteinylhydroquinone and the crude buffer extract of firefly pupae, suggesting the presence of a biosynthetic enzyme in the pupal extract.     

Enhanced luciferin entry causes rapid wound-induced light emission in plants expressing high levels of luciferase

In-vivo imaging of transgenic tobacco plants (Nicotiana tobacum L.) expressing firefly luciferase under the control of the Arabidopsis phenylalanine ammonia-lyase 1 (PAL1)-promoter showed that luciferase-catalyzed light emission began immediately after the substrate luciferin was sprayed onto the leaves and reached a plateau phase after approximately 60 min. This luminescence could easily be detected for up to 24 h after luciferin application although the light intensity declined continuously during this period. A strong and rapid increase in light emission was observed within the first minutes after wounding of luciferin-sprayed leaves. However, these data did not correlate with luciferase activity analysed by an in-vitro enzyme assay. In addition, Arabidopsis plants expressing luciferase under the control of the constitutive 35S-promoter showed similar wound-induced light emission. In experiments in which only parts of the leaves were sprayed with luciferin solutions, it was shown that increased uptake of luciferin at the wound site and its transport through vascular tissue were the main reasons for the rapid burst of light produced by preformed luciferase activity. These data demonstrate that there are barriers that restrict luciferin entry into adult plants, and that luciferin availability can be a limiting factor in non-invasive luciferase assays. Received: 11 March 2000 / Accepted: 16 May 2000     

Bioluminescence reaction catalyzed by membrane-bound luciferase in the "firefly squid," Watasenia scintillans

The small Japanese "firefly squid," Watasenia scintillans, emits a bluish luminescence from dermal photogenic organs distributed along the ventral aspects of the head, mantle, funnel, arms and eyes. The brightest light is emitted by a cluster of three tiny organs located at the tip of each of the fourth pair of arms. Studies of extracts of the arm organs show that the light is due to a luciferin-luciferase reaction in which the luciferase is membrane-bound. The other components of the reaction are coelenterazine disulfate (luciferin), ATP, Mg(2+), and molecular oxygen. Based on the results, a reaction scheme is proposed which involves a rapid base/luciferase-catalyzed enolization of the keto group of the C-3 carbon of luciferin, followed by an adenylation of the enol group by ATP. The AMP serves as a recognition moiety for docking the substrate molecule to a luciferase bound to membrane, after which AMP is cleaved and a four-membered dioxetanone intermediate is formed by the addition of molecular oxygen. The intermediate then spontaneously decomposes to yield CO(2) and coelenteramide disulfate (oxyluciferin) in the excited state, which serves as the light emitter in the reaction.     

Synthesis and bioluminescence of difluoroluciferin

A new synthesis route to firefly luciferin analogs was developed via the synthesis of 5′,7′-difluoroluciferin. As a luciferase substrate, it produces maximal bioluminescence at a much lower pH than is optimal for native luciferin, and at lower pH it gives much more of the red-shifted emission that is characteristic of the phenolate. These features are attributed to the enhanced acidity of the o,o-difluorophenol.     

The role of lysine 529, a conserved residue of the acyl-adenylate-forming enzyme superfamily, in firefly luciferase

Firefly luciferase catalyzes the highly efficient emission of yellow-green light from the substrates luciferin, Mg-ATP, and oxygen in a two-step process. The enzyme first catalyzes the adenylation of the carboxylate substrate luciferin with Mg-ATP followed by the oxidation of the acyl-adenylate to the light-emitting oxyluciferin product. The beetle luciferases are members of a large family of nonbioluminescent proteins that catalyze reactions of ATP with carboxylate substrates to form acyl-adenylates. Formation of the luciferase-luciferyl-AMP complex is a specific example of the chemistry common to this enzyme family. Site-directed mutants at positions Lys529, Thr343, and His245 were studied to determine the effects of the amino acid changes at these positions on the individual luciferase-catalyzed adenylation and oxidation reactions. The results suggest that Lys529 is a critical residue for effective substrate orientation and that it provides favorable polar interactions important for transition state stabilization leading to efficient adenylate production. These findings as well as those with the Thr343 and His245 mutants are interpreted in the context of the firefly luciferase X-ray structures and computational-based models of the active site.     

A bifunctional luminogenic substrate for two luminescent enzymes: firefly luciferase and horseradish peroxidase.

Horseradish peroxidase (HRP) catalyzes the oxidative chemiluminescent reaction of luminol, and firefly luciferase catalyzes the oxidation of firefly D-luciferin. Here we report a novel substrate, 5-(5'-azoluciferinyl)-2,3-dihydro-1,4-phthalazinedione (ALPDO), that can trigger the activity of HRP and firefly luciferase in solution because it contains both luminol and luciferin functionalities. It is synthesized by diazotization of luminol and its subsequent azo coupling with firefly luciferin. NMR spectral data show that the C5' of benzothiazole in luciferin connects the diazophthalahydrazide. The electronic absorption and fluorescence properties of ALPDO are different from those of its precursor molecules. The chemiluminescence emission spectra of the conjugate substrate display biphotonic emission characteristic of azophthalatedianion and oxyluciferin. It has an optimum pH of 8.0 for maximum activity with respect to HRP as well as luciferase. At pH 8.0 the bifunctional substrate has 12 times the activity of luminol but has 7 times less activity than the firefly luciferin-luciferase system. The specific enhancement of light emission from the cyclic hydrazide part of ALPDO helped in the sensitive assay of HRP down to 2.0 x 10(-13) M and of ATP to 1.0 x 10(-14) mol. Addition of enhancers such as firefly luciferin and p-iodophenol (PIP) to the HRP-ALPDO-H2O2 system enhanced the light output.     

The use of the luciferase reporter system forin planta gene expression studies

The properties of the firefly luciferase (LUC) make it a very good nondestructive reporter to quantify and image transgene promoter activity in plants. The short half-life of the LUC mRNA and protein, and the very limited regeneration of the LUC protein after reacting with luciferin, enables monitoring of changes in gene activity with a high time resolution. However, the ease at which luciferase activity is measuredin planta, using a light sensitive camera system (2D-luminometer), contrasts sharply with the complications that arise from interpreting the results. A variegated pattern of luciferase activity, that is often observed inin planta measurements, might either be caused by differences in influx, availability of the substrates (luciferin, oxygen, ATP) or by local differences in reporter gene activity. Here we tested the possible contribution of differences in the availability of each substrate to the variegatedin planta luciferase activity, and we show whenin planta luciferase activity is measured under substrate equilibrium conditions and can be related to the promoter activity of the reporter gene. Furthermore, we demonstrate the effects of protein stability, apparent half-life of luciferase activity, regeneration of luciferase and pH on thein vivo andin vitro luciferase measurements. The combined results give the prerequisites for the correct utilisation of the luciferase reporter system, especially forin vivo gene expression studies in plant research.     

Cytoplasmic factors that affect the intensity and stability of bioluminescence from firefly luciferase in living mammalian cells

In order to improve calibration of firefly luciferase signals obtained by injecting the enzyme into single, isolated heart and liver cells we have investigated why the luminescence from cells is greatly depressed compared with in vitro (in mammalian ionic milieu) and why the decay of the intracellular signal is remarkably slow. We have shown that inorganic pyrophosphate greatly depresses the signal in vitro and that micromolar concentrations of inoragnic pyrophosphate, comparable with that in cytoplasm, reverse this inhibition and stabilize the signal, eliminating its decay. Higher concentrations of pyrophosphate depress the signal by inhibiting ATP-binding to luciferase. Luciferse-injected cells exposed to extracellular luciferin concentrations above about 100 μmol/1 (corresponding to a cytoplasmic level of c. 5–10 μmol/1 because of a transplasmalemmal gradient) show a gradual, irreversible loss of signal. We attribute this phenomenon (which is not seen in vitro) to the gradual accumlation of a luminescently inactive, irreversible, luciferase-oxyluciferin complex. At low luciferin levels this complex is prevented from forming by cytoplasmic pyrophosphate. Above c. 100μmol/1 extracellular luciferin, the pyrophosphate level in the cytoplasm fails to fully prevent the complex forming. In vitro this phenomenon does not occur because the luciferase concentrations and hence oxyluciferin levels are orders of magnitude lower than in cells injected with concentrated luciferase solutions, which have a cytoplasmic luciferase concentration of approximately 2-4 μmol/1.     

Thein vivo pattern of firefly luciferase expression in transgenic plants

Expression of the firefly luciferase gene in transgenic plants produces light emission patterns when the plants are supplied with luciferin. We explored whether inin vivo pattern of light emission truly reveals the pattern of luciferase gene expression or whether it reflects other parameters such as the availability of the substrate, luciferin, or the tissue-specific distribution of organelles in which luciferase was localized. The tissue-specific distribution of luciferase activity and thein vivo pattern of light were examined when the luciferase gene was driven by different promoters and when luciferase was redirected from the peroxisome, where it is normally targeted, to the chloroplast compartment. It was found that the distribution of luciferase activity closely correlated with the tissue-specific pattern of luciferase mRNA. However, thein vivo light pattern appeared to reflect not only tissue-specific distribution of luciferase activity, but also the pattern of luciferin uptake.     

Determination of adenosine 5'-triphosphate by the luciferase system with a stopped-flow spectrometer.

A stopped-flow spectrometer is used for ATP assay by firefly luciferase-luciferin method. It allows one to record initial rise of the light intensity and to differentiate the light produced due to the conversion of ADP to ATP by nucleoside diphosphokinase in the firefly lantern when other nucleoside triphosphates are present. Addition of luciferin (0.27 mm) to luciferase extract increases the light intensity by a factor of 50–100. This method can be used to measure ATP in the picomole range.     

A photocytes-associated fatty acid-binding protein from the light organ of adult Taiwanese firefly, Luciola cerata

Background

Intracellular fatty acid-binding proteins (FABPs) are considered to be an important energy source supplier in lipid metabolism; however, they have never been reported in any bioluminescent tissue before. In this study, we determined the structural and functional characteristics of a novel FABP (lcFABP) from the light organ of adult Taiwanese firefly, Luciola cerata, and showed anatomical association of lcFABP with photocytes.

Principal Findings

Our results demonstrated the primary structure of lcFABP deduced from the cDNA clone of light organ shares structural homologies with other insect and human FABPs. In vitro binding assay indicated the recombinant lcFABP binds saturated long chain fatty acids (C₁₄-C₁₈) more strongly than other fatty acids and firefly luciferin. In addition, tissue distribution screening assay using a rabbit antiserum specifically against the N-terminal sequence of lcFABP confirmed the light organ-specific expression of lcFABP. In the light organ, the lcFABP constituted about 15% of total soluble proteins, and was detected in both cytosol and nucleus of photocytes.

Conclusions

The specific localization of abundant lcFABP in the light organ suggests that sustained bioluminescent flashes in the light organ might be a high energy demanding process. In photocytes, lcFABP might play a key role in providing long chain fatty acids to peroxisomes for the luciferase-catalyzed long chain acyl-CoA synthetic reaction.     

Is there a specific receptor for anesthetics? Contrary effects of alcohols and fatty acids on phase transition and bioluminescence of firefly luciferase.

Firefly luciferase emits a burst of light when mixed with ATP and luciferin (L) in the presence of oxygen. This study compared the effects of long-chain n-alcohols (1-decanol to 1-octadecanol) and fatty acids (decanoic to octadecanoic acids) on firefly luciferase. Fatty acids were stronger inhibitors of firefly luciferase than n-alcohols. Myristyl alcohol inhibited the light intensity by 50% (IC50) at 13.6 microM, whereas the IC50 of myristic acid was 0.68 microM. According to the Meyer-Overton rule, fatty acids are approximately 12,000-fold stronger inhibitors than corresponding alcohols. The Lineweaver-Burk plot showed that myristic acid inhibited firefly luciferase in competition with luciferin, whereas myristyl alcohol inhibited it noncompetitively. The differential scanning calorimetry (DSC) showed that an irreversible thermal transition occurred at approximately 39 degrees C with a transition DeltaHcal of 1.57 cal g-1. The ligand effects on the transition were evaluated by the temperature where the irreversible change is half completed. Alcohols decreased whereas fatty acids increased the thermal transition temperature of firefly luciferase. Koshland's transition-state theory (Science. 1963. 142:1533-1541) states that ligands that bind to the substrate-recognition sites induce the enzyme at a transition state, which is more stabilized than the native state against thermal perturbation. The long-chain fatty acids bound to the luciferin recognition site and stabilized the protein conformation at the transition state, which resisted thermal denaturation. Eyring's unfolding theory (Science. 1966. 154:1609-1613) postulates that anesthetics and alcohols bind nonspecifically to interfacial areas of proteins and reversibly unfold the conformation. The present results showed that alcohols do not compete with luciferin and inhibit firefly luciferase nonspecifically by unfolding the protein. Fatty acids are receptor binders and stabilize the protein conformation at the transition state.