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 microm). 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 degrees 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-gamma-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.     

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.     

Bioluminescence of the insect pathogen Xenorhabdus luminescens

Luminescence of batch cultures of Xenorhabdus luminescens was maximal when cultures approached stationary phase; the onset of in vivo luminescence coincided with a burst of synthesis of bacterial luciferase, the enzyme responsible for luminescence. Expression of luciferase was aldehyde limited at all stages of growth, although more so during the preinduction phase. Luciferase was purified from cultures of X. luminescens Hm to a specific activity of 4.6 x 10(13) guanta/s per mg of protein and found to be similar to other bacterial luciferases. The Xenorhabdus luciferase consisted of two subunits with approximate molecular masses of 39 and 42 kilodaltons. A third protein with a molecular mass of 24 kilodaltons copurified with luciferase, and in its presence, either NADH or NADPH was effective in stimulating luminescence, indicating that this protein is an NAD(P)H oxidoreductase. Luciferases from two other luminous bacteria, Vibrio harveyii (B392) and Vibrio cholerae (L85), were partially purified, and their subunits were separated in 5 M urea and tested for complementation with the subunits prepared from X. luminescens Hb. Positive complementation was seen with luciferase subunits among all three species. The slow decay kinetics of the Xenorhabdus luciferase were attributed to the alpha subunit.     

Luminescence enhancement of the catalytic 19 kDa protein (KAZ) of Oplophorus luciferase by three amino acid substitutions

To characterize the luminescence properties of nanoKAZ, a 16 amino acid substituted mutant of the catalytic 19 kDa protein (KAZ) of Oplophorus luciferase, the effects of each mutated amino acid were investigated by site-specific mutagenesis. All 16 single substituted KAZ mutants were expressed in Escherichia coli cells and their secretory expressions in CHO-K1 cells were also examined using the signal peptide sequence of Gaussia luciferase. Luminescence activity of KAZ was significantly enhanced by single amino acid substitutions at V44I, A54I, or Y138I. Further, the triple mutant KAZ-V44I/A54I/Y138I, named eKAZ, was prepared and these substitutions synergistically enhanced luminescence activity, showing 66-fold higher activity than wild-KAZ and also 7-fold higher activity than nanoKAZ using coelenterazine as a substrate. Substrate specificity of eKAZ for C2- and/or C6-modified coelenterazine analogues was different from that of nanoKAZ, indicating that three amino acid substitutions may be responsible for the substrate recognition of coelenterazine to increase luminescence activity. In contrast, these substitutions did not stimulate protein secretion from CHO-K1 cells, suggesting that the folded-protein structure of KAZ might be different from that of nanoKAZ.     

Bioluminescence of the insect pathogen Xenorhabdus luminescens.

Luminescence of batch cultures of Xenorhabdus luminescens was maximal when cultures approached stationary phase; the onset of in vivo luminescence coincided with a burst of synthesis of bacterial luciferase, the enzyme responsible for luminescence. Expression of luciferase was aldehyde limited at all stages of growth, although more so during the preinduction phase. Luciferase was purified from cultures of X. luminescens Hm to a specific activity of 4.6 x 10(13) guanta/s per mg of protein and found to be similar to other bacterial luciferases. The Xenorhabdus luciferase consisted of two subunits with approximate molecular masses of 39 and 42 kilodaltons. A third protein with a molecular mass of 24 kilodaltons copurified with luciferase, and in its presence, either NADH or NADPH was effective in stimulating luminescence, indicating that this protein is an NAD(P)H oxidoreductase. Luciferases from two other luminous bacteria, Vibrio harveyii (B392) and Vibrio cholerae (L85), were partially purified, and their subunits were separated in 5 M urea and tested for complementation with the subunits prepared from X. luminescens Hb. Positive complementation was seen with luciferase subunits among all three species. The slow decay kinetics of the Xenorhabdus luciferase were attributed to the alpha subunit.     

Control of luminescence decay and flavin binding by the LuxA carboxyl-terminal regions in chimeric bacterial luciferases.

Bacterial luciferases (LuxAB) can be readily classed as slow or fast decay luciferases based on their rates of luminescence decay in a single turnover assay. Luciferases from Vibrio harveyi and Xenorhabdus (Photorhabdus) luminescens have slow decay rates, and those from the Photobacterium genus, such as P. (Vibrio) fischeri, P. phosphoreum, and P. leiognathi, have rapid decay rates. By generation of an X. luminescens-based chimeric luciferase with a 67 amino acid substitution from P. phosphoreum LuxA in the central region of the LuxA subunit, the "slow" X. luminescens luciferase was converted into a chimeric luciferase, LuxA(1)B, with a significantly more rapid decay rate. Two other chimeras with P. phosphoreum sequences substituted closer to the carboxyl terminal of LuxA, LuxA(2)B and LuxA(3)B, retained the characteristic slow decay rates of X. luminescens luciferase but had weaker interactions with both reduced and oxidized flavins, implicating the carboxyl-terminal regions in flavin binding. The dependence of the luminescence decay on concentration and type of fatty aldehyde indicated that the decay rate of "fast" luciferases arose due to a high dissociation constant (K(a)) for aldehyde (A) coupled with the rapid decay of the resultant aldehyde-free complex via a dark pathway. The decay rate of luminescence (k(T)) was related to the decanal concentration by the equation: k(T) = (k(L)A + k(D)K(a))/(K(a) + A), showing that the rate constant for luminescence decay is equal to the decay rate via the dark- (k(D)) and light-emitting (k(L)) pathways at low and high aldehyde concentrations, respectively. These results strongly implicate the central region in LuxA(1)B as critical in differentiating between "slow" and "fast" luciferases and show that this distinction is primarily due to differences in aldehyde affinity and in the decomposition of the luciferase-flavin-oxygen intermediate.     

中国萤火虫云南窗萤荧光素酶cDNA的克隆表达和序列分析

从一种来自中国日行性萤火虫(云南窗萤)发光器官mRNA中克隆、测序并表达了有功能的荧光素酶.云南窗萤荧光素酶的cDNA序列有1647个碱基,编码548个氨基酸残基.从推测得到的氨基酸序列的比对分析得出:云南窗萤的荧光素酶与来自Lampyris noctiluca,L.turkestanicus和Nyctophila cf.caucasica三种萤火虫的荧光素酶有97.8%的序列一致性.从推测得出的氨基酸序列进行系统发育分析,其结果表明:云南窗萤和Lampyris Nyctophila聚在一起,与同属的发光强夜行性的萤火虫不形成的单系.云南窗萤荧光素酶在大肠杆菌中表达的条带大约70kDa,并且在有荧光素存在时发出黄绿色荧光.对荧光素酶的结构模拟和分析表明,云南窗萤荧光素酶基因的氨基端和羧基端结构域之间的裂沟处存在这5个多肽环,这正是从其他荧光素酶推测得到的催化荧光反应时的底物结合位点.云南窗萤和窗萤属的其他3种萤火虫的荧光素酶卡目比,有13个不同氨基酸位点,位于模拟分子结构的表面.对于这些多肽环、不刚氨基酸残基和晶体结构的进一步研究有利于解释日行和夜行性萤火虫荧光素酶的差异.     

Firefly luciferase genes from the subfamilies Psilocladinae and Ototretinae (Lampyridae, Coleoptera)

Firefly luciferase genes have been isolated from approximately 20 species of Lampyrinae, Luciolinae, and Photurinae. These are mostly nocturnal luminescent species that use light signals for sexual communication. In this study, we isolated three cDNAs for firefly luciferase from Psilocladinae (Cyphonocerus ruficollis) and Ototretinae (Drilaster axillaris and Stenocladius azumai), which are diurnal non-luminescent or weakly luminescent species that may use pheromones for communication. The amino acid sequences deduced from the three cDNAs showed 81-89% identities to each other and 60-81% identities with known firefly luciferases. The three purified recombinant proteins showed luminescence and fatty acyl-CoA synthetic activities, as observed in other firefly luciferases. The emission maxima by the three firefly luciferases (λmax, 545-546 nm) were shorter than those by known luciferases from the nocturnal fireflies (λmax, 550-568 nm). These results suggest that the primary structures and enzymatic properties of luciferases are conserved in Lampyridae, but the luminescence colors were red-shifted in nocturnal species compared to diurnal species.     

An alternative mechanism of bioluminescence color determination in firefly luciferase

Beetle luciferases (including those of the firefly) use the same luciferin substrate to naturally display light ranging in color from green (lambda(max) approximately 530 nm) to red (lambda(max) approximately 635 nm). In a recent communication, we reported (Branchini, B. R., Murtiashaw, M. H., Magyar, R. A., Portier, N. C., Ruggiero, M. C., and Stroh, J. G. (2002) J. Am. Chem. Soc. 124, 2112-2113) that the synthetic adenylate of firefly luciferin analogue D-5,5-dimethylluciferin was transformed into the emitter 5,5-dimethyloxyluciferin in bioluminescence reactions catalyzed by luciferases from Photinus pyralis and the click beetle Pyrophorus plagiophthalamus. 5,5-Dimethyloxyluciferin is constrained to exist in the keto form and fluoresces mainly in the red. However, bioluminescence spectra revealed that green light emission was produced by the firefly enzyme, and red light was observed with the click beetle protein. These results, augmented with steady-state kinetic studies, were taken as experimental support for mechanisms of firefly bioluminescence color that require only a single keto form of oxyluciferin. We report here the results of mutagenesis studies designed to determine the basis of the observed differences in bioluminescence color with the analogue adenylate. Mutants of P. pyralis luciferase putative active site residues Gly246 and Phe250, as well as corresponding click beetle residues Ala243 and Ser247 were constructed and characterized using bioluminescence emission spectroscopy and steady state kinetics with adenylate substrates. Based on an analysis of these and recently reported (Branchini, B. R., Southworth, T. L., Murtiashaw, M. H., Boije, H., and Fleet, S. E. (2003) Biochemistry 42, 10429-10436) data, we have developed an alternative mechanism of bioluminescence color. The basis of the mechanism is that luciferase modulates emission color by controlling the resonance-based charge delocalization of the anionic keto form of the oxyluciferin excited state.     

中国萤火虫云南窗萤荧光素酶cDNA的克隆表达和序列分析(英文）

从一种来自中国日行性萤火虫（云南窗萤）发光器官mRNA中克隆、测序并表达了有功能的荧光素酶。云南窗萤荧光素酶的cDNA序列有1 647个碱基,编码548个氨基酸残基。从推测得到的氨基酸序列的比对分析得出：云南窗萤的荧光素酶与来自Lampyris noctiluca, L. turkestanicus和Nyctophila cf. caucasica三种萤火虫的荧光素酶有97.8%的序列一致性。从推测得出的氨基酸序列进行系统发育分析,其结果表明：云南窗萤和Lampyris+Nyctophila聚在一起, 与同属的发光强夜行性的萤火虫不形成的单系。云南窗萤荧光素酶在大肠杆菌中表达的条带大约70 kDa,并且在有荧光素存在时发出黄绿色荧光。对荧光素酶的结构模拟和分析表明,云南窗萤荧光素酶基因的氨基端和羧基端结构域之间的裂沟处存在这5个多肽环,这正是从其他荧光素酶推测得到的催化荧光反应时的底物结合位点。云南窗萤和窗萤属的其他3种萤火虫的荧光素酶相比,有13个不同氨基酸位点,位于模拟分子结构的表面。对于这些多肽环、不同氨基酸残基和晶体结构的进一步研究有利于解释日行和夜行性萤火虫荧光素酶的差异。     

Blue fluorescent protein from the calcium-sensitive photoprotein aequorin: catalytic properties for the oxidation of coelenterazine as an oxygenase

Blue fluorescent protein from the calcium-binding photoprotein aequorin (BFP-aq) is a complex of Ca2+ -bound apoaequorin and coelenteramide, and shows luminescence activity like a luciferase, catalyzing the oxidation of coelenterazine with molecular oxygen. To understand the catalytic properties of BFP-aq, various fluorescent proteins (FP-aq) have been prepared from semi-synthetic aequorin and characterized in comparison with BFP-aq. FP-aq has luciferase activity and could be regenerated into native aequorin by incubation with coelenterazine. The results from substrate specificity studies of FP-aq using various coelenterazine analogues have suggested that the oxidation of coelenterazine by BFP-aq in the luciferase reaction and the regeneration process to aequorin might involve the same catalytic site of BFP-aq.     

Generation of thermostable monomeric luciferases from Photorhabdus luminescens

Bacterial luciferases and the genes encoding these light-emitting enzymes have an increasing number of applications in biological sciences. Temperature lability and the heterodimeric nature of these luciferases have been the major obstacles for their widespread use, for instance, as genetic reporters. Escherichia coli expressing wild-type Photorhabdus luminescens luciferase was found to produce eight times more light than the corresponding Vibrio harveyi luciferase clone in vivo at 37 degrees C. Three monomeric luciferases were created by translationally fusing the two genes encoding luxA and luxB proteins of P. luminescens. These clones were equally active in producing light in vivo when cultivated at 37 degrees C compared to cultivation at 30 degrees C. The fusion containing the longest linker showed the highest activity. In vitro, the monomeric luciferases were less active having at best 20% of activity of the wild-type enzyme due to the partial formation of insoluble aggregates. The results suggest that P. luminescens luciferase and monomeric derivatives thereof should be more suitable than the corresponding V. harveyi enzyme to be used as reporters in cell types which need cultivation at elevated temperatures.     

Identification of two catalytic domains in a luciferase secreted by the copepod Gaussia princeps

Gaussia luciferase secreted by the copepod Gaussia princeps catalyzes the oxidation of coelenterazine to produce blue light. The primary structure of Gaussia luciferase deduced from the cDNA sequence shows two repeat sequences of 71 amino acid residues, suggesting the luciferase consists of two structural domains. Two domains in Gaussia luciferase were expressed independently in Escherichia coli cells, purified and characterized. We found that both domains have luminescence activity with coelenterazine, and the catalytic properties including luminescence spectrum, optimal pH, substrate specificity and luminescence stimulation by halogen ions (Cl⁻, Br⁻ and I⁻) are identical to intact Gaussia luciferase. Thus, Gaussia luciferase has two catalytic domains for the luminescence reaction.     

Binding of murine monoclonal antibodies to the active and inactive configurations of aequorin

Murine monoclonal IgG1 antibodies (MAb), designated Aq-11 and Aq-12, were prepared against the photoprotein aequorin from jelly fish. Aequorin is a calcium-sensitive photoprotein which consists of a single polypeptide chain, apoaequorin, and a functional chromophore, coelenterazine. Native aequorin consists of two species with molecular masses of 25 and 23.5 kDa. MAb Aq-12 was found by immunoblot analysis to bind specifically to the 25 kDa species, while MAb Aq-11 reacted with the 23.5 kDa protein. Activation of apoaequorin with coelenterazine was associated with a shift of the 23.5 kDa molecule to the 25 kDa species. In contrast, treatment with calcium ions induced a shift back to the 23.5 kDa form. These changes between the active and inactive forms were identified by reactivity with MAbs Aq-11 and Aq-12. The results thus indicate that these MAbs should be useful in monitoring activation of this photoprotein.     

Cloning and expression of the lux-operon of Photorhabdus luminescens, strain Zm1: nucleotide sequence of luxAB genes and basic properties of luciferase

A chromosomal fragment of bacteria Photorhabdus luminescence Zm1, which contains the lux operon, was cloned into the vector pUC18. The hybrid clone containing plasmid pXen7 with the EcoRI fragment approximately 7-kb was shown to manifest a high level of bioluminescence. By subcloning and restriction analysis of the EcoRI fragment, the location of luxCDABE genes relative to restriction sites was determined. The nucleotide sequence of the DNA fragment containing the luxA and luxB genes encoding alpha- and beta-subunits of luciferase was determined. A comparison with the nucleotide sequences of luxAB genes in Hm and Hw strains of Ph. luminescence revealed 94.5 and 89.7% homology, respectively. The enterobacterial repetitive intergenic sequence (ERIC) of 126 bp typical for Hw strains was identified in the spacer between the luxD and luxA genes. The lux operon of Zm1 is assumed to emerge through recombination between Hm and Hw strains. Luciferase of Ph. luminescence was shown to possess a high thermal stability: its activity decreased by a factor of 10 at 44 degrees C for 30 min, whereas luciferases of marine bacteria Vibrio fischeri and Vibrio harveyi were inactivated by one order of magnitude at 44 degrees C for 1 and 6 min, respectively. The lux genes of Ph. luminescence are suggested for use in gene engineering and biotechnology.     

Photoexcited bacterial bioluminescence. Identity and properties of the photoexcitable luciferase.

Properties of photoexcitable luciferase are compared with those of luciferase, both isolated from the bacterium Beneckea harveyi. The proteins have the same molecular weight, are similarly charged at pH 8, and can be inactivated, with comparable efficiencies, by antibodies against either pure luciferase (a heterodimeric protein) or individual subunits thereof. Compared with luciferase, photoexcitable luciferase has a broader pH range for optimal activity, is more stable under acidic conditions, is less stable under alkaline conditions, and is more resistant at neutral pH to inactivation by heat, urea, and trypsin; A flavine-like chromophore, designated B, can be isolated from photoexcitable luciferase. The binding of B to luciferase restores all the properties characteristic of photoexcitable luciferase. Moreover, photoexcitable luciferases from mutants selected to have heat labile luciferases are also thermally unstable. It is concluded that photoexcitable luciferase actually consists of a luciferase-B complex which is conformationally distinct from luciferase under certain conditions.     

Luciferase from Fulgeochlizus bruchi (Coleoptera:Elateridae), a Brazilian click-beetle with a single abdominal lantern: molecular evolution, biological function and comparison with other click-beetle luciferases

Bioluminescent click-beetles emit a wide range of bioluminescence colors (λ(Max) = 534-594 nm) from thoracic and abdominal lanterns, which are used for courtship. Only the luciferases from Pyrophorus and Pyrearinus species were cloned and sequenced. The Brazilian Fulgeochlizus bruchi click-beetle, which inhabits the Central-west Cerrado (Savannas), is noteworthy because, differently from other click-beetles, the adult stage displays only a functional abdominal lantern, which produces a bright green bioluminescence for sexual attraction purposes, and lacks functional thoracic lanterns. We cloned the cDNA for the abdominal lantern luciferase of this species. Notably, the primary sequence of this luciferase showed slightly higher identity with the green emitting dorsal lantern luciferases of the Pyrophorus genus instead of the abdominal lanterns luciferases. This luciferase displays a blue-shifted spectrum (λ(Max) = 540 nm), which is pH-insensitive from pH 7.5 to 9.5 and undergoes a slight red shift and broadening above this pH; the lowest K(M) for luciferin among studied click-beetle luciferases, and the highest optimum pH (9.0) ever reported for a beetle luciferase. At pH 9.0, the K(M) for luciferin increases, showing a decrease of affinity for this substrate, despite the higher activity. The slow luminescence decay rate of F. bruchi luciferase in vitro reaction could be an adaptation of this luciferase for the long and sustained in vivo luminescence display of the click-beetle during the courtship, and could be useful for in vivo intracellular imaging.     

Bioluminescent organs of two deep-sea arrow worms, Eukrohnia fowleri and Caecosagitta macrocephala, with further observations on Bioluminescence in chaetognaths

Bioluminescence in the deep-sea chaetognath Eukrohnia fowleri is reported for the first time, and behavioral, morphological, and chemical characteristics of bioluminescence in chaetognaths are examined. Until this study, the only known species of bioluminescent chaetognath was Caecosagitta macrocephala. The luminescent organ of that species is located on the ventral edge of each anterior lateral fin, whereas that of E. fowleri runs across the center of the tail fin on both dorsal and ventral sides. Scanning electron microscopy showed that the bioluminescent organs of both species consist of hexagonal chambers containing elongate ovoid particles-the organelles holding bioluminescent materials. No other luminous organism is known to use hexagonal packing to hold bioluminescent materials. Transmission electron microscopy of particles from C. macrocephala revealed a densely packed paracrystalline matrix punctuated by globular inclusions, which likely correspond to luciferin and luciferase, respectively. Both species use unique luciferases in conjunction with coelenterazine for light emission. Luciferase of C. macrocephala becomes inactive after 30 min, but luciferase of E. fowleri is highly stable. Although C. macrocephala has about 90 times fewer particles than E. fowleri, it has a similar bioluminescent capacity (total particle volume) due to its larger particle size. In situ observations of C. macrocephala from a remotely operated vehicle revealed that the luminous particles are released to form a cloud. The discovery of bioluminescence in a second chaetognath phylogenetically distant from the first highlights the importance of bioluminescence among deep-sea organisms.     

Site-directed mutagenesis of firefly luciferase active site amino acids: a proposed model for bioluminescence color.

Under physiological conditions firefly luciferase catalyzes the highly efficient emission of yellow-green light from the substrates luciferin, Mg-ATP, and oxygen. In nature, bioluminescence emission by beetle luciferases is observed in colors ranging from green (approximately 530 nm) to red (approximately 635 nm), yet all known luciferases use the same luciferin substrate. In an earlier report [Branchini, B. R., Magyar, R. M., Murtiashaw, M. H., Anderson, S. M., and Zimmer, M. (1998) Biochemistry 37, 15311-15319], we described the effects of mutations at His245 on luciferase activity. In the context of molecular modeling results, we proposed that His245 is located at the luciferase active site. We noted too that the H245 mutants displayed red-shifted bioluminescent emission spectra. We report here the construction and purification of additional His245 mutants, as well as mutants at residues Lys529 and Thr343, all of which are stringently conserved in the beetle luciferase sequences. Analysis of specific activity and steady-state kinetic constants suggested that these residues are involved in luciferase catalysis and the productive binding of substrates. Bioluminescence emission spectroscopy studies indicated that point mutations at His245 and Thr343 produced luciferases that emitted light over the color range from green to red. The results of mutational and biochemical studies with luciferase reported here have enabled us to propose speculative mechanisms for color determination in firefly bioluminescence. An essential role for Thr343, the participation of His245 and Arg218, and the involvement of bound AMP are indicated.