A new brilliantly blue-emitting luciferin-luciferase system from Orfelia fultoni and Keroplatinae (Diptera).

Larvae of O. fultoni (Keroplatidae: Keroplatinae), which occur along river banks in the Appalachian Mountains in Eastern United States, produce the bluest bioluminescence among insects from translucent areas associated to black bodies, which are  located mainly in the anterior and posterior parts of the body. Although closely related to Arachnocampa spp (Keroplatidae: Arachnocampininae), O.fultoni has a morphologically and biochemically distinct bioluminescent system which evolved independently, requiring a luciferase enzyme, a luciferin, a substrate binding fraction (SBF) that releases luciferin in the presence of mild reducing agents, molecular oxygen, and no additional cofactors. Similarly, the closely related Neoceroplatus spp, shares the same kind of luciferin-luciferase system of Orfelia fultoni. However, the molecular properties, identities and functions of luciferases, SBF and luciferin of Orfelia fultoni and other  luminescent members of the Keroplatinae subfamily still remain to be fully elucidated. Using O. fultoni as a source of luciferase, and the recently discovered non-luminescent cave worm Neoditomiya sp as the main source of luciferin and SBF, we isolated and initially characterized these compounds. The luciferase of O. fultoni is a stable enzyme active as an apparent trimer (220 kDa) composed of ~70 kDa monomers, with an optimum pH of 7.8. The SBF, which is found in the black bodies in Orfelia fultoni and in smaller dark granules in Neoditomiya sp, consists of a high molecular weight complex of luciferin and proteins, apparently associated to mitochondria. The luciferin, partially purified from hot extracts by a combination of anion exchange chromatography and TLC, is a very polar and weakly fluorescent compound, whereas its oxidized product displays blue fluorescence with an emission spectrum matching the bioluminescence spectrum (~460 nm), indicating that it is oxyluciferin. The widespread occurrence of luciferin and SBF in both luminescent and non-luminescent Keroplatinae larvae indicate an additional important biological function for the substrate, and therefore the name keroplatin.

Expression, purification, and characterization of recombinant apoPholasin.

Pholasin is a reactive oxygen-sensitive photoprotein that consists of an apoprotein (apoPholasin) and an unknown chromophore. The preferred human codon-optimized apoPholasin gene was transiently expressed in mammalian cells and apoPholasin was detected using an anti-recombinant apoPholasin antibody. For the first time, we found that apoPholasin secreted into the culture medium could catalyze the oxidation of coelenterazine (CTZ, a luciferin) to produce continuous luminescence. The fusion protein of apoPholasin and glutathione S-transferase (GST-apoPholasin) was successfully expressed as a soluble form in bacterial cells using the cold induction system. The purified GST-apoPholasin also had luminescence activity with CTZ, showing the bioluminescence emission peak at 461 nm, and the resultant product showed purple blue fluorescence under 365 nm light. Unexpectedly, the main oxidation product of CTZ was identified as coelenteramine (CTM), not coelenteramide (CTMD).

Oxyluciferin, a luminescence product of firefly luciferase, is enzymatically regenerated into luciferin.

The activity regenerating luciferin from the luminescent product oxyluciferin was found in the protein fraction of a lantern extract from Photinus pyralis. The protein, luciferin-regenerating enzyme (LRE), was purified to homogeneity by ammonium sulfate precipitation followed by successive column chromatography on Ultrogel AcA34, S-Sepharose FF, Q-Sepharose FF, TSKgel super Q 5pw and TSKgel G3000 SW(XL). This enzyme was a single polypeptide with a molecular mass of 38 kDa. LRE converted oxyluciferin to 2-cyano-6-hydroxybenzothiazole and thioglycolic acid. In the presence of d-cysteine, 2-cyano-6-hydroxybenzothiazole was turned over into luciferin. The same activities were detected in the extracts from two Japanese fireflies, Luciola cruciata and Luciola lateralis. We have cloned a cDNA encoding LRE from poly(A)+ RNA of the lantern of P. pyralis using reverse transcription-polymerase chain reaction, 5'-RACE (rapid amplification of cDNA ends) and 3'-RACE. The primary structure of LRE from P. pyralis deduced from the nucleotide sequence was shown to consist of 308 amino acids with a molecular weight of 33,619. The cDNA was successfully expressed under the control of the tac promoter in Escherichia coli.

Dehydroluciferyl-AMP is the main intermediate in the luciferin dependent synthesis of Ap4A catalyzed by firefly luciferase.

It was previously assumed that E x LH2-AMP was the intermediate complex in the synthesis of Ap4A catalyzed by firefly luciferase (EC 1.13.12.7), when luciferin (LH2) was used as cofactor. However, here we show that LH2 is partly transformed, shortly after the onset of the luciferase reaction, to dehydroluciferin (L) with formation of an E x L-AMP complex which is the main intermediate for the synthesis of Ap4A. Formation of three more derivatives of LH2 were also observed, related to the production of light by the enzyme. CoA, a known stimulator of light production, inhibits the synthesis of Ap4A by reacting with the E x L-AMP complex and yielding L-CoA.

Separation, identification and determination of luciferin in the Iranian firefly, Lampyris turkestanicus by HPLC and spectroscopic methods.

Iranian firefly larvae, Lampyris turkestanicus collected from north of Iran and their luciferin were analyzed by HPLC, TLC, MS and spectroscopic Fourier transform ([FT]-IR, FT-NMR, UV and fluorescence) methods. The results showed that luciferin in L turkestanicus lanterns was the same as in the American firefly, Photinus pyralis and synthetic D-luciferin.

The roles of the two highly unstable components F and P involved in the bioluminescence of euphausiid shrimps.

Bioluminescence of euphausiids takes place when a fluorescent tetrapyrrole F and a highly unstable protein P react in the presence of oxygen. A previous study on the euphausiid Meganyctiphanes norvegica indicated that F acts as a catalyst and P is consumed in the luminescence reaction, differing from the luminescence system of dinoflagellates in which a tetrapyrrole luciferin, nearly identical to F, is enzymatically oxidized in the presence of dinoflagellate luciferase. In the present study, P was extracted from Euphausia pacifica as well as from M. norvegica, then purified separately by affinity chromatography on a column of biliverdin-Sepharose 4B, completing the whole process in less than 5 h. The samples of P obtained from both species had a molecular weight of 600,000, a purity of about 80%, and a specific activity 50-100 times greater than that previously found. The activity of P rapidly decreased in solutions, even at 0 degrees C, and the inactivation of P derived from M. norvegica was more than four times faster than that derived from E. pacifica. The kinetics of the luminescence reaction was investigated with F and P whose concentrations were systematically varied. The reaction was characteristically slow and involved two different reaction rates; the turnover number at 0 degrees C was 30/h for the initial 20 min and 20/h after the initial 1 h. The total light emitted in a 50-h period indicated that the bioluminescence quantum yield of F was about 0.6 at 0 degrees C, and P recycled many times in the luminescence reaction. Thus, the present results conclusively show that F is a luciferin and P is a luciferase of an unusually slow-working type, contrary to early report.

Structure and non-enzymatic light emission of two luciferin precursors isolated from the luminous mushroom Panellus stipticus.

The chemical structure of two luciferin precursors PS-A and PS-B, isolated from the luminous mushroom Panellus stipticus, were determined as 1-O-decanoylpanal (2) and 1-O-dodecanoylpanal (3), respectively. Both PS-A and PS-B were converted into chemiluminescent luciferins by treatment with 50 mmol/l methylamine in a pH 3.5 buffer solution containing an anionic surfactant Tergitol 4 at 25-35 degrees C. The luciferins emitted chemiluminescence in a pH 7-8 buffer solution containing a cationic surfactant in the presence of O2 and O2-.

Pholasin--a bioluminescent indicator for detecting activation of single neutrophils.

Pholasin is the protein-bound luciferin from the bivalve mollusc Pholas dactylus which reacts with its luciferase and molecular oxygen to produce light. Pholasin was purified 226-fold with a yield of 58% from P. dactylus to give a preparation free from luciferase contamination. The ratio (k) of endogenous pholasin chemiluminescence to that when maximally stimulated by luciferase was 8.12 X 10(-6) +/- 0.87 X 10(-6) (mean +/- SD, n = 6), equivalent to a t 1/2 of 23.7 h at pH 9. Pholasin could detect reactive oxygen metabolite production from neutrophils stimulated by the chemotactic peptide N-formyl-Met-Leu-Phe, in the presence and absence of 2-chloroadenosine or cytochalasin B, and by latex beads in the presence and absence of cytochalasin B. Pholasin was also able to detect a longer-lived oxidative activity distinct from myeloperoxidase, and released from neutrophils activated by latex beads or chemotactic peptide; luminol could not. Under optimal conditions pholasin produced a signal some 50-100 times that of luminol in the presence of activated neutrophils. This enabled activation of a single neutrophil by chemotactic peptide (1 microM) to be detected, giving a signal of 194 +/- 21 chemiluminescent counts per second, some six times that of the background signal (mean +/- SD, n = 2). Pholasin thus provides an indicator sufficiently sensitive to establish whether neutrophil activation occurs through thresholds in individual cells.

Proton NMR of aequorin. Structural changes concomitant with calcium-independent light emission.

Aequorin, a Ca(II)-sensitive bioluminescent protein from jellyfish, emits light at 469 nm from an excited state of a substituted pyrazine (oxyluciferin) which results from the oxidation of a chromophore molecule that is noncovalently bound to the protein. The chromophore is oxidized when Ca(II) or other activating metal ions are bound by aequorin. In the absence of Ca(II), spontaneous emission of light, referred to as Ca(II)-independent light emission, occurs at a rate less than 10(-6) of that for Ca(II)-induced emission. Proton nuclear magnetic resonance (NMR), circular dichroism (CD), and fluorescence were used to study structural changes of aequorin accompanying Ca(II)-independent light emission. Time course studies by 1H NMR and CD demonstrate that as a result of Ca(II)-independent light emission, aequorin progressively changes from a rigid, fully active form showing little segmental mobility to a practically unfolded, discharged (i.e., inactive) form in which a number of amino acid residues are significantly mobile. This slow discharged protein (SDP) is distinct in nature and conformation from aequorin which has been discharged by Ca(II), i.e., the blue fluorescent protein. The rate of Ca(II)-independent discharge of aequorin is substantially reduced in the presence of excess Mg(II); the time constant for inactivation at 5 degrees C is 30 days with no Mg(II) present and 70 days with Mg(II) present. The NMR spectra are nearly identical at a given stage of inactivation whether or not Mg(II) is present. Oxyluciferin remains bound to SDP. If it is removed, however, by column chromatography, the resulting apo-SDP partially refolds, and the segmental mobility acquired in the formation of SDP is significantly attenuated particularly for some of the aromatic amino acid residues.

Biochemistry of dinoflagellate bioluminescence: purification and characterization of dinoflagellate luciferin from Pyrocystis lunula.

Bioluminescence in all dinoflagellate species studied to date is produced by the luciferase-catalyzed oxidation of a newly elucidated type of luciferin, hypothesized to have a substituted polypyrrole-type structure. This paper presents the purification and characterization of the luciferin from Pyrocystis lunula along with evidence that it is a polypyrrole-type molecule. Luciferin is extremely labile at low pH, at high salt concentration, and to O2, so, where possible, the purification steps were carried out in the presence of a buffered reducing agent and under argon. Purified luciferin is soluble in water and polar organic solvents. It is yellow (lambda max 245 and 390 nm with a shoulder at 290 nm in neutral or basic aqueous solution) and displays a strong blue fluorescence (lambda max for excitation at 390 nm, for emission at 474 nm) that closely matches the bioluminescence emission spectrum [Bode, V. C., & Hastings, J. W. (1963) Arch. Biochem. Biophys. 103, 488--499]. Autoxidation leads to concomitant decreases in the 390-nm absorbance, 474-nm fluorescence, and biological activity; similar changes occurred with oxidation by K3Fe(CN)6, thus allowing a quantitation of luciferin by titration. Luciferin has a molecular weight between 500 and 600, displays positive Ehrlich and Schlesinger reactions, and yields on acid chromate oxidation fragments apparently resembling substituted maleimides; these data support the proposal that dinoflagellate luciferin contains a substituted polypyrrole of the bile pigment type.

Structural identification and synthesis of luciferin from the bioluminescent earthworm, Diplocardia longa.

For the first time, luciferin from a bioluminescent earthworm has been purified, identified, and synthesized. This luciferin from the North American species, Diplocardia longa, is a simple aldehyde compound, N-isovaleryl-3-aminopropanal, with an amide functional group. It is a clear, odorless oil at room temperature. It is nonvolatile and has no near-uv-visible absorption or fluorescence. Derivatives of this compound were made to facilitate its identification: the luciferin 2,4-dinitrophenylhydrazone (mp 174 degrees C), a yellow crystalline solid; and the luciferin alcohol, a clear oil. Synthesis of Diplocardia luciferin yielded an oil of identical spectroscopic (proton nuclear magnetic resonance (NMR), 13C NMR, mass, and ir), chemical (dinitrophenylhydrazone and alcohol derivatives, bioluminescence activity), and physical (thin-layer chromatography, volatility) properties to those of the purified native Diplocardia luciferin.

Dinoflagellate bioluminescence: a comparative study of invitro components.

In vitro bioluminescence components of the dinoflagellates Gonyaulax polyedra, G. tamarensis, Dissodinium lunual, and Pyrocystis noctiluca were studied. The luciferases and luciferins of the four species cross-react in all combinations. All of these species possess high-molecular weight luciferases (200,000-400,000 daltons) with similar pH activity profiles. The active single chains of luciferases from the Gonyaulax species have a MW of 130,000 while those from P. noctiluca and D. lunula have a MW of 60,000. Extractable luciferase activity varies with time of day in the two Gonyaulax species, but not in the other two. A luciferin binding protein (LBP) can easily be extracted from the two Gonyaulax species (MW approximately 120,000 daltons), but none could be detected in extracts of either D. lunula or P. noctiluca. Scintillons are extractable from all four species, but they vary in density and the degree to which activity can be increased by added luciferin. Although the biochemistry of bioluminescence in these dinoflagellates is generally similar, the observations that D. lunula and P. noctiluca apparently lack LBP and have luciferases with low MW single chains require further clarification.

Oplophorus oxyluciferin and a model luciferin compound biologically active with Oplophorus luciferase.

The luciferin of the bioluminescent decapod shrimp, Oplophorus gracilorostris, was purified and studied with respect to u.v. spectrum, fluorescence spectrum, mass spectrum and luminescent cross-reaction with the enzyme luciferase of the bioluminescent ostracod, Cypridina hilgendorfii. On the basis of these results, an empirical formula C10H13N3O3 and an imidazo [1,2-a]pyrazin-3-one structure are proposed for luciferin. Of three model luciferin compounds, 3-hydroxy-2-methylimidazo[1,2-a]pyridine is biologically active with both Oplophorus and Cypridina luciferase, indicating that a pyrazine structure is not essential for biological activity with Cypridina luciferase.

Extraction of Renilla-type luciferin from the calcium-activated photoproteins aequorin, mnemiopsin, and berovin.

Photoproteins, which emit light in an oxygen-independent intramolecular reaction initiated by calcium ions, have been isolated from several bioluminescent organisms, including the hydrozoan jellyfish Aequorea and the ctenophore Mnemiopsis. The system of a related anthozoan coelenterate, the sea pansy Renilla reniformis, however, is oxygen dependent, requiring two organic components, luciferin and luciferase. Previously published indirect evidence indicates that photoproteins may contain a Renilla-type luciferin. We have now extracted in high yield a Renilla-type luciferin from three photoproteins, aequorin (45% yield), mnemiopsin (98% yield), and berovin (85% yield). Photoprotein luciferin, released from the holoprotein by mercaptoethanol treatment and separated from apo-photoprotein by gel filtration, no longer responds to calcium but now requires luciferase and O2 for light production. Photoprotein luciferin is identical to Renilla luciferin with respect to reaction kinetics and bioluminescence spectral distribution. In view of these results, the generally accepted hypothesis that the photoprotein chromophore is a protein-stabilized hydroperoxide of luciferin must be modified. We believe, instead, that the chromophore is free luciferin and that oxygen is bound as an oxygenated derivative of an amino-acid side chain of the protein. We propose the general term "coelenterate luciferin" to describe the light-producing chromophore from all bioluminescent coelenterates and ctenophores.