Localisation of luciferase in luminous marine bacteria by gold immunocytochemical labelling

Abstract Bioluminescent bacteria are able to produce light by an oxidative reaction involving the enzyme luciferase. The biochemistry of the reaction has been well documented. It has been postulated from the reaction pathway that the enzyme luciferase is membrane bound. Two species of luminous bacteria, Vibrio fischeri and V. harveyi , were isolated from sea water, fixed and embedded in resin for transmission electron microscopy. A commercially available V. fischeri bacterial luciferase was used to immunise rats for production of an antibody against luciferase. This antibody was coupled with a protein A gold probe and used to immunolabel the sections of bacteria. It was shown that the luciferase was associated with the inner membrane, and to a lesser extent present in the cytoplasm. Our results confirm that the luciferase is predominantly membrane bound.     

Reversible steps in the reaction of aldehydes with bacterial luciferase intermediates.

Aliphatic aldehydes of different chain lengths were found to differ in their reaction at 22 °C with the B. harveyi luciferase peroxyflavin intermediate. Although similar quantum yields were obtained in the luciferase reaction with the different chain-length aldehydes, the catalytic turnover rates differed. The kinetics of a reaction utilizing two aldehydes of different chain lengths can thus indicate the degree to which the aldehyde reaction is reversible. By such criteria the reactions of octanal and decanal were found to be readily reversible, while that of dodecanal was not. This conclusion was supported both by the effects of long-chain alcohols, which are competitive inhibitors, and by the secondary addition of hydroxylamine, an aldehyde trapping agent. The results are consistent with a model in which there are many intermediates along the reaction path. Since the reactions are monitored by decay of luminescence intensity, it is difficult to determine the position of the rate-determining step. For octanal and decanal the rate-limiting step could be at an early reversible stage of the reaction, but later for dodecanal, subsequent to a less reversible step, but still prior to the final irreversible step which populates the excited state.     

Bioluminescence decay kinetics in the reaction of bacterial luciferase with different aldehydes

At 22°C the bioluminescence decay kinetics in the in vitro reaction catalysed by Vibrio harveyi luciferase in the presence of different aldehydes–-nonanal, decanal, tridecanal and tetradecanal did not follow the simple exponential pattern and could be fitted to a two-exponential process. One more principal distinction from the first-order kinetics is the dependence of the parameters on aldehyde concentration. The complex bioluminescence decay kinetics are interpreted in terms of a scheme, where bacterial luciferase is able to perform multiple turnovers using different flavin species to produce light. The initial phase of the bioluminescent reaction appears to proceed mainly with fully reduced flavin as the substrate while the final one results from the involvement of flavin semiquinone in the catalytic cycle.     

The production of oxyluciferin during the firefly luciferase light reaction.

The luciferase-product complex (E · P) was isolated from the reaction mixture after light emission had occurred. The spectral properties of the product in the E · P complex are similar to those of oxyluciferin, with a broad absorption at 385 nm. The enzyme from the complex regains full activity upon the addition of substrates. The product is not covalently bound to the enzyme and readily dissociates in the presence of 6 m urea. The isolated E · P complex was found to have 1 mol of oxyluciferin per 100,000 daltons of luciferase. No AMP could be detected in the E·P complex unless inorganic pyrophosphatase was present during the reaction. In that case 1 mol of AMP per 100,000 daltons was found.Stopped flow studies showed that an increase in 385 nm absorption occurred concomitant with light emission. Measurement of the initial rate of product formation and the rate of photon emission showed they were identical, suggesting that oxyluciferin is indeed the light-emitting product. In the initial burst of the reaction two oxyluciferin moles per 100,000 daltons of luciferase are formed. A plot of the log of the initial rate of product formation was biphasic, indicating that the first mole of product is formed at a faster rate than the second. These results are consistent with previous experiments. However, they do not resolve the question of the molecular weight of the catalytically active species.     

The binding and spectral alterations of oxidized flavin mononucleotide by bacterial luciferase

The binding of oxidized flavin mononucleotide (FMN) to bacterial luciferase was studied by equilibrium dialysis. A Scatchard plot of the data indicates a single FMN binding site per luciferase molecule, with a dissociation constant of 2.4 × 10^?4 M at 2° in 0.05 M Bis-Tris, 0.2 M NaCl, pH 7.0. The visible absorbance spectrum of luciferase-bound FMN is altered considerably relative to the spectrum of free FMN. The spectrum of the bound flavin shows an apparent splitting of the 443-nm peak yielding well-defined maxima at 458 nm and 434 nm.     

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.     

Differential transfers of reduced flavin cofactor and product by bacterial flavin reductase to luciferase

It is believed that the reduced FMN substrate required by luciferase from luminous bacteria is provided in vivo by NAD(P)H-FMN oxidoreductases (flavin reductases). Our earlier kinetic study indicates a direct flavin cofactor transfer from Vibrio harveyi NADPH-preferring flavin reductase P (FRP(H)) to the luciferase (L(H)) from the same bacterium in the in vitro coupled luminescence reaction. Kinetic studies were carried out in this work to characterize coupled luminescence reactions using FRP(H) and the Vibrio fischeri NAD(P)H-utilizing flavin reductase G (FRG(F)) in combination with L(H) or luciferase from V. fischeri (L(F)). Comparisons of K(m) values of reductases for flavin and pyridine nucleotide substrates in single-enzyme and luciferase-coupled assays indicate a direct transfer of reduced flavin, in contrast to free diffusion, from reductase to luciferase by all enzyme couples tested. Kinetic mechanisms were determined for the FRG(F)-L(F) and FRP(H)-L(F) coupled reactions. For these two and the FRG(F)-L(H) coupled reactions, patterns of FMN inhibition and effects of replacement of the FMN cofactor of FRP(H) and FRG(F) by 2-thioFMN were also characterized. Similar to the FRP(H)-L(H) couple, direct cofactor transfer was detected for FRG(F)-L(F) and FRP(H)-L(F). In contrast, despite the structural similarities between FRG(F) and FRP(H) and between L(F) and L(H), direct flavin product transfer was observed for the FRG(F)-L(H) couple. The mechanism of reduced flavin transfer appears to be delicately controlled by both flavin reductase and luciferase in the couple rather than unilaterally by either enzyme species.     

Dimethyl-and monomethyloxyluciferins as analogs of the product of the bioluminescence reaction catalyzed by firefly luciferase

The absorption and fluorescence spectra of dimethyloxyluciferin (DMOL) and monomethyloxyluciferin (MMOL) were studied at pH 3.0-12.0. In the range of pH 3.0-8.0, the fluorescence spectrum of DMOL exhibits a maximum at lambda(em) = 639 nm. At higher pH values an additional emission maximum appears at lambda(em) = 500 nm (wavelength of excitation maximum lambda(ex) = 350 nm), which intensity increases with time. It is shown that this peak corresponds to the product of DMOL decomposition at pH > 8.0. The absorption spectra of MMOL were studied in the range of pH 6.0-9.0. At pH 8.0-9.0, the absorption spectrum of MMOL exhibits one peak at lambda(abs) = 440 nm. At pH 7.3-7.7, an additional band appears with maximum at lambda(abs) = 390 nm. At pH 6.0-7.0 two maxima are observed, at lambda(abs) = 375 and 440 nm. The fluorescence spectra of MMOL (pH 6.0-9.7, lambda(ex) = 440 or 375 nm) exhibit one maximum. It is shown that decomposition of DMOL and MMOL in aqueous solutions results in products of similar structure. DMOL and MMOL are rather stable at the pH optimum of luciferase. It is suggested that they can be used as fluorescent markers for investigation of the active site of the enzyme.     

Enhancement of light emission in the bacterial luciferase reaction by H2O2

In the bacterial luciferase reaction, light emission is due to the mixed function oxidation of FMNH2 and long chain aldehydes, which leads to the formation of an electronically excited product species, postulated to be luciferase-bound 4a-hydroxy flavin. In the present work it was found that H2O2 stimulates an additional and kinetically distinct luminescence. The stimulation is more apparent in reactions inhibited by long chain alcohols, and the H2O2 is effective even if added secondarily. The stimulation requires H2O2 only at the outset; its subsequent destruction by catalase does not diminish the response, appreciably.     

Taxonomy of the marine,luminous bacteria

Summary One hundred and seventy-three strains of marine, luminous bacteria isolated from sea water, surfaces and intestines of fish, as well as from the luminous organs of fish and squid were submitted to an extensive phenotypic characterization. A numerical analysis of the results grouped these strains into four clusters which were formed on the basis of overall phenotypic similarity. One cluster, which was given the designationBeneckea harveyi, consisted of strains which had a moles% GC content in their DNAs of 46.5±1.3 and a single, sheathed, polar flagellum when grown in liquid medium. Most of these strains had unsheathed, peritrichous flagella in addition to the sheathed, polar flagellum when grown on solid medium. The two phenotypically similar clusters which were assigned the species designationsPhotobacterium phosphoreum andP. mandapamensis consisted of strains which had 1–3 unsheathed, polar flagella and moles % GC contents in their DNAs of 41.5±0.7 and 42.9±0.5, respectively. The cluster designatedP. fischeri contained strains having 2–8 sheathed, polar flagella and a moles % GC content of 39.8±1.1. These four species could be further distinguished on the basis of a number of nutritional properties as well as other phenotypic traits. The assignment of the luminous, marine bacteria to four species was supported by differences in the properties of the luminous system as well as differences in the pattern of regulation of spartokinase activity which are discussed. The speciesB. harveyi was found to be phenotypically similar to a number of previously characterized, non-luminous strains ofBeneckea which should probably be assigned to this species.Non-Standard Abbreviations ASW artificial sea water - ATCC American Type Culture Collection - BM basal medium - BMA basal medium agar - GC guanine plus cytosine - LA luminous medium agar - LB luminous medium broth - MA Difco Marine Agar - NCMB National Collection of Marine Bacteria - PHB poly--hydroxybutyrate - S similarity coefficient - YEB yeast extract broth This paper is part of a dissertation submitted by the senior author to the Graduate Division of the University of Hawaii in partial fulfillment of the requirements for the Ph.D. Degree in Microbiology     

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.     

Contribution by symbiotically luminous fishes to the occurrence and bioluminescence of luminous bacteria in seawater

Seawater samples from a variety of locations contained viable luminous bacteria, but luminescence was not detectable although the system used to measure light was sensitive enough to measure light from a single, fully induced luminous bacterial cell. When the symbiotically luminous fishCleidopus gloriamaris was placed in a sterile aquarium, plate counts of water samples showed an increase in luminous colony-forming units. Luminescence also increased, decreasing when the fish was removed. Light measurements of water samples from a sterile aquarium containingPhotoblepharon palpebratus, another symbiotically luminous fish, whose bacterial symbionts have not been cultured, showed a similar pattern of increasing light which rapidly decreased upon removal of the fish. These experiments suggest that symbiotically luminous fishes release brightly luminous bacteria from light organs into their environment and may be a source of planktonic luminous bacteria. Although planktonic luminous bacteria are generally not bright when found in seawater, water samples from environments with populations of symbiotically luminous fish may show detectable levels of light.     

Classification of luminous bacteria from the light organ of the Australian Pinecone fish,Cleidopus gloriamaris

Luminous bacteria isolated from the light organs of the Australian Pinecone fish Cleidopus gloriamaris have been studied. The isolates were from fish from four different geographical estuarine systems on the east coast of Australia. All isolates were found to be strains of Vibrio fischeri, a species not hitherto demonstrated conclusively as forming a symbiotic association. Some ecological considerations are discussed.Non-Standard Abbreviation PHB polyhydroxybutyrate     

Relationship of the luminous bacterial symbiont of the Caribbean flashlight fish,Kryptophanaron alfredi (family Anomalopidae) to other luminous bacteria based on bacterial luciferase (luxA) genes

Flashlight fishes (family Anomalopidae) have light organs that contain luminous bacterial symbionts. Although the symbionts have not yet been successfully cultured, the luciferase genes have been cloned directly from the light organ of the Caribbean species, Kryptophanaron alfredi. The goal of this project was to evaluate the relationship of the symbiont to free-living luminous bacteria by comparison of genes coding for bacterial luciferase (lux genes). Hybridization of a luxAB probe from the Kryptophanaron alfredi symbiont to DNAs from 9 strains (8 species) of luminous bacteria showed that none of the strains tested had lux genes highly similar to the symbiont. The most similar were a group consisting of Vibrio harveyi, Vibrio splendidus and Vibrio orientalis. The nucleotide sequence of the luciferase subunit gene luxA of the Kryptophanaron alfredi symbiont was determined in order to do a more detailed comparison with published luxA sequences from Vibrio harveyi, Vibrio fischeri and Photobacterium leiognathi. The hybridization results, sequence comparisons and the mol% G+C of the Kryptophanaron alfredi symbiont luxA gene suggest that the symbiont may be considered as a new species of luminous Vibrio related to Vibrio harveyi.The nucleotide sequence reported in this article has been deposited in Genbank under accession number M36597     

Pyruvate production and excretion by the luminous marine bacteria.

During aerobic growth on glucose, several species of luminous marine bacteria exhibited an imcomplete oxidative catabolism of substrate. Pyruvate, one of the products of glucose metabolism, was excreted into the medium during exponential growth and accounted for up to 50% of the substrate carbon metabolized. When glucose was depleted from the medium, the excreted pyruvate was promptly utilized, demonstrating that the cells are capable of pyruvate catabolism. Pyruvate excretion is not a general phenomenon of carbohydrate metabolism since it does not occur during the utilization of glycerol or maltose. When cells pregrown on glycerol were exposed to glucose, they began to excrete pyruvate, even if protein synthesis was blocked with chloramphenicol. Glucose thus appears to have an effect on the activity of preexisting catabolic enzymes.