Mutant Analysis and Enzyme Subunit Complementation in Bacterial Bioluminescence in Photobacterium fischeri

Chemical mutagens were used to obtain mutants deficient in bioluminescence in the marine bacterium Photobacterium fischeri strain MAV. Acridine dyes were effective in the production of dark mutants but not in the production of auxotrophs. These dark mutants were all of one type and appeared to contain lesions blocking the synthesis of luciferase. ICR-191 was especially effective in the production of aldehyde mutants, i.e., dark strains that luminesce when a long-chain aldehyde such as n-decanal is added to them. However, other mutant types were isolated after treatment with ICR-191. N-methyl-N'-nitro-N-nitrosoguanidine induced many bioluminescence-deficient types with respect to both the site of the lesion and the quantitative effect on the luminescent system. We characterized the dark and dim mutants with respect to their response to exogenous decanal, levels of in vivo and in vitro luminescence, and their rates of reversion to wild type. In addition, the luciferases of the mutant strains were examined by subunit complementation. On the basis of these analyses, we identified mutants which synthesize altered luciferase, strains which are deficient in synthesis of luciferase, and aldehyde mutants. The results of analysis of luciferase from the aldehyde mutants and the complementation studies indicate that the lesions in these strains are in the luciferase itself. Results obtained with wild-type cells grown in minimal medium, and aldehyde mutant cells grown either in complete or minimal medium, indicate that a "natural aldehyde factor" is involved in in vivo light emission. These same studies showed that the long-chain aldehyde(s) could only partially substitute for the natural "aldehyde factor." The possibility that the in vivo aldehyde factor is not a long-chain aldehyde is discussed.     

ATP pool and bioluminescence in psychrophilic bacteria Photobacterium phosphoreum

Bioluminescence activity and ATP pool were investigated in the cells of psychrophilic bacteria Photobacterium phosphoreum collected from the exponential and stationary growth phases and immobilized in polyvinyl alcohol (PVA) cryogel. In liquid culture, ATP pool remained at an almost constant level throughout the luminescence cycle (over 100 h). The ATP pool in the stationary-phase and PVA-immobilized cells remained constant throughout their incubation in the medium (over 200 h) and in 3% NaCl solution (over 100 h). Quantitative assessment of integral photon yield and ATP pool indicated that bioluminescence decay in growing or stationary cells was not caused by limitation from the energy substrates of the luciferase reaction. Kinetic and quantitative parameters of emission activity and ATP pool excluded the possibility of formation of the aldehyde substrate for luciferase via reduction of the relevant fatty acids in NADPH and ATP-dependent reductase reaction and its oxidation in the monooxygenase reaction. Our results indicate that the aliphatic aldehyde is not utilized in the process of light emission.     

Luciferase inactivation in the luminous marine bacterium Vibrio harveyi.

Luciferase was rapidly inactivated in stationary-phase cultures of the wild type of the luminous marine bacterium Vibrio harveyi, but was stable in stationary-phase cultures of mutants of V. harveyi that are nonluminous without exogenous aldehyde, termed the aldehyde-deficient mutants. The inactivation in the wild type was halted by cell lysis and was slowed or stopped by O2 deprivation or by addition of KCN and NaF or of chloramphenicol. If KCN and NaF or chloramphenicol were added to a culture before the onset of luciferase inactivation, then luciferase inactivation did not occur. However, if these inhibitors were added after the onset of luciferase inactivation, then luciferase inactivation continued for about 2 to 3 h before the inactivation process stopped. The onset of luciferase inactivation in early stationary-phase cultures of wild-type cell coincided with a slight drop in the intracellular adenosine 5'-triphosphate (ATP) level from a relatively constant log-phase value of 20 pmol of ATP per microgram of soluble cell protein. Addition of KCN and NaF to a culture shortly after this drop in ATP caused a rapid decrease in the ATP level to about 4 pmol of ATP per microgram whereas chloramphenicol added at this same time caused a transient increase in ATP level to about 25 pmol/microgram. The aldehyde-deficient mutant (M17) showed a relatively constant log-phase ATP level identical with that of the wild-type cells, but rather than decreasing in early stationary phase, the ATP level increased to a value twice that in log-phase cells. We suggest that the inactivation of luciferase is dependent on the synthesis of some factor which is produced during stationary phase and is itself unstable, and whose synthesis is blocked by chloramphenicol or cyanide plus fluoride.     

Bacterial bioluminescence in vivo: control and synthesis of aldehyde factor in temperature-conditional luminescence mutants

Bioluminescent marine bacteria possess luciferase, which catalyzes the oxidation of reduced flavin mononucleotide and long-chain aldehyde to produce light. Temperature-sensitive mutants of these bacteria can be obtained which require exogenous aldehyde for light production at higher temperatures. In Beneckea harveyi. two classes of such mutants were found which differed with regard to their response to temperature shifts. In one class, a shift from permissive to nonpermissive temperature in liquid cultures resulted in a rapid (t((1/2)) approximately 3 min) loss of luminescence. In the other, there was no immediate decline in luminescence; it was the increase of luminescence that was blocked. Through studies of these and other effects of temperature shifts on the in vivo luminescence of these mutants, we conclude that at least two genes are specifically involved in the in vivo biosynthesis of aldehyde for the luminescence reaction and that both genes are coordinately controlled with that for luciferase.     

Genetic studies of Photobacterium mandapamensis. II. The classification of mutants with an altered luminescence intensity according to their sensitivity to exogenous aldehyde]

The collection of 157 dark and dim Photobacterium mandapamensis strains was divided into four groups using the addition of 0.2 ml of 0.15% myristis aldehyde to cell suspension. The luminescence did not change in the presence of the aldehyde in 76 mutants, it decreased in 30 mutants, it was 2--8-fold increased in 35 mutants, and it was increased more than 10-fold in 16 mutant strains. 19 strains of those having luminescence in the presence of the aldehyde have mutations in genes controlling the biosynthesis of the aldehyde factor. Among them mutants are chosen which can be used as indicators for the aldehyde presence in the medium.     

Toxicity of the bacterial luciferase substrate, n-decyl aldehyde, to Saccharomyces cerevisiae and Caenorhabditis elegans

This study determined that the bacterial luciferase fusion gene (luxAB) was not a suitable in vivo gene reporter in the model eukaryotic organisms Saccharomyces cerevisiae and Caenorhabditis elegans. LuxAB expressing S. cerevisiae strains displayed distinctive rapid decays in luminescence upon addition of the bacterial luciferase substrate, n-decyl aldehyde, suggesting a toxic response. Growth studies and toxicity bioassays have subsequently confirmed, that the aldehyde substrate was toxic to both organisms at concentrations well tolerated by Escherichia coli. As the addition of aldehyde is an integral part of the bacterial luciferase activity assay, our results do not support the use of lux reporter genes for in vivo analyses in these model eukaryotic organisms.     

Assay of ATP in intact cells of the facultative phototroph Rhodobacter capsulatus expressing recombinant firefly luciferase

This study reports on the construction, calibration and use of recombinant cells of Rhodobacter capsulatus expressing the luciferase gene of the North American firefly Photinus pyralis to detect, by bioluminescence, variations of endogenous ATP levels under various physiological conditions. We show that the antibiotic polymyxin B allows luciferin to rapidly move into cell cytosol, but does not make external ATP freely accessible to intracellular luciferase. Notably, in toluene:ethanol-permeabilized cells, the apparent K(mATP) for luciferase (50 microM) is similar to that measured in soluble cell fractions. This finding limits the applicability of the firefly luciferase for monitoring intracellular maximal ATP concentration because dark/aerobic-grown recombinant cells of Rba. capsulatus contain approximately 1.3-2.6+/-0.5 mM ATP. Therefore, the effects of chemical and physical factors such as oxygen, light, carbonyl cyanide m-chlorophenyl hydrazone and antimycin A on ATP synthesis were examined in cells subjected to different starvation periods to reduce the endogenous ATP pool below the luciferase ATP saturation level (< or =0.2 mM). We conclude that the amount of endogenous ATP generated by light is maximal in the presence of oxygen, which is required to optimize the membrane redox poise.     

Inhibition of Vibrio harveyi bioluminescence by cerulenin: in vivo evidence for covalent modification of the reductase enzyme involved in aldehyde synthesis.

Bacterial bioluminescence is very sensitive to cerulenin, a fungal antibiotic which is known to inhibit fatty acid synthesis. When Vibrio harveyi cells pretreated with cerulenin were incubated with [3H]myristic acid in vivo, acylation of the 57-kilodalton reductase subunit of the luminescence-specific fatty acid reductase complex was specifically inhibited. In contrast, in vitro acylation of both the synthetase and transferase subunits, as well as the activities of luciferase, transferase, and aldehyde dehydrogenase, were not adversely affected by cerulenin. Light emission of wild-type V. harveyi was 20-fold less sensitive to cerulenin at low concentrations (10 micrograms/ml) than that of the dark mutant strain M17, which requires exogenous myristic acid for luminescence because of a defective transferase subunit. The sensitivity of myristic acid-stimulated luminescence in the mutant strain M17 exceeded that of phospholipid synthesis from [14C]acetate, whereas uptake and incorporation of exogenous [14C]myristic acid into phospholipids was increased by cerulenin. The reductase subunit could be labeled by incubating M17 cells with [3H]tetrahydrocerulenin; this labeling was prevented by preincubation with either unlabeled cerulenin or myristic acid. Labeling of the reductase subunit with [3H]tetrahydrocerulenin was also noted in an aldehyde-stimulated mutant (A16) but not in wild-type cells or in another aldehyde-stimulated mutant (M42) in which [3H]myristoyl turnover at the reductase subunit was found to be defective. These results indicate that (i) cerulenin specifically and covalently inhibits the reductase component of aldehyde synthesis, (ii) this enzyme is partially protected from cerulenin inhibition in the wild-type strain in vivo, and (iii) two dark mutants which exhibit similar luminescence phenotypes (mutants A16 and M42) are blocked at different stages of fatty acid reduction.     

Control of aldehyde synthesis in the luminous bacterium Beneckea harveyi.

Some of the Beneckea harveyi dim aldehyde mutants, all of which emit light upon addition of exogenous long-chain aldehyde, also emit light when myristic acid is added. Analysis of these myristic acid-responsive mutants indicates that they are blocked before fatty acid formation, whereas another class of mutants, which respond only to aldehyde, appear to be defective in the enzyme(s) involved in the conversion of acid to aldehyde. Evidence is presented that this activity, designated myristic acid reductase, is coinduced with luciferase and is involved in the recycling of acid produced in the luciferase reaction, with specificity for the C14 compounds.     

Differential regulation of enzyme activities involved in aldehyde metabolism in the luminescent bacterium Vibrio harveyi.

The effects of catabolite repression and nutrient abundance on the activities of Vibrio harveyi enzymes known to be related to aldehyde metabolism were investigated. The growth of cells in complex medium containing glucose, which decreases in vivo luminescence and luciferase synthesis, also resulted in decreases in the specific activities of V. harveyi aldehyde dehydrogenase and acyl carrier protein acyltransferase as well as in the degree of fatty acylation of three bioluminescence-specific polypeptides (32, 42, and 57 kilodaltons), as monitored by sodium dodecyl sulfatepolyacrylamide gel electrophoresis. This repression was partially alleviated in glucose medium containing cyclic AMP. The acylation of the above-mentioned proteins, in addition to light emission and luciferase and acyltransferase activities, was also repressed when cells were grown in minimal medium, with partial recovery of these functions upon the addition of arginine. In contrast, aldehyde dehydrogenase activity was increased in minimal medium. These results suggest that the 42-, 57-, and 32-kilodalton proteins, which are responsible for the supply and reduction of fatty acids to form aldehydes for the luciferase reaction, are regulated in the same way as luciferase under the above-described conditions. However, aldehyde dehydrogenase, whose role in V. harveyi aldehyde metabolism is not yet known, is regulated in a different way with respect to nutrient composition.     

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.     

Autoinduction in a luminous bacterium: A confirmation of the hypothesis

In some luminous bacterial species, it is postulated that luciferase is “autoinduced” by a substance produced by the bacteria themselves. This hypothesis was confirmed. In experiments with growing cultures that were subjected to repeated subculturing into or dialysis against fresh medium, which should prevent the autoinducer from accumulating, the normal synthesis of luciferase and the development of luminescence did not occur.     

Inhibition of bioluminescence in Photobacterium phosphoreum by sulfamethizole and its stimulation by thymine

In bioluminescent bacteria very few agents have been reported that can selectively inhibit the luminescence. In sensitivity tests with Photobacterium phosphoreum, using 55 different antibiotics, it was found that sulfamethizole, an inhibitor of dihydropteroate synthetase and the formation of folic acid, inhibited bioluminescence more than growth. Likewise, in mutants requiring thymine for growth, the luminescence per cell was much less in a medium low in thymine. In neither case could the decreased specific luminescence be attributed to a decrease in the cellular level of luciferase or aldehyde factor; the involvement of additional but unidentified factors in the regulation of in vivo bioluminescence is postulated.     

Ca2+ oscillations stimulate an ATP increase during fertilization of mouse eggs

Mammalian eggs and embryos rely upon mitochondrial ATP production to survive and proceed through preimplantation development. Ca(2+) oscillations at fertilization have been shown to cause a reduction of mitochondrial NAD+ and flavoproteins, suggesting they might also cause changes in cytosolic ATP levels. Here, we have monitored intracellular Ca(2+) and ATP levels in fertilizing mouse eggs by imaging the fluorescence of a Ca(2+) dye and luminescence of firefly luciferase. At fertilization an initial increase in ATP levels occurs with the first Ca(2+) transient, with a second increase occurring about 1 h later. The increase in cytosolic ATP was estimated to be from a prefertilization concentration of 1.9 mM to a peak value of 3 mM. ATP levels returned to prefertilization values as the Ca(2+) oscillations terminated. An increase in ATP also occurred with other stimuli that increase Ca(2+) and it was blocked when Ca(2+) oscillations were inhibited by BAPTA injection. Additionally, an ATP increase was not seen when eggs were activated by cycloheximide, which does not cause a Ca(2+) increase. These data suggest that mammalian fertilization is associated with a sudden but transient increase in cytosolic ATP and that Ca(2+) oscillations are both necessary and sufficient to cause this increase in ATP levels.     

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 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.     

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.     

Mutants of luminous bacteria with an altered control of luciferase synthesis.

Arginine is known to increase the luminescence in vivo and in vitro of the marine bacterium Beneckea harveyi growing in minimal medium. Mutants in which this arginine effect is either diminished, or absent were isolated as bright clones on a minimal medium after N-methyl-N'-nitro-N-nitrosoguanidine mutagenesis. On a minimal medium both with and without added arginine and also on complex medium, these "minimal bright" mutants produce higher levels of luminescence than the wild type both in vivo and in vitro. This is attributed to the production of an increased amount of luciferase, which itself is wild type in terms of its specific activity.     

Shifts in the intracellular ATP pools of immobilisedNostoc cells (Cyanobacteria) induced by water stress

Summary Immobilised, desiccated cells ofNostoc commune UTEX 584 have the capacity to increase the size of their extractable intracellular ATP pool upon rewetting. The time taken to recover the pool size depends on the conditions of storage at a particular water potential and the duration of storage. Under the conditions employed, the rewetting of cells induced an increase in ATP pool size at the expense of photophosphorylation or electron transport (oxidative) phosphorylation. The rise in the ATP pool size was instantaneous and was shown to be due to ATP synthesis. This increase did not occur when cells were rewetted in the presence of sodium azide (10 mmol/l), while a partial inhibition was observed with CCCP (carbonyl cyanidem-chlorophenylhydrazone; 2 mol/l). For cells dried at more extreme water potentials, the lag ofc 48 h observed before the ATP pool reached control values is of similar duration to that observed in the recovery of nitrogenase upon rewetting. Chloramphenicol (10 mol/l) stimulated significantly the upshift in the size of the ATP pool ofNostoc cells upon rewetting, yet inhibited completely the rise in nitrogenase activity.