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.     

Molecular biology of bacterial bioluminescence.

The cloning and expression of the lux genes from different luminescent bacteria including marine and terrestrial species have led to significant advances in our knowledge of the molecular biology of bacterial bioluminescence. All lux operons have a common gene organization of luxCDAB(F)E, with luxAB coding for luciferase and luxCDE coding for the fatty acid reductase complex responsible for synthesizing fatty aldehydes for the luminescence reaction, whereas significant differences exist in their sequences and properties as well as in the presence of other lux genes (I, R, F, G, and H). Recognition of the regulatory genes as well as diffusible metabolites that control the growth-dependent induction of luminescence (autoinducers) in some species has advanced our understanding of this unique regulatory mechanism in which the autoinducers appear to serve as sensors of the chemical or nutritional environment. The lux genes have now been transferred into a variety of different organisms to generate new luminescent species. Naturally dark bacteria containing the luxCDABE and luxAB genes, respectively, are luminescent or emit light on addition of aldehyde. Fusion of the luxAB genes has also allowed the expression of luciferase under a single promoter in eukaryotic systems. The ability to express the lux genes in a variety of prokaryotic and eukaryotic organisms and the ease and sensitivity of the luminescence assay demonstrate the considerable potential of the widespread application of the lux genes as reporters of gene expression and metabolic function.     

Stimulation of DNA repair as an evolutionary drive for bacterial luminescence

It was demonstrated recently that luminescence of a free‐living marine bacterium, Vibrio harveyi, stimulates DNA repair, most probably by activation of the photoreactivation process. Here, we ask whether the stimulation of DNA repair could be an evolutionary drive that ensured maintenance and development of early bacterial luminescent systems. To test this hypothesis, we cultivated V. harveyi lux⁺ bacteria and luxA mutants in mixed cultures. Initial cultures were mixed to obtain a culture consisting of roughly 50% lux⁺ cells and 50% luxA mutants. Then bacteria were cultivated for several days and ratio of luminescent to dark bacteria was measured. Under these conditions, luxA mutants became highly predominant within a few days of cultivation. This indicates that, without a selective pressure, the luminescence is a disadvantage for bacteria, perhaps due to consumption of significant portion of cell energy. However, when the same experiments were repeated but cultures were irradiated with low UV doses, luminescent bacteria started to predominate shortly after the irradiation. Therefore, we conclude that stimulation of photoreactivation may be an evolutionary drive for bacterial bioluminescence. Copyright © 2003 John Wiley & Sons, Ltd.     

Carbohydrate specificity of lectins from luminescent bacteria

The presence of lectins on a cell surface was demonstrated for 70 cultures of luminescent bacteria using hemagglutination reactions. It was shown that hemagglutination of luminescent bacteria is inhibited by glucose, maltose, fructose, mannose, and N-acetyl-D-glucosamine. The differences in the inhibition of hemagglutination of luminescent and nonluminescent (spontaneous mutants) symbiotic cultures by N-acetyl-D-galactosamine were revealed. The fact that N-acetyl-D-galactosamine inhibits hemagglutination of the luminescent symbiotic bacteria but does not inhibit hemagglutination of the symbiotic cultures lacking luminescence suggests that lectins with N-acetyl-D-galactosamine specificity are possibly involved in the formation and functioning of the symbiosis of luminescent bacteria with marine animals possessing luminous organs.     

Ultrastructure of the "dark" hepatocytes under physiologically normal conditions and in toxic lesion of the liver (a morphometric study)]

Quanity and structural organization of the "dark" hepatocytes are different depending on the functional state of the liver. Therefore, functional estimation of the liver state with a changed number of "dark" hepatocytes demands detection of factors determining the changes in their organization and quantity in the organ.     

Interplay of two quorum sensing regulation systems of Vibrio fischeri

Many bacteria developed a possibility to recognise aspects of their environment or to communicate with each other by chemical signals. An important strategy is the so-called quorum sensing (QS), a regulatory mechanism for the gene expression, where the bacteria measure their own cell density by means of this signalling pathway. One of the best-studied species using QS is the marine luminescent bacterium Vibrio fischeri which is considered here as a model organism.The two main regulatory pathways (lux and ain) are combined to a regulation system, the dynamics is modelled by an ODE system. This system is analysed thoroughly, considering stationary states, dynamical behaviour and the possible biological meaning of it. The influence of different parameter values on the behaviour is examined, the same basic system is able to reflect the peculiarities of different bacteria strains (respectively, their mutants).     

New rapid and simple methods for detection of bacteria and determination of their antibiotic susceptibility by using phage mutants

Three new methods applying a novel approach for rapid and simple detection of specific bacteria, based on plaque formation as the end point of the phage lytic cycle, are described. Different procedures were designed to ensure that the resulting plaques were derived only from infected target bacteria ("infectious centers"). (i) A pair of amber mutants that cannot form plaques at concentrations lower than their reversion rate underwent complementation in the tested bacteria; the number of plaques formed was proportional to the concentration of the bacteria that were coinfected by these phage mutants. (ii) UV-irradiated phages were recovered by photoreactivation and/or SOS repair mediated by target bacteria and plated on a recA uvrA bacterial lawn in the dark to avoid recovery of noninfecting phages. (iii) Pairs of temperature-sensitive mutants were allowed to coinfect their target bacteria at the permissive temperature, followed by incubation of the plates at the restrictive temperature to avoid phage infection of the host cells. This method allowed the omission of centrifuging and washing the infected cells. Only phages that recovered by recombination or complementation were able to form plaques. The detection limit was 1 to 10 living Salmonella or Escherichia coli O157 cells after 3 to 5 h. The antibiotic susceptibility of the target bacteria could also be determined in each of these procedures by preincubating the target bacteria with antibiotic prior to phage infection. Bacteria sensitive to the antibiotic lost the ability to form infectious centers.     

发光细菌在水环境生物毒性检测中应用的研究进展

发光细菌是一类自身含发光基因且能够发出可见光的细菌,其分布非常广泛。由于具备了日常毒性检测所要求的快速灵敏以及再现性好的特点,发光细菌法愈来愈受到关注,且因其快速和低成本的特点常被用作早期预警系统。基因操作技术的介入更使得发光细菌试验具有了分辨各种毒性的功能。本文综述了发光细菌在环境毒性检测中的进展,重点介绍了基于发光细菌的毒性试验方法,以及在水质检测中的应用。     

Carbohydrate specificity of lectins from luminous bacteria

The presence of lectins on a cell surface was demonstrated for 70 cultures of luminous bacteria using hemagglutination reactions. It was shown that hemagglutination of luminous bacteria is inhibited by glucose, maltose, fructose, mannose, and N-acetyl-D-glucosamine. The differences in the inhibition of hemagglutination of luminescent and nonluminescent (spontaneous mutants) symbiotic cultures by N-acetyl-D-galactosamine were revealed. The fact that N-acetyl-D-galactosamine inhibits hemagglutination of the luminescent symbiotic bacteria but does not inhibit hemagglutination of the symbiotic cultures lacking luminescence suggests that lectins with N-acetyl-D-galactosamine specificity are possibly involved in the formation and functioning of the symbiosis of luminous bacteria with marine animals possessing luminous organs.     

New Rapid and Simple Methods for Detection of Bacteria and Determination of Their Antibiotic Susceptibility by Using Phage Mutants

Three new methods applying a novel approach for rapid and simple detection of specific bacteria, based on plaque formation as the end point of the phage lytic cycle, are described. Different procedures were designed to ensure that the resulting plaques were derived only from infected target bacteria (“infectious centers”). (i) A pair of amber mutants that cannot form plaques at concentrations lower than their reversion rate underwent complementation in the tested bacteria; the number of plaques formed was proportional to the concentration of the bacteria that were coinfected by these phage mutants. (ii) UV-irradiated phages were recovered by photoreactivation and/or SOS repair mediated by target bacteria and plated on a recA uvrA bacterial lawn in the dark to avoid recovery of noninfecting phages. (iii) Pairs of temperature-sensitive mutants were allowed to coinfect their target bacteria at the permissive temperature, followed by incubation of the plates at the restrictive temperature to avoid phage infection of the host cells. This method allowed the omission of centrifuging and washing the infected cells. Only phages that recovered by recombination or complementation were able to form plaques. The detection limit was 1 to 10 living Salmonella or Escherichia coli O157 cells after 3 to 5 h. The antibiotic susceptibility of the target bacteria could also be determined in each of these procedures by preincubating the target bacteria with antibiotic prior to phage infection. Bacteria sensitive to the antibiotic lost the ability to form infectious centers.     

Comparative assessment of toxic effects of surfactants using biotesting methods

This study assesses the comparative sensitivity and possibility of obtaining fast results of various methods of biotesting for several surfactants: Tween 85, sodium dodecyl sulfate (SDS), Fairy dishwashing gel, and Mif washing powder. The following test organisms are used for the study: luminescent bacteria Photobacterium phosphoreum (Beijerinck), preparation of Ecolum luminescent bacteria, unicellular algae Scenedesmus quadricauda (G.M. Smith), infusorian Paramecium caudatum (Ehrenberg), and crustacean Daphnia magna (Straus). It has been revealed that Fairy dishwashing gel possesses the strongest toxicity against the studied test objects. Daphnia and algae are most sensitive to the effects of Fairy and SDS, protozoan and luminescent bacteria are most sensitive to SDS, and Ecolum is most sensitive to Mif washing powder. The tested aquatic organisms and Ecolum are most tolerant to the effect of Tween 85.     

Quantitative criteria for estimating the effectiveness of bioluminescence expression in natural and transgenic luminescent bacteria

Computational coefficients for estimating the effectiveness of bioluminescence expression in natural luminescent bacteria Photobacterium leiognathi 54 and transgenic strain E. coli Z905/pPHL7 bearing lux-operon in a multicopy plasmid are suggested and their use at molecular, cell, and population levels was considered. It was shown that at the population level, all transgenic variants have an advantage over natural variants of P. leiognathi 54 irrespective of the type of lux-operon regulation. At the cell level, the effectiveness of bioluminescence expression in the bright and dim variants of the transgenic strain increased by several orders. At the level of one lux-operon, the effectiveness of expression in the bright variant of the transgenic strain is substantially higher than in the natural bright variant; in dim variants, the efficiency values are similar; the effectiveness of bioluminescence expression in the dark variant of E. coli Z905-2/pPHL7 is by two orders of magnitude lower than in the dark variant of P. leiognathi 54.     

Virulence of luminescent and non-luminescent isogenic vibrios towards gnotobiotic Artemia franciscana larvae and specific pathogen-free Litopenaeus vannamei shrimp

Aims:  This study was conducted to test the virulence of luminescent (L) and non-luminescent (NL) isogenic strains of Vibrio campbellii LMG21363, Vibrio harveyi BB120 (wild type) and quorum-sensing mutant strains derived from the wild type such as Vibrio harveyi BB152, BB170, MM30 and BB886.
Methods and Results:  The NL strains could be obtained by culturing rifampicin-resistant luminescent strains in the dark under static condition. The virulence of the L and NL strains was tested in gnotobiotic Artemia franciscana larvae challenged with 10⁴ CFU ml⁻¹ of bacteria. All luminescent isogenic tested strains showed higher virulence compared to the NL strains. The virulence of L and NL V. campbellii and V. harveyi BB120 was also tested in specific pathogen-free juvenile shrimp upon intramuscular injection with 10⁶ CFU of bacteria. In contrast with Artemia , there was no significant difference in mortality between the groups challenged with L and NL strains ( P  > 0·05). The non-luminescent strains were not able to revert back to the luminescent state and quorum sensing did not influence this phenotypic shift.
Conclusions:  Luminescent Vibrio strains can switch to a non-luminescent state by culturing them in static conditions. The NL strains become less virulent as verified in Artemia .
Significance and Impact of the Study:  The luminescent state of Vibrio cells in a culture needs to be verified in order to assure maintenance of virulence.     

Generation and properties of a luminescent insect pathogen Xenorhabdus nematophilus (Enterobacteriaceae)

Studies on the interaction of the insect pathogenic bacterium, Xenorhabdus nematophilus (Enterobacteriaceae), with its nematode and insect hosts would be greatly assisted if a luminescent phenotype were generated that would allow the detection of viable bacteria in vivo without the necessity for disruption of the cellular interactions. The plasmid, pMGM221, containing the luminescence gene (luxCDABE) of Vibrio harveyi was introduced into different strains (DD136 and 19061) and phases (one and two) of X. nematophilus by triparental mating. For reproducible and efficient conjugation, it was necessary to use older cultures (96-160 h) in the stationary phase of X. nematophilus for mating with relatively small differences (<2-fold) in transconjugant yield for the different strains and phases of X. nematophilus. All transconjugants emitted high levels of light with optimum bioluminescence at 27 degrees C in Luria broth at pH 8.0 containing 20 g/L NaCl; pH, osmolarity, and temperature conditions were similar to those encountered by the bacteria in the hemolymph of the larvae of Galleria mellonella. Plasmids were detected in the transconjugants after 6 months of subculturing the bacteria without antibiotic selection. Aside from light emission, luminescent transconjugants had the same physiological properties as the nonluminescent parental strains, including identical rates of growth, production of exoenzymes, removal from and subsequent emergence into the insect's hemolymph, bacterial-induced hemocyte damage, suppression of prophenoloxidase activation, and the ability to kill G. mellonella larvae. Light-emitting larvae could readily be detected by eye in a dark room, and all bacteria reisolated from dead larvae were luminescent. These properties validate the use of luminescent X. nematophilus not only as a means of following bacterial host interactions, but also as a potential agent to follow the infection and death of the insect population.     

Studies on the ultraviolet-sensitive mutants of blue-green alga Synechocystis aquatilis Sanv.

Summary Several mutants of the unicellular blue-green alga Synechocystis aquatilis Sanv. were isolated. They differed from the wild type by the levels of sensitivity to ultraviolet (UV) irradiation. The most sensitive mutant is unable to carry out photoreactivation and shows increased resistance to mitomycin C, N-methyl-N-nitro-N-nitrosoguanidine and methyl methanesulfonate. This strain shows an enhanced rate of spontaneous and UV-induced mutagenesis. Another UV-sensitive mutant with normal level of X-ray sensitivity is characterized by a decreased mutability. The three other UV-sensitive mutants show simultaneous decrease of resistance to X-ray and alkylating agents. The existence of these cross-sensitive mutants indicates that a repair mechanism may operate in blue-green algae similar to dark repair systems of bacteria and yeast.     

Isolation and characterization of effector-loop mutants of CDC42 in yeast

The highly conserved small GTPase Cdc42p is a key regulator of cell polarity and cytoskeletal organization in eukaryotic cells. Multiple effectors of Cdc42p have been identified, although it is unclear how their activities are coordinated to produce particular cell behaviors. One strategy used to address the contributions made by different effector pathways downstream of small GTPases has been the use of "effector-loop" mutants of the GTPase that selectively impair only a subset of effector pathways. We now report the generation and preliminary characterization of a set of effector-loop mutants of Saccharomyces cerevisiae CDC42. These mutants define genetically separable pathways influencing actin or septin organization. We have characterized the phenotypic defects of these mutants and the binding defects of the encoded proteins to known yeast Cdc42p effectors in vitro. The results suggest that these effectors cannot account for the observed phenotypes, and therefore that unknown effectors exist that affect both actin and septin organization. The availability of partial function alleles of CDC42 in a genetically tractable system serves as a useful starting point for genetic approaches to identify such novel effectors.     

Heterogeneity of the populations of marine luminescent bacteria Photobacterium leiognathi under different conditions of cultivation

Manifestation of pleiotropic effects in the isogenic variants of luminescent bacteria Photobacterium leiognathi 54 was investigated. The decrease or increase of the expression level of bioluminescence was caused by changes in lux operon regulation. The dynamics of the bioluminescence of dark and dim variants did not differ from the dynamics of the initial luminescent variant, but dependence of the level of luminescence intensity on the exogenous autoinductor of the lux operon was revealed. The investigated variants of P. leiognathi 54 inherited fairly stable morphological characteristics, colony architectonics, level of luminescence, and activity of some enzymes; variants with reduced bioluminescence formed colonies of the S type. Stable bright variants with S- and R-type colonies appeared both in the initial strain population and in the dark variant population, but with smaller frequency. Populations of the bright variant with R-type colonies were most heterogeneous; this can be determined by the lack of glucose repression of the bioluminescence in contrast to other investigated variants of P. leiognathi.     

Biological timing in plants

Plants present unique advantages for the study of circadian rhythms. One is the variety of physiological processes that exhibit circadian rhythmicity. The use of novel luminescent reporters of gene expression and of calcium levels recently provided the first clues as to how the clock orchestrates many different activities in parallel. Signaling cascades for the transduction of light signals are the subject of intensive studies, making plants an unparalleled system for the dissection of phototransduction pathways for the entrainment of the clock to daily light–dark cycles. Finally, mutants with aberrant circadian rhythms have been isolated in the small weedArabidopsis, that may lead to the identification of molecular cogs of the circadian oscillator in plants.     

"Quorum sensing" regulation of lux gene expression and the structure of lux operon in marine bacteria Alivibrio logei

A group of luminescent strains of marine bacteria Alivibrio logei has been isolated (basins of the Okhotsk, White and Bering Seas). Strains A. logei were shown to be psycrophiic bacteria with an optimal growth temperature of approximately 15 degrees C. Biolumiscent characteristics of strains were studied, and the expression of lux genes was shown to be regulated by the "quorum sensing" system. The A. logei lux operon was cloned in Escherichia coli cells and the structure of this operon and its nucleotide sequence were determined. The structure of A. logei lux operon differs markedly from that in the closely related species of luminescent marine bacteria A. fischeri. In the structure of the A. logei lux operon, the the luxI gene is absent in front of luxC, and a fragment containing luxR2-luxI genes is located immediately after luxG gene. Luminescent psycrophiic marine bacteria of A. logei are assumed to be widely distributed in cold waters of northern seas.     

Participation of mobile elements in formation of properties of pathogenic bacteria]

Published reports about structural organization of genes coding for pathogenicity factors are reviewed. Many of such genes are often united into "virulence blocks" or "pathogenicity islands" and are surrounded by mobile genetic elements, promoting their transposition between related bacteria genomes and leading to changes in virulence in the course of evolution. Data on the similarity of nucleotide sequences of virulence genes in different bacteria are presented, despite differences in their localization in the relevant genomes. The role of rRNA genes in dissemination of virulence genes among different bacteria during transduction or conjugation is shown.