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.     

Expression of bioluminescence by Escherichia coli containing recombinant Vibrio harveyi DNA.

When isogenic strains of Escherichia coli, RR1 (rec+) and HB101 (recA), were transformed with mapped recombinant plasmids known to contain Vibrio harveyi luciferase genes and large regions of DNA flanking on both sides, a small percentage (0.005%) of the colonies expressed high levels of luminescence (up to 10(12) quanta s-1 ml-1) in the absence of added aldehyde. The altered ability to express light was found to be due to a mutation in the host and not to an alteration in the recombinant DNA. When these bright colonies were cured of plasmid, they could be retransformed with cloned V. harveyi gene fragments in cis and in trans to yield luminescent colonies at 100% frequency. The maximum length of V. harveyi DNA required to produce light-emitting E. coli was shorter (6.3 kilobase pairs) than that required for expression of the V. fischeri system in E. coli. Cell extracts from bright clones contained wild-type levels of activity for the heteropolymeric (alpha beta) luciferase; fatty acid labeling revealed the presence of the three acylated polypeptides of the fatty acid reductase system which is involved in aldehyde biosynthesis for the luminescence reaction. The increased light emission in the mutant bacteria appeared to arise in part from production of higher levels of polycistronic mRNAs coding for luciferase.     

Study on the relationship of protease production and luminescence in Vibrio harveyi

AIMS: To demonstrate that Vibrio harveyi produces various types of toxins and how the production of those toxins is related with luminescence. METHODS AND RESULTS: Luminescence and toxicity of eight V. harveyi were evaluated. We demonstrated that all V. harveyi emitting luminescence were isolated from marine organisms and also showed that they were highly pathogenic when compared with culture collection V. harveyi based on cytotoxic assay test. On the contrary, V. harveyi isolated from shrimp farm showed no luminescence but showed high pathogenicity based on toxicity test. The effect of protease inhibitors on pathogenicity and luminescence was also investigated. We demonstrated that light emission of pathogenic V. harveyi remarkably decreased after addition of protease inhibitor. Furthermore, extracellular proteins from cell-free culture supernatant of luminescent and nonluminescent V. harveyi were compared using SDS-PAGE analysis. Results showed that there were differences in molecular weight and amount of proteins. CONCLUSIONS: Vibrio harveyi parasiting marine organisms have both luminescence and pathogenicity. Based on this study, luminescence and protease toxin activity in V. harveyi are related. Moreover, this paper clarified that V. harveyi produces various types of toxins. SIGNIFICANCE AND IMPACT OF THE STUDY: The current study demonstrated that V. harveyi produces two kinds of toxins, haemolysin and protease toxin. It may be clear roots of V. harveyi toxin.     

Reversible inhibition of bacterial bioluminescence by long-chain fatty acids

Long-chain unsaturated fatty acids, as well as certain saturated fatty acids such as lauric acid, are inhibitors of the in vivo luminescence of wild-type strains of four species of luminous bacteria (Beneckea harveyi, Photobacterium phosphoerum, P. fischeri, andP. leiognathi) as well as the myristic acid-stimulated luminescence in the aldehyde dim mutant M17 ofB. harveyi. Based on studies with the system in vivo, the principal site of action of all the fatty acids appears to be the reductase activity that converts myristic acid to myristyl aldehyde. This was confirmed by in vitro studies: Reductase activity in crude cell-free extracts is strongly inhibited by oleic acid.     

Biosynthesis and stereochemistry of the autoinducer controlling luminescence in Vibrio harveyi.

Knowledge of the pathway for synthesis of the autoinducer, N-(beta-hydroxybutyryl)-homoserine lactone (HBHL), controlling luminescence in Vibrio harveyi can provide important information concerning the relationship between the nutrition and physiology of the bacteria and the phenomenon of light emission. In this study, the D and L isomers of the autoinducer containing the stereoisomers of beta-hydroxybutyric acid were synthesized and characterized by proton nuclear magnetic resonance in the presence of a chiral shift reagent, a europium(III) derivative of Tris[3-(heptafluoropropyl-hydroxymethylene)-(+)-camphorato]. By using a newly isolated autoinducer mutant which responds to low physiological concentrations of the autoinducer, it could be shown that autoinducer activity was associated with D-HBHL and not L-HBHL. Blockage of fatty acid biosynthesis by the addition of fatty acids and/or the antibiotic cerulenin to the cells prevented synthesis of the autoinducer as measured by the loss of autoinducer activity and a decrease in the incorporation of labelled acetate into the partially purified autoinducer. These results indicate that fatty acid biosynthesis is necessary for light emission in luminescent bacteria because it controls formation of the lux autoinducer.     

The effect of copper concentration on the virulence of pathogenic Vibrio harveyi

AIM: To demonstrate the influence of copper on luminescence and toxin production in Vibrio harveyi. METHODS AND RESULTS: The effect of copper concentration on the expression of both luminescence and toxin of V. harveyi was investigated. Copper concentration of less than 40 ppm had no effect on the growth. While V. harveyi cultured with 40 ppm copper concentration showed decreased luminescence as measured by spectrofluorophotometer and as observed. LuxD gene, which is related to luminescence expression, was monitored using real-time RT-PCR. Result showed that the concentration of cDNA coding for luxD was lower in V. harveyi with copper. Toxic activity against both HeLa cells and shrimp haemocytes was also lower in the culture supernatant of V. harveyi grown with 40 ppm copper concentration. Moreover, V. harveyi extracellular proteins were analysed using SDS-PAGE. Results showed that culture supernatant from V. harveyi grown without copper had thicker band indicating a higher concentration of the putative cysteine protease, one of the major toxin of V. harveyi. CONCLUSIONS: This study proved that both luminescence and toxin were repressed by copper. SIGNIFICANCE AND IMPACT OF THE STUDY: The current study demonstrated that copper inhibited expression of phenotype of V. harveyi. Furthermore, it may inhibit quorum sensing of V. harveyi.     

Purification and structural identification of an autoinducer for the luminescence system of Vibrio harveyi

An autoinducer required for the growth-dependent development of luminescence in Vibrio harveyi has been purified, structurally identified, and chemically synthesized. The autoinducer, which is excreted by the cells, was extracted with chloroform from conditioned media in which V. harveyi cells had been grown. The concentrated extract was separated on a silica gel column and the autoinducer activity further purified by thin layer, paper, and high performance liquid chromatography. The structure of the partially purified autoinducer was identified by 1H NMR and mass spectrometry as N-(beta-hydroxybutyryl)homoserine lactone. This compound was chemically synthesized by condensation of beta-hydroxybutyrate with alpha-amino-gamma-butyrolactone hydrobromide using 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide as a carboxyl group activator. The pure synthetic autoinducer gave the characteristic NMR and mass spectra, co-migrated with the natural autoinducer on thin layer plates, and specifically stimulated induction of luminescence of V. harveyi. Light emission of a regulatory dark mutant of V. harveyi could be stimulated over 1000-fold by the addition of N-(beta-hydroxybutyryl)homoserine lactone, reaching intensities comparable to that of the native strain. The similarity in structure of the autoinducer of V. harveyi to that of Vibrio fischeri suggests that the regulation of luminescence induction in these bacteria may be related in spite of their differences in lux gene organization.     

Experimental bacteriophage-mediated virulence in strains of Vibrio harveyi

Vibriosis is a major disease problem in prawn aquaculture. Until now there has been no clear explanation why some strains of Vibrio are pathogenic, while others are not. This study demonstrated that the presence of the bacteriophage V. harveyi myovirus like (VHML) may confer virulence to V. harveyi Strain 642. This was demonstrated by infecting na?ve avirulent V. harveyi Strains 12, 20, 45 and 645 with the bacteriophage and converting them into virulent strains. The previously na?ve strains of Vibrio infected with Bacteriophage VHML from V. harveyi Strain 642 demonstrated up-regulation of haemolysin, up-regulation of protein excretion, additional proteins which were recognised as toxic proteins from Strain 642 by monoclonal antibodies specific to the exotoxin sub-units, and a significant increase in mortality of larval Penaeus monodon. It was concluded that Bacteriophage VHML conferred virulence to V. harveyi Strains 12, 20, 45 and 645 and that Bacteriophage VHML either fully or partly confers virulence in V. harveyi Strain 642.     

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.     

Transcriptional regulation of lux genes transferred into Vibrio harveyi

Past work has shown that transformed Escherichia coli is not a suitable vehicle for studying the expression and regulation of the cloned luminescence (lux) genes of Vibrio harveyi. Therefore, we have used a conjugative system to transfer lux genes cloned into E. coli back into V. harveyi, where they can be studied in the parental organism. To do this, lux DNA was inserted into a broad-spectrum vector, pKT230, cloned in E. coli, and then mobilized into V. harveyi by mating aided by the conjugative plasmid pRK2013, also contained in E. coli. Transfer of the wild-type luxD gene into the V. harveyi M17 mutant by this means resulted in complementation of the luxD mutation and full restoration of luminescence in the mutant; expression of transferase activity was induced if DNA upstream of luxC preceded the luxD gene on the plasmid, indicating the presence of a strong inducible promoter. To extend the usefulness of the transfer system, the gene for chloramphenicol acetyltransferase was inserted into the pKT230 vector as a reporter. The promoter upstream of luxC was verified to be cell density regulated and, in addition, glucose repressible. It is suggested that this promoter may be the primary autoregulated promoter of the V. harveyi luminescence system. Strong termination signals on both DNA strands were recognized and are located downstream from luxE at a point complementary to the longest mRNA from the lux operon. Structural lux genes transferred back into V. harveyi under control of the luxC promoter are expressed at very high levels in V. harveyi as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis: the gene transfer system is thus useful for expression of proteins as well as for studying the regulation of lux genes in their native environment.     

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.     

Genetically modified Vibrio harveyi strains as potential bioindicators of mutagenic pollution of marine environments

For biodetection of mutagenic pollution of marine environments, an organism naturally occurring in these habitats should be used. We found that marine bacterium Vibrio harveyi may be an appropriate bioindicator of mutagenic pollution. For positive selection of mutants, we developed a simple method for isolation of V. harveyi mutants resistant to neomycin. We constructed genetically modified V. harveyi strains that produce significantly more neomycin-resistant mutants upon treatment with low concentrations of mutagens than the wild-type counterpart. The sensitivity of the mutagenicity test with the V. harveyi strains is at least comparable to (if not higher than) that of the commonly used Ames test, which uses Salmonella enterica serovar Typhimurium strains. Therefore, we consider that the V. harveyi strains described in this report could be used as potential bioindicators of mutagenic pollution of marine environments.     

Construction and detection of bioluminescent strains of Bacillus subtilis

Bioluminescence ( lux ) genes from Vibrio fischeri and V. harveyi were introduced into Bacillus subtilis on a plasmid vector and by chromosomal integration. The plasmid-bearing strain was highly luminescent and stable under antibiotic selection, but luminescence was lost in the absence of selection and following sporulation and germination. The chromosomally marked strains emitted less light but were found to be stable without the requirement for antibiotic selection and following sporulation and germination. Individual luminescing colonies of both B. subtilis strains could be detected against a high background of non-bioluminescent indigenous soil microbial colonies on agar plates using a charge-coupled device camera. These bioluminescent Gram-positive strains could be of value in studies concerning the survival and spread of genetically-modified micro-organisms in soil environments.     

A Persistent Daily Rhythm in Photosynthesis

The luminescent marine dinoflagellate, Gonyaulax polyedra, exhibits a diurnal rhythm in the rate of photosynthesis and photosynthetic capacity measured by incorporation of C¹⁴O₂, at different times of day. With cultures grown on alternating light and dark periods of 12 hours each, the maximum rate is at the 8th hour of the light period. Cultures transferred from day-night conditions to continuous dim light continue to show the rhythm of photosynthetic capacity (activity measured in bright light) but not of photosynthesis (activity measured in existing dim light). Cultures transferred to continuous bright light, however, do not show any rhythm. Several other properties of the photosynthetic rhythm are similar to those of previously reported rhythms of luminescence and cell division. This similarity suggests that a single mechanism regulates the various rhythms.     

Induction of light emission by luminescent bacteria treated with UV light and chemical mutagens

Intensity of light emission by luminescent bacteria in response to UV irradiation and chemical mutagens was tested. We demonstrated that luminescence of six strains of marine bacteria (belonging to four species: Photobacterium leiognathi, P. phosphoreum, Vibrio fischeri and V. harveyi) is significantly increased by UV irradiation relatively shortly after dilution of cultures. Such a stimulation of luminescence was abolished in cells treated with chloramphenicol 15 min before UV irradiation, indicating that effective gene expression is necessary for UV-mediated induction of light emission. These results suggest that stimulation of luminescence in UV-irradiated bacterial cells may operate independently of the quorum sensing regulation. A significant induction of luminescence was also observed upon treatment of diluted cultures of all investigated strains with chemical mutagens: sodium azide (SA), 2-methoxy-6-chloro-9-(3-(2-chloroethyl)aminopropylamino)acridine x 2HCl (ICR-191), 4-nitro-o-phenylenediamine (NPD), 4-nitroquinolone-N-oxide (NQNO), 2-aminofluorene (2-AF), and benzo[alpha]pyrene. These results support the proposal that genes involved in bioluminescence belong to the SOS regulon. The use of bacterial luminescence systems in assays for detection of mutagenic compounds is discussed in the light of this proposal.