Stable-light-emitting Escherichia coli as a biosensor

We have studied possibilities for constructing Escherichia coli strains capable of producing stable light. Light production in E. coli is achieved by cloning the genes encoding bacterial luciferase from Vibrio harveyi. To gain the advantage of sensitive detection of light we transferred the genes under the control of a strong, regulatable promoter system. Stabilization of light produced by E. coli clones was accomplished by finding the optimal plasmid construction and growth conditions as well as suitable measuring buffers. The adjustment of the luciferase synthesis for bioluminescence measurements to a high but not harmful level gives healthy cells and stable luciferase. Cultivation at 30 °C in an uninduced state was found to be the most important factor in getting stable-light production. The overall cell metabolism being unstressed gives us the possibility of monitoring cell physiology and factors affecting it via bioluminescence reactions in vivo. To make the results easy to interpret the light emission has to be stable during a measurement period of one to several hours. In the case of the original light-producing bacteria, Vibrio and Photobacterium strains it has not thus far been possible to find conditions where light emission would be stable for several hours. Based on our findings an automated biosensor system can be developed to monitor the effects of biologically active compounds against stable-light-producing bacteria.     

An Oligonucleotide Primer System for Amplification of the Ribulose-1,5-Bisphosphate Carboxylase/Oxygenase Genes of Bacteria of Various Taxonomic Groups

Based on the analysis of GenBank nucleotide sequences of the cbbL and cbbM genes, coding for the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBPC), the key enzyme of the Calvin cycle, a primer system was designed that allows fragments of these genes about 800 bp long to be PCR-amplified for various photo- and chemotrophic bacteria. The efficiency of the designed primer system in detection of RuBPC genes was demonstrated in PCR with DNA of taxonomically diverse bacteria possessing RuBPC genes with a known primary structure. Nucleotide sequences of RuBPC gene fragments of bacteria belonging to the genera Acidithiobacillus, Ectothiorhodospira, Magnetospirillum, Methylocapsa, Thioalkalispira, Rhodobacter, and Rhodospirillum were determined to be deposited with GenBank and to be translated into amino acid sequences and subjected to phylogenetic analysis.     

The Luminescent Systems of Pony Fishes

The anatomy of bioluminescent organs and mode of light production in 18 species of pony fish have been investigated using fresh and preserved material. The luminescent systems are similarly arranged in all. Basically, the system consists of a light organ located at the distal end of the esophagus, and a series of abdominal accessory structures positioned in tandem for controlling light intensity and for directing and dispersing the light. Light is produced by numerous symbiotic luminous bacteria in the light organ. A simple classification of the luminescent systems is proposed. The light organs of Leiognathus elongatus and L. rivulatus show marked sexual dimorphism. The bacteria present in the light organs of many pony fishes are easily culturable, but not those from L. elongatus. Electron micrographs of the light organs of L. elongatus and L. rivulatus show the presence of numerous rod-shaped bacteria measuring approximately 0.8 µ x 2.4 µ and 0.8 µ x 7.3 µ, respectively. It is concluded that the light organ of L. elongatus contains another example of a type of non-culturable luminous bacteria that have been found elsewhere. Such bacteria appear to require from the host some special factor for growth and luminescence.     

Burkholderia BcpA mediates biofilm formation independently of interbacterial contact‐dependent growth inhibition

Contact‐dependent growth inhibition (CDI) is a phenomenon in which Gram‐negative bacteria use the toxic C‐terminus of a large surface‐exposed exoprotein to inhibit the growth of susceptible bacteria upon cell–cell contact. Little is known about when and where bacteria express the genes encoding CDI system proteins and how these systems contribute to the survival of bacteria in their natural niche. Here we establish that, in addition to mediating interbacterial competition, the Burkholderia thailandensis CDI system exoprotein BcpA is required for biofilm development. We also provide evidence that the catalytic activity of BcpA and extracellular DNA are required for the characteristic biofilm pillars to form. We show using a bcpA–gfp fusion that within the biofilm, expression of the CDI system‐encoding genes is below the limit of detection for the majority of bacteria and only a subset of cells express the genes strongly at any given time. Analysis of a strain constitutively expressing the genes indicates that native expression is critical for biofilm architecture. Although CDI systems have so far only been demonstrated to be involved in interbacterial competition, constitutive production of the system's immunity protein in the entire bacterial population did not alter biofilm formation, indicating a CDI‐independent role for BcpA in this process. We propose, therefore, that bacteria may use CDI proteins in cooperative behaviours, like building biofilm communities, and in competitive behaviours that prevent non‐self bacteria from entering the community.     

Behavior of Some Episomal Elements in a Recombination-Deficient Mutant of Escherichia coli

Conjugal transfer and autonomous replication of some episomes occurred normally in a recombination-deficient (Rec^–) mutant of Escherichia coli K-12. Transduction with phage Plbt of an R factor also occurred normally in this Rec^– mutant, but complete or abortive transduction with Plbt of chromosomal genes did not occur. In contrast, transduction of galactose genes by phage λ_dg occurred in the Rec^– bacteria as frequently as in the Rec⁺ strain. It was shown that phage Plbt does not grow at all on the Rec–bacteria. Recombination between two different R factors, two mutants of phage λ and two mutants of phage T4 occurred normally in the Rec^– bacteria, but did not give a Rec⁺ phenotype to the host bacteria. Colicinogenic factor I made the Rec^– host bacteria more resistant to ultraviolet light but the colicinogenic strain was still infertile in the crosses with the Hfr srains of E. coli K-12.     

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     

Nitrogen-fixing symbiosis between photosynthetic bacteria and legumes

Rhizobia having photosynthetic systems form nitrogen-fixing nodules on the stem and/or root of some species of the legumes Aeschynomene and Lotononis. This review is focused on the recent knowledge about the physiology, genetics and role of the photosystem in these bacteria. Photosynthetic electron transport seems to involve reaction centers, soluble cytochrome c2 and cytochrome bc1. Anaerobically, the electron transport system becomes over-reduced. The photosynthesis genes have been partially characterized; their organization is classical but their regulation is unusual as it is activated by far-red light via a bacteriophytochrome. This original mechanism of regulation seems well adapted to promote photosynthesis during stem symbiosis. Photosynthesis plays a major role in the efficiency of stem nodulation. It is also observed that infrared light stimulates nitrogen fixation in nodules containing photosynthetic bacteroids, suggesting that photosynthesis may additionally provides energy for nitrogen fixation, allowing for more efficient plant growth. Other aspects of these bacteria are discussed, in particular their taxonomic position and nodulation ability, the role of carotenoids and the potential for application of photosynthetic rhizobia in rice culture. This revised version was published online in June 2006 with corrections to the Cover Date.     

The Pho Regulons of Bacteria

Bacterial Pho regulons contain genes whose products are involved in the transport and assimilation of inorganic phosphate. The expression of these genes is regulated by a specific two-component signal transduction system. The paper summarizes data on the organization and function of Pho regulons in gram-negative and gram-positive bacteria, with particular emphasis on the Pho regulons of the best studied bacteria Escherichia coli and Bacillus subtilis.     

LOV‐domain photoreceptor,encoded in a genomic island,attenuates the virulence of Pseudomonas syringae in light‐exposed Arabidopsis leaves

In Arabidopsis thaliana, light signals modulate the defences against bacteria. Here we show that light perceived by the LOV domain‐regulated two‐component system (Pst–Lov) of Pseudomonas syringae pv. tomato DC3000 (Pst DC3000) modulates virulence against A. thaliana. Bioinformatic analysis and the existence of an episomal circular intermediate indicate that the locus encoding Pst–Lov is present in an active genomic island acquired by horizontal transfer. Strains mutated at Pst–Lov showed enhanced growth on minimal medium and in leaves of A. thaliana exposed to light, but not in leaves incubated in darkness or buried in the soil. Pst–Lov repressed the expression of principal and alternative sigma factor genes and their downstream targets linked to bacterial growth, virulence and quorum sensing, in a strictly light‐dependent manner. We propose that the function of Pst–Lov is to distinguish between soil (dark) and leaf (light) environments, attenuating the damage caused to host tissues while releasing growth out of the host. Therefore, in addition to its direct actions via photosynthesis and plant sensory receptors, light may affect plants indirectly via the sensory receptors of bacterial pathogens.     

革兰氏阴性菌亚铁离子转运系统的组成及作用机制

几乎所有细菌的生长都离不开铁元素。在有氧的环境中,三价铁离子几乎无法被细菌直接利用。但是在宿主胃肠道中,铁元素主要以可溶性的亚铁离子形式存在,它们可通过革兰氏阴性菌外膜直接进入胞周质,在周质通过亚铁离子转运系统,将铁离子转运至胞浆供细菌利用。绝大多数阴性菌主要是通过Feo转运系统利用亚铁离子,大肠杆菌的Feo转运系统由feoA、feoB和feoC3个基因组成。除Feo转运系统外,还发现Yfe转运系统、Efe转运系统、Sit转运系统等。本文重点介绍革兰氏阴性菌Feo转运系统的组成及作用机制,以期为进一步研究细菌亚铁离子的转运机制提供参考。     

Phylogenetic analysis of photosynthetic genes of Rhodocyclus gelatinosus: Possibility of horizontal gene transfer in purple bacteria

Nucleotide sequences of the genes coding for the M and cytochrome subunits of the photosynthetic reaction center of Rhodocyclus gelatinosus, a purple bacterium in the subdivision, were determined. The deduced amino acid sequences of these proteins were compared with those of other photosynthetic bacteria. Based on the homology of these two photosynthetic proteins, Rc. gelatinosus was placed in the subdivision of purple bacteria, which disagrees with the phylogenetic trees based on 16S rRNA and soluble cytochrome c ₂. Horizontal transfer of the genes which code for the photosynthetic apparatus in purple bacteria can be postulated if the phylogenetic trees based on 16S rRNA and soluble cytochrome c ₂ reflect the real history of purple bacteria.Abbreviations LH I light harvesting complex I - RC reaction center     

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.     

Plasmid Transfer Detection in Soil using the Inducible lPR System Fused to Eukaryotic Luciferase Genes

We report a model system for plasmid transfer analysis using the regulated lambda phage right promoter, λPr, fused to luc and lucOR as repoter genes. We have demonstrated that the systems cI857-λPr::luc and cI857-λPr::lucOR are temperature-inducible in Escherichia coli but not in other Gram-negative bacteria analyzed, enabling detection of luminescence when plasmids were mobilized from E. coli to those Gram-negative backgrounds. Using light for the detection, we have observed plasmid transfer from E. coli harboring RK2 and R388 derived plasmids to Pseudomonas putida KT2440 (co-introduced with donors) and to indigenous microorganisms, in vitro and in nonsterile soil microcosms. The importance of nutrients for an efficient plasmid transfer in nonsterile soil microcosms has been confirmed. When plasmid transfer experiments were carried out into nonsterile soil microcosms, significant populations of indigenous transconjugants arose. This system provides efficient marker genes and avoids the use of antibiotics for the selection of transconjugants.     

Genome-wide analysis of the chalcone synthase superfamily genes of <Emphasis Type="Italic">Physcomitrella patens</Emphasis>

Enzymes of the chalcone synthase (CHS) superfamily catalyze the production of a variety of secondary metabolites in bacteria, fungi and plants. Some of these metabolites have played important roles during the early evolution of land plants by providing protection from various environmental assaults including UV irradiation. The genome of the moss, Physcomitrella patens, contains at least 17 putative CHS superfamily genes. Three of these genes (PpCHS2b, PpCHS3 and PpCHS5) exist in multiple copies and all have corresponding ESTs. PpCHS11 and probably also PpCHS9 encode non-CHS enzymes, while PpCHS10 appears to be an ortholog of plant genes encoding anther-specific CHS-like enzymes. It was inferred from the genomic locations of genes comprising it that the moss CHS superfamily expanded through tandem and segmental duplication events. Inferred exon–intron architectures and results from phylogenetic analysis of representative CHS superfamily genes of P. patens and other plants showed that intron gain and loss occurred several times during evolution of this gene superfamily. A high proportion of P. patens CHS genes (7 of 14 genes for which the full sequence is known and probably 3 additional genes) are intronless, prompting speculation that CHS gene duplication via retrotransposition has occurred at least twice in the moss lineage. Analyses of sequence similarities, catalytic motifs and EST data indicated that a surprisingly large number (as many as 13) of the moss CHS superfamily genes probably encode active CHS. EST distribution data and different light responsiveness observed with selected genes provide evidence for their differential regulation. Observed diversity within the moss CHS superfamily and amenability to gene manipulation make Physcomitrella a highly suitable model system for studying expansion and functional diversification of the plant CHS superfamily of genes.