The effects of the regulatory proteins RcsA and RcsB on the expression of the Vibrio fischeri lux operon in Escherichia coli

A study was made of the effect of RcsA and RcsB on the Vibrio fischeri lux expression in Escherichia coli. RcsA suppressed the LuxR activity and thereby inhibited expression of the lux genes coding for luciferase and reductase. In osmotic shock, RcsA-RcsB activated lux expression and, consequently, bioluminescence of E. coli cells in the early log phase.     

Osmotic Shock Induction of the Expression of Vibrio fischeri lux Genes in Escherichia coli Cells

The effect of osmotic shock on the expression of genes in the lux regulon of marine bacteria Vibrio fischeri was studied in cells ofEscherichia coli. Bioluminescence of cells was shown to drastically increase, when cells were exposed to osmotic shock at the early logarithmic growth phase, at far lower optic densities as compared to the critical optic density characteristic. The expression of lux genes induced by osmotic shock is determined by the two-component regulatory system RcsC–RcsB. A nucleotide sequence in the regulatory region of the luxR gene homologous to the RcsB-box consensus of E. coli is assumed to be a primary site for this system.     

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.     

Inorganic polyphosphate and polyphosphate kinase: their novel biological functions and applications

In this review, we discuss the following two subjects: 1) the physiological function of polyphosphate (poly(P)) as a regulatory factor for gene expression in Escherichia coli, and 2) novel functions of E. coli polyphosphate kinase (PPK) and their applications. With regard to the first subject, it has been shown that E. coli cells in which yeast exopolyphosphatase (poly(P)ase), PPX1, was overproduced reduced resistance to H2O2 and heat shock as did a mutant whose polyphosphate kinase gene is disrupted. Sensitivity to H2O2 and heat shock evinced by cells that overproduce PPX1 is attributed to depressed levels of rpoS expression. Since rpoS is a central element in a regulatory network that governs the expression of stationary-phase-induced genes, poly(P) affects the expression of many genes through controlling rpoS expression. Furthermore, poly(P) is also involved in expression of other stress-inducible genes that are not directly regulated by rpoS. The second subject includes the application of novel functions of PPK for nucleoside triphosphate (NTP) regeneration. Recently E. coli PPK has been found to catalyze the kination of not only ADP but also other nucleoside diphosphates using poly(P) as a phospho-donor, yielding NTPs. This nucleoside diphosphate kinase-like activity of PPK was confirmed to be available for NTP regeneration essential for enzymatic oligosaccharide synthesis using the sugar nucleotide cycling method. PPK has also been found to express a poly(P):AMP phosphotransferase activity by coupling with adenylate kinase (ADK) in E. coli. The ATP-regeneration system consisting of ADK, PPK, and poly(P) was shown to be promising for practical utilization of poly(P) as ATP substitute.     

"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.     

Cloning and nucleotide sequence of luxR, a regulatory gene controlling bioluminescence in Vibrio harveyi.

Mutagenesis with transposon mini-Mulac was used previously to identify a regulatory locus necessary for expression of bioluminescence genes, lux, in Vibrio harveyi (M. Martin, R. Showalter, and M. Silverman, J. Bacteriol. 171:2406-2414, 1989). Mutants with transposon insertions in this regulatory locus were used to construct a hybridization probe which was used in this study to detect recombinants in a cosmid library containing the homologous DNA. Recombinant cosmids with this DNA stimulated expression of the genes encoding enzymes for luminescence, i.e., the luxCDABE operon, which were positioned in trans on a compatible replicon in Escherichia coli. Transposon mutagenesis and analysis of the DNA sequence of the cloned DNA indicated that regulatory function resided in a single gene of about 0.6-kilobases named luxR. Expression of bioluminescence in V. harveyi and in the fish light-organ symbiont Vibrio fischeri is controlled by density-sensing mechanisms involving the accumulation of small signal molecules called autoinducers, but similarity of the two luminescence systems at the molecular level was not apparent in this study. The amino acid sequence of the LuxR product of V. harveyi, which indicates a structural relationship to some DNA-binding proteins, is not similar to the sequence of the protein that regulates expression of luminescence in V. fischeri. In addition, reconstitution of autoinducer-controlled luminescence in recombinant E. coli, already achieved with lux genes cloned from V. fischeri, was not accomplished with the isolation of luxR from V. harveyi, suggesting a requirement for an additional regulatory component.     

Cloning and expression of the Photobacterium phosphoreum luminescence system demonstrates a unique lux gene organization

The organization of the lux structural genes (A-E) in Photobacterium phosphoreum has been determined and a new gene designated as luxF discovered. The P. phosphoreum luminescence system was cloned into Escherichia coli using a pBR322 vector and identified by cross-hybridization with Vibrio fischeri lux DNA. The lux genes were located by specific expression of P. phosphoreum DNA fragments in the T7-phage polymerase/promoter system in E. coli and identification of the labeled polypeptide products. The luxA and luxB gene products (luciferase subunits) were shown to catalyze light emission in the presence of FMNH2, O2, and aldehyde. The luxC, luxD, and luxE gene products (fatty acid reductase subunits) responsible for aldehyde biosynthesis could be specifically acylated with 3H-labeled fatty acids. The order of the lux genes in P. phosphoreum was found to be luxCDABFE with luxF coding for a new polypeptide of 26 kDa. The presence of a new gene in the P. phosphoreum luminescence system between luxB and luxE as compared to the organization of the lux structural gene in V. fischeri and Vibrio harveyi (luxCDABE) demonstrates that the luminescent systems in the marine bacteria have significantly diverged. The discovery of the luxF gene provides the basis for elucidating the role of its gene product in the expression of luminescence in different marine bacteria.     

Expression of genes for guanyl-specific ribonucleases in Bacillus intermedius and Bacillus pumilus is regulated by the PhoP-PhoR two-component signal transduction system of PHO regulon of Bacillus subtilis]

Promoters of the genes of guanyl-specific ribonucleases of Bacillus intermedius (binase) and Bacillus pumilus (RNase Bp) were found to contain sequences homologous to those recognizable by the regulatory protein PhoP in the promoters of the PHO regulon of B. subtilis, as well as regions partially homologous to the binding sites of another regulatory protein, PhoB, in the promoters of the PHO regulon of Escherichia coli. The role of the two-component regulatory systems PhoP-PhoR and PhoB-PhoR in the regulation of expression of the genes of binase and RNase Bp in recombinant strains of B. subtilis and E. coli was studied by using mutant strains. It was established that the expression of these genes in recombinant B. subtilis cells is stringently controlled by the PhoP-PhoR two-component regulatory system, whereas the expression of these genes in E. coli cells is not controlled by the regulatory proteins PhoB or PhoR. Presumably, regulatory systems of the response to phosphate starvation, analogous to the PHO regulon of B. subtilis, also function in other representatives of the genus Bacillus.     

Isolation of the lux genes from Photobacterium leiognathi and expression in Escherichia coli

Genes necessary for luminescence (lux genes) in the marine bacterium Photobacterium leiognathi, strain PL721, were isolated and expressed in Escherichia coli. A 15-kb fragment obtained from a partial digestion of PL721 DNA with HindIII was cloned into the plasmid pACYC184, resulting in the hybrid plasmid pSD721. When pSD721 was transformed into E. coli ED8654, the resulting transformants were luminous with no additions to the cells, indicating that it contained the structural genes coding for the alpha and beta subunits of luciferase (luxA and luxB), and for components involved in aldehyde biosynthesis. Hybridization analysis with luxA and luxB 32P probes confirmed the location of these two genes on the 15-kb insert. When pSD721 was transformed into four different strains of E. coli, luminescence expression varied widely in amount and in pattern. In some strains, luminescence developed like an autoinducible system, and at maximum induction was very bright, even with no addition of aldehyde, while in others, luminescence was 100-fold less, and no induction was seen. In no case was luminescence affected by shifts in temperature, osmolarity, or iron concentration. These results indicate that, while the complete lux regulon is apparently contained on the 15-kb cloned fragment, the regulation of the lux regulon in pSD721 is subject to host controls by E. coli, controls which vary widely among different E. coli strains.     

The role of antioxidant enzymes in response of Escherichia coli to osmotic upshift

Aerobic growth of Escherichia coli sodAsodB and katE mutants lacking cytosolic superoxide dismutases and catalase hydroperoxidase II was inhibited by osmotic upshift to a greater extent than of their wild-type parent strains. The fur mutation leading to an intracellular overload of iron also increased sensitivity of growing E. coli cells to osmotic upshift. Using lacZ fusions, it was shown that expression of antioxidant genes soxS and katE was stimulated by an increase in osmolarity. These data suggest that in aerobically growing E. coli cells, moderate osmotic upshift causes activation of certain antioxidant systems.     

Osmoadaptation of Mammalian cells - an orchestrated network of protective genes

In mammals, the cells of the renal medulla are physiologically exposed to interstitial osmolalities several-fold higher that found in any other tissue. Nevertheless, these cells not only have the ability to survive in this harsh environment, but also to function normally, which is critical for maintenance of systemic electrolyte and fluid homeostasis. Over the last two decades, a substantial body of evidence has accumulated, indicating that sequential and well orchestrated genomic responses are required to provide tolerance to osmotic stress. This includes the enhanced expression and action of immediate-early genes, growth arrest and DNA damage inducible genes (GADDs), genes involved in cell cycle control and apoptosis, heat shock proteins, and ultimately that of genes involved in the intracellular accumulation of nonperturbing organic osmolytes. The present review summarizes the sequence of genomic responses conferring resistance against osmotic stress. In addition, the regulatory mechanisms mediating the coordinated genomic response to osmotic stress will be highlighted.     

Rapid and sensitive pollutant detection by induction of heat shock gene-bioluminescence gene fusions.

Heat shock gene expression is induced by a variety of environmental stresses, including the presence of many chemicals. To address the utility of this response for pollutant detection, two Escherichia coli heat shock promoters, dnaK and grpE, were fused to the lux genes of Vibrio fischeri. Metals, solvents, crop protection chemicals, and other organic molecules rapidly induced light production from E. coli strains containing these plasmid-borne fusions. Introduction of an outer membrane mutation, tolC, enhanced detection of a hydrophobic molecule, pentachlorophenol. The maximal response to pentachlorophenol in the tolC+ strain was at 38 ppm, while the maximal response in an otherwise isogenic tolC mutant was at 1.2 ppm. Stress responses were observed in both batch and chemostat cultures. It is suggested that biosensors constructed in this manner may have potential for environmental monitoring.     

Analysis of reading frame and expressional regulation of randomly selected promoter-proximal genes in Escherichia coli

The expression of seventy-seven randomly cloned genes of Escherichia coli was examined following a variety of treatments including heat shock, glucose starvation, phosphate starvation, ammonium starvation or osmotic shock, with the aid of lacZ reporter gene protein fusions on multicopy plasmids. Two of 77 genes (amr and yigL) had not previously been identified as protein encoding open-reading frames (ORFs) in annotations of the E. coli genome database. Thirteen genes exhibited significant changes in expression in response to at least one of the treatments, and six of them appeared to be controlled by more than one sigma (sigma) factor of RNA polymerase. This study thus allows us not only to identify the reading frame of the genomic genes but also to support the hypothesis earlier proposed that a significant proportion of genes in E. coli are involved in adaptations to various stresses to which the organism is likely to be exposed in the environment.