[Quorum sensing systems of regulation, synthesis of phenazine antibiotics, and antifungal (corrected) activity in rhizospheric bacterium Pseudomonas chlororaphis 449].

Strain Pseudomonas chlororaphis 449, an antagonist of a broad spectrum of phytopathogenic microorganisms isolated from the maize rhizosphere, was shown to produce three phenazine antibiotics: phenazine-1-carboxylic acid (PCA), 2-hydroxylphenazine-1-carboxylic acid (2-OH-PCA), and 2-hydroxylphenazine (2-OH-PHZ). Two Quorum Sensing (QS) systems of regulation were identified: PhzIR and CsaI/R. Genes phzI and csaI were cloned and sequenced. Cells of strain 449 synthesize at least three types of AHL: N-butanoyl-L-homoserine lactone (C4-AHL), N-hexanoyl-L-homoserine lactone (C6-AHL), and N-(3-oxo-hexanoyl)-L-homoserine lactone (30C6-AHL). Transposon mutagenesis was used to generate mutants of strain 449 deficient in synthesis of phenazines, which carried inactivated phzA and phzB genes of the phenazine operon and gene phzO. Mutations phzA- and phzB-caused a drastic reduction in the antagonistic activity of bacteria toward phytopathogenic fungi. Both mutants lost the ability to protect cucumber and leguminous plants against phytopathogenic fungi Rhizoctonia solani and Sclerotinia sclerotiorum. These results suggest a significant role of phenazines in the antagonistic activity of P. chlororaphis 449.

[Quorum-sensing regulation in soil pseudomonads].

228 strains of soil and rhizosphere pseudomonads isolated in different geographic zones were screened, with the use of two tester systems, for the capacity to produce N-acetyl-homoserine lactones (AHLs), which are autoinducers involved in quorum-sensing (QS) regulation. AHL production was found in 11.4% of the strains investigated. In five Pseudomonas chlororaphis strains shown to be active AHL producers and chosen for further study, PCR identified two QS systems that involved the phzI, phzR, csaI, and csaR genes; this finding suggests the conservative nature of these regulation systems in P. chlororaphis. Strain P. chlororaphis 449, chosen as a model object and studied in greater detail, produced three AHL species including N-butanoyl-homoserine lactone and N-hexanoyl-homoserine lactone. This strain produced three types of phenazine antibiotics, as well as siderophores and cyanide; it also exhibited antagonistic properties toward a wide spectrum of phytopathogenic fungi. The phzI and csaI genes, coding for synthases of AHLs of two types, were cloned and sequenced; mutants with knocked-out phzI and csal genes were obtained. With the use of transposon mutagenesis and the gene substitution method, mutations were obtained in the global expression regulator genes gacS, coding for the GacA-GacS regulation system kinase, and rpoS, coding for the sigma S subunit of RNA polymerase. The effect of these mutations on the AHL synthesis and on the regulation of various metabolic processes in P. chlororaphis was studied.

[Quorum sensing of genes expression--perspective drug target against bacterial pathogenicity].

Bacteria are capable to sense an increase of cell density population and to reply quickly and coordinately by the induction of special sets of genes. This type of the regulation was named Quorum Sensing (QS); it is based on the effect of low-molecular-weight signaling molecules of different nature (autoinducers) which accumulate in the culture at high density of bacterial population and interact with receptor regulatory proteins. QS systems are the global regulators of bacterial genes expression and play a key role in the control of many metabolic processes in cell including the regulation of virulence of bacteria. Here we review the molecular mechanisms of QS systems functioning in bacteria belonging to different taxonomic groups and discuss the potential of QS regulation as a new drug target for the treatment of bacterial infections. At present this approach is accounted as a new alternative strategy of antimicrobial therapy directed on the development of drugs inhibiting QS regulation and active just against pathogenicity of bacteria (antipathogenic drugs). Such a strategy allows to avoid a wide dissemination of resistant forms of pathogenic bacteria and the formation of biofilms increasing in many times the resistance of bacteria to drug preparations.

[Activation of the expression of the microcin C51 operon upon glucose starvation of cells at the exponential growth phase].

It was earlier shown that expression of the microcin C51 operon in Escherichia coli cells is activated upon decelerated growth of cells during their transition to the stationary growth phase and depends on the sigmaS subunit of RNA polymerase. Using a single-copy construct containing the cloned promoter region of the microcin C51 operon and a promoterless lac operon (P(mcc)-lac), it was shown that the promoter of the microcin operon was also induced by stress caused by the transition of cells at the exponential growth phase into the medium without glucose as a sole carbon source. Activation of P(mcc)-lac expression upon severe glucose starvation occurred in rpoS+ and rpoS- strains. In cells carrying the rpoD800 mutation that renders the sigma70 subunit of RNA polymerase temperature-sensitive, an activation of P(mcc)-lac expression was observed at nonpermissive temperature, in contrast to its complete inhibition in E. coli cells at the phase of delayed growth. Other stressors-nitrogen starvation, high temperatures, osmotic shock, tetracycline and chloramphenicol-did not activate P(mcc)-lac expression in cells at the exponential growth phase.

[Involvement of sigma S and sigma 70 subunits of RNA polymerase and the CRP protein in the regulation of microcin C51 operon expression]. / Uchastie sigmy S, sigmy 70 sub''edinits RNK-polimerazy i belka CRP v reguliatsii ékspressii operona mikrotsina C51.

Expression of the microcin C51 operon in Escherichia coli cells is activated during cell entry into the stationary growth phase and depends on the sigmaS subunit of RNA polymerase (RpoS). The null rpoS mutations retained the residual expression level of the transcriptional P(mcc)-lac fusion, which indicates that other sigma subunit can participate in the regulation of transcription of the microcin C51 operon. Data presented in this work show that the overproduction of sigma70 in rpoS- cells diminished the level of P(mcc)-lac expression, as in wild-type cells, which seems to be the consequence of competition between sigma factors for a limited number of core RNA polymerase molecules. In the presence of the rpoD800 mutation that renders sigma70 temperature-sensitive, expression of P(mcc)-lac was not induced in the phase of delayed culture growth at nonpermissive temperature, which indicates that sigma70 is indispensable for microcin operon expression. Point substitutions in the -10 P(mcc) region, leading to the formation of 5'-TGaTATAAT-3' site, enhanced promoter activity but did not affect the relationship between P(mcc)-lac transcription and growth phase, sigmaS, and the activator protein CRP. The activator protein CRP was shown to bind a DNA fragment containing the TGTGA(AATGAA)TCTAT site in the -59.5 bp position relative to the start site of transcription. Mutation in the ssrI gene encoding 6S RNA did not disturb P9mcc)-lac expression; these results indicate that 6S RNA does not participate in the regulation of microcin C51 operon expression.

[Synthesis of signaling N-acyl-homoserine-lactones participating in quorum sensing in rhizosphere and soil bacteria Pseudomonas and Xanthomonas]. / Sintez signal'nykh N-atsil-gomoserin-laktonov, uchastvuiushchikh v mezhkletochnom obmene informatsiei, u rizosfernykh i pochvennykh bakterii Pseudomonas i Xanthomonas.

Signaling molecules assigned to N-acyl-homoserine-lactones (AHL) serve as autoinducers for the genes controlling the quorum sensing regulatory system. In many gram-negative bacteria, AHL are the key factors responsible for density-dependent regulation of exoenzyme and secondary metabolite production; they also participate in interaction between bacteria and higher organisms. The soil and rhisosphere bacteria Pseudomonas and Xanthomonas from different geographical zones of Russia and the former USSR were analyzed for the presence of the AHL producers. Screening was conducted by using a test system based on the mutant strain Chromobacterium violaceum, which was unable to synthesize AHL but produced a pigment violacein in the presence of exogenous AHL. The AHL-like compounds proved to be formed by 9.7% of the studied bacteria. Various Pseudomonas species differed in the capacity to synthesize this compounds. In at least a half of the isolated P. aureofaciens and P. aeruginosa, an intense AHL production was observed, whereas the AHL-producers were far less frequent among the P. fluorescens, P. chlororaphis, P. lemonnieri, P. geniculata, and P. putida. None of the 41 Xanthomonas maltophilia strains examined synthesized AHL.

[Features of functioning of the promoter of microcin C51 promoter under various conditions of Escherichia coli cell growth]. / Osobennosti funktsionirovaniia promotora operona mikrotsina C51 v razlichnykh usloviiakh rosta kletok Escherichia coli.

The level of transcription from the promoter of the microcin C51 operon (Pmcc) depends on the growth phase of Escherichia coli cells: transcription proceeds with low efficiency at the exponential phase of growth and with higher efficiency when growth of cells is delayed during entry into the stationary phase. The functioning of Pmcc was studied in cells grown in different media by a single-copy construct, which contained the cloned promoter region of the microcin C51 operon and the promoterless lac operon. A decrease in the rate of cell growth caused by changes in the sole carbon source in minimal medium correlated with an increase in the level of transcription from the Pmcc promoter at the exponential phase of growth; the expression of Pmcc-lac during cell entry into the stationary phase was higher under unfavorable medium conditions. The use of composite rich media impaired this feature. The addition of l-leucine (100 micrograms/ml) to the medium decreased the expression of Pmcc-lac in wild-type cells carrying the delta lrp mutation. A further increase in leucine concentration and the presence of other amino acids in the medium enhanced transcription that started from Pmcc during cell entry into the stationary growth phase. The capacity of the Pmcc promoter and of the wild-type lacZ gene promoter was virtually the same upon IPTG induction. A mutation in the ompR gene did not markedly influence transcription started from Pmcc.

[Identification and expression of plasmid genes participating in the synthesis of microcin C51]. / Identifikatsiia i ékspressiia plazmidnykh genov, uchastvuiushchikh v sinteze mikrotsina C51.

A structural gene of heptapeptide, which is a component of the microcin C51 molecule, was identified by hybridization of plasmid DNA fragments and a mixture of synthesized oligonucleotides with the sequence corresponding to that of amino acids in the peptide. Sequence analysis of the structural gene of microcin peptide and its promoter region was performed. The data obtained indicate that the peptide of microcin C51 is synthesized on ribosomes. Four polypeptides of 67, 39, 16, and 14 kDa were identified using the system of minicells. These polypeptides are specified by a DNA fragment responsible for microcin synthesis and immunity in a producer cell. Apparently, three of these polypeptides with molecular masses of 67, 39, and 16 kDa are responsible for microcin production and immunity. The 67 kDa polypeptide is involved in the expression of immunity to microcin and, probably, in microcin production.

[Plasmid genes participating in the synthesis of microcin C51]. / Plazmidnye geny, uchastvuiushchie v sinteze mikrotsina C51.

Microcin C51 is an antibiotic with a wide application range produced by Escherichia coli cells. Using insertions of transposon Tn5 a set of mutations was induced in the recombinant plasmid pAST, which determines synthesis of microcin C51. The mutations were physically mapped. Complementation analysis was performed for insertions and deletions in the Mic+ plasmids pAST and pUHAB that lead to the absence of microcin or immunity to it. The analysis showed that at least three plasmid genes take part in microcin production and two genes determine immunity of producer cells to microcin. Functioning of the ompR gene product was necessary for synthesis of microcin C51.

[Characterization of enterobacteria producing the broad-spectrum antibiotics microcins]. / Kharakteristika énterobakterii, produtsiruiushchikh antibiotiki shirokogo spektra deistviia mikrotsiny.

As a result of screening among 11956 enterobacteria strains isolated from feces of normal children, grown-ups and lambs, seven active microcin-producing strains were obtained. The microcins were shown to be peptides or their derivatives with a low molecular weight (less than 10,000) and a broad spectrum of activity, mainly against gram-negative bacteria. According to cross immunity criteria the microcins studied belonged to two different types. Those of type I could be further classified into two subtypes on the account of difference in the spectrum of antibacterial activity. In 5 cases out of 7 the microcin-producing ability and immunity to microcins have been attributed to plasmids that the strains harboured. The effect of microcins on sensitive cells depended on ompR and ompF gene products.

[Mapping of plasmid genes responsible for microcin R51 synthesis and immunity to it]. / Kartirovanie plazmidnykh genov, opredeliaiushchikh sintez mikrotsina R51 i immunitet k nemu.

Microcin R51 is plasmid-determined low-molecular-weight peptide antibiotic produced by Escherichia coli. The spectrum of its action includes many different species of gram negative and some gram positive bacteria. Microcinogenic strains are immune to the action of the microcin they synthesize. As shown earlier, genes responsible for MccR51 production and immunity are located in a continuous 11.1 kb DNA fragment. These genes were cloned in pUC19 and pACYC184 plasmid vectors. Deletion derivatives and Tn5 insertion mutant plasmids which determined no microcin synthesis and immunity were obtained. Analysis of clones' phenotypes and physical mapping of mutant plasmids demonstrated that the 5 kb DNA fragment was indispensable for microcin production. The region of about 4.6 kb confers complete immunity of the producing strains, while partial immunity is provided by 1.8-1.9 kb DNA fragment.