[Low-Molecular Thiols as a Factor Improving the Sensitivity of Escherichia coli Mutants with Impaired ADP-Heptose Synthesis to Antibiotics].

Low molecular-weight thiols as glutathione and cysteine are an important part of the cell's redox regulation system. Previously, we have shown that inactivation of ADP-heptose synthesis in Escherichia coli with a gmhA deletion induces the oxidative stress. It is accompanied by rearrangement of thiol homeostasis and increased sensitivity to antibiotics. In our study, we found that restriction of cysteine metabolism (ΔcysB and ΔcysE) and inhibition of glutathione synthesis (ΔgshAB) lead to a decrease in the sensitivity of the ΔgmhA mutant to antibiotics but not to its expected increase. At the same time, blocking of the export of cysteine (ΔeamA) or increasing import (Ptet-tcyP) into cells of the oxidized form of cysteine-cystine leads to an even greater increase in the sensitivity of gmhA-deleted cells to antibiotics. In addition, there is no correlation between the cytotoxic effect of antibiotics and the level of reactive oxygen species (ROS), the total pool of thiols, or the viability of the initial cell population. However, a correlation between the sensitivity to antibiotics and the level of oxidized glutathione in cells was found in our study. Apparently, a decrease in the content of low-molecular-weight thiols saves NADPH equivalents and limits the processes of protein redox modification. This leads to increasing of resistance of the ΔgmhA strain to antibiotics. An increase in low-molecular-weight thiols levels requires a greater expenditure of cell resources, leads to an increase in oxidized glutathione and induces to greater increase in sensitivity of the ΔgmhA strain to antibiotics.

Enhancement of the Bactericidal Effect of Antibiotics by Inhibition of Enzymes Involved in Production of Hydrogen Sulfide in Bacteria.

Counteraction of the origin and distribution of multidrug-resistant pathogens responsible for intra-hospital infections is a worldwide issue in medicine. In this brief review, we discuss the results of our recent investigations, which argue that many antibiotics, along with inactivation of their traditional biochemical targets, can induce oxidative stress (ROS production), thus resulting in increased bactericidal efficiency. As we previously showed, hydrogen sulfide, which is produced in the cells of different pathogens protects them not only against oxidative stress but also against bactericidal antibiotics. Next, we clarified the interplay of oxidative stress, cysteine metabolism, and hydrogen sulfide production. Finally, demonstrated that small molecules, which inhibit a bacterial enzyme involved in hydrogen sulfide production, potentiate bactericidal antibiotics including quinolones, beta-lactams, and aminoglycosides against bacterial pathogens in in vitro and in mouse models of infection. These inhibitors also suppress bacterial tolerance to antibiotics by disrupting the biofilm formation and substantially reducing the number of persister bacteria, which survive the antibiotic treatment. We hypothesise that agents which limit hydrogen sulfide biosynthesis are effective tools to counteract the origin and distribution of multidrug-resistant pathogens.

[Enhancement of the Bactericidal Effect of Antibiotics by Inhibition of Enzymes Involved in Production of Hydrogen Sulfide in Bacteria].

Counteraction of the origin and distribution of multidrug-resistant pathogens responsible for intra-hospital infections is a worldwide issue in medicine. In this brief review, we discuss the results of our recent investigations, which argue that many antibiotics, along with inactivation of their traditional biochemical targets, can induce oxidative stress (ROS production), thus resulting in increased bactericidal efficiency. As we previously showed, hydrogen sulfide, which is produced in the cells of different pathogens protects them not only against oxidative stress but also against bactericidal antibiotics. Next, we clarified the interplay of oxidative stress, cysteine metabolism, and hydrogen sulfide production. Finally, demonstrated that small molecules, which inhibit a bacterial enzyme involved in hydrogen sulfide production, potentiate bactericidal antibiotics including quinolones, beta-lactams, and aminoglycosides against bacterial pathogens in in vitro and in mouse models of infection. These inhibitors also suppress bacterial tolerance to antibiotics by disrupting the biofilm formation and substantially reducing the number of persister bacteria, which survive the antibiotic treatment. We hypothesise that agents which limit hydrogen sulfide biosynthesis are effective tools to counteract the origin and distribution of multidrug-resistant pathogens.

[Inactivation of Terminal Oxidase bd-I Leads to Supersensitivity of E. coli to Quinolone and Beta-Lactam Antibiotics].

In cells of Escherichia coli, terminal oxidase bd-I encoded by the cydAB gene catalyzes the reduction of O2 to water using hydroquinone as an electron donor. In addition to the cydAB operon, two other genes, cydC and cydD, encoding the heterodimeric ATP-binding cassette-type transporter are essential for the assembly of cytochrome bd-I. It was shown that inactivation of cytochrome bd-I by the introduction of cydB or cydD deletions into the E. coli chromosome leads to supersensitivity of the bacteria to antibiotics of the quinolone and beta-lactam classes. The sensitivity of these mutants to antibiotics is partially suppressed by introduction of a constitutively expressed gene katG under the control of the Ptet promoter into their genome. The increased level of hydrogen sulfide resulting from the introduction of the mstA gene, encoding 3-mercaptopyruvate sulfurtransferase, under the control of the Ptet promoter, leads to the same effect. These data demonstrate the important role of cytochrome bd-I in the defense of bacteria from oxidative stress and bactericidal antibiotics.

Exceptional Concentrations of Gold Nanoparticles in 1,7 Ga Fluid Inclusions From the Kola Superdeep Borehole, Northwest Russia.

In the drill core of the Kola super-deep borehole (SG-3, 12,262 m depth) gold-bearing rocks of Archaean age have been located at depths of 9,500 to 11,000 m. In veins, between 9,052 and 10,744 m, within this gold zone, quartz contains fluid inclusions with gold nanoparticles. There are 4 types of fluid inclusions (1) gas inclusions of dense CO2, (2) liquid-vapor two-phase aqueous inclusions, (3) three-phase inclusions with NaCl daughter crystals, and (4) CO2-aqueous inclusions. In all inclusion types, there are extremely high concentrations of gold. The highest gold concentrations were found in the type 3 and 4 fluid inclusions with an average concentration of c. 750 ppm and may be as high as 6,000 ppm. The presence of gold as nanoparticles in the solutions of these fluid inclusions was determined by optical and spectroscopic methods. We suggest that these fluids could be a precursor of "orogenic gold fluids" which, at the gold concentrations determined, would reduce the requirements for large volumes of metamorphic fluids to form orogenic ore deposits. Further, as nanoparticles, gold could be transported in larger amounts than in true solution.

Acadesine Triggers Non-apoptotic Death in Tumor Cells.

We studied the cytotoxicity of acadesine (5-aminoimidazole-4-carboxamide-1-ß-D-ribofuranoside) for tumor and normal cells of various species and tissue origin. In tumor cells, acadesine triggered non-apoptotic death; the potency of the compound to normal cells was substantially lower. Acadesine was toxic for tumor cells with multidrug resistant phenotypes caused by the transmembrane transporter Р-glycoprotein or lack of proapoptotic p53. Activity of adenosine receptors was required for acadesine-induced cell death, whereas functioning of АМР-dependent protein kinase was not required. A more pronounced cytotoxicity for tumor cells, as well as the non-canonical death mechanism(s), makes acadesine a promising candidate for antitumor therapy.

[Mutation analysis of the purine operon leader region in Bacillus subtilis].

Expression of Bacillus subtilis purine (purE) operon is a subject of double negative control involving repressor protein PurR and a transcription terminator located in the operon leader region. We have performed site-directed mutagenesis of the specific motives, which are involved in formation of alternative hairpin structures, one of which produces transcription termination at the leader region ofpurEoperon. In vivo and in vitro analyses of the generated mutants have shown that purine bases, guanine and hypoxantine, serve as effector metabolites capable of increasing stability of terminating hairpin within the leader mRNA. Therefore, the leader RNA of purE operon serves as a sensor towards these metabolites and a riboswitch that provides premature termination of the operon transcription. The synergistic effect of the PurR repressor protein and a transcription terminator located at the leader region on the expression of purE operon was also revealed.

Reconstruction of Purine Metabolism in Bacillus subtilis to Obtain the Strain Producer of AICAR: A New Drug with a Wide Range of Therapeutic Applications.

AICAR is a natural compound, an analogue and precursor of adenosine. As activator of AMP-activated protein kinase (AMPK), AICAR has a broad therapeutic potential, since it normalizes the carbohydrate and lipid metabolism and inhibits the proliferation of tumor cells. The synthesis of AICAR inBacillus subtiliscells is controlled by the enzymes of purine biosynthesis; their genes constituting purine operon (pur-operon). Reconstruction of purine metabolism inB. subtiliswas performed to achieve overproduction of AICAR. For this purpose, the genepurH, which encodes formyltransferase/IMP-cyclohydrolase, an enzyme that controls the conversion of AICAR to IMP, was removed from theB. subtilisgenome, ensuring the accumulation of AICAR. An insertion inactivating the genepurRthat encodes the negative transcriptional regulator of the purine biosynthesis operon was introduced into theB.subtilischromosome in order to boost the production of AICAR; the transcription attenuator located in the leader sequence ofpur-operon was deleted. Furthermore, the expression integrative vector carrying a strong promoter of therpsFgene encoding the ribosomal protein S6 was designed. The heterologousEscherichia coligenepurFencoding the first enzyme of the biosynthesis of purines with impaired allosteric regulation, as well as the modifiedE.coligeneprsresponsible for the synthesis of the precursor of purines - phosphoribosyl pyrophosphate (PRPP) - was cloned into this vector under the control of therpsFgene promoter. The modifiedpurFandprsgenes were inserted into the chromosome of theB. subtilisstrain.B. subtilisstrain obtained by these genetic manipulations accumulates 11-13 g/L of AICAR in the culture fluid.

[Mutations altering the specificity of the sensor RNA encoded by the Bacillus subtilis pbuE gene].

Site-directed mutagenesis was used to study the leader region of the Bacillus subtilis pbuE gene, which codes for adenine-specific sensor RNA. Two nucleotide substitutions, 70U --> C and A100 --> G, in the conserved region (A box) of the leader changed the specificity of the sensor RNA in vivo: guanine acted as a positive transcription effector in place of adenine.