Activation of Purine Biosynthesis Suppresses the Sensitivity of E. coli gmhA Mutant to Antibiotics.

Inactivation of enzymes responsible for biosynthesis of the cell wall component of ADP-glycero-manno-heptose causes the development of oxidative stress and sensitivity of bacteria to antibiotics of a hydrophobic nature. The metabolic precursor of ADP-heptose is sedoheptulose-7-phosphate (S7P), an intermediate of the non-oxidative branch of the pentose phosphate pathway (PPP), in which ribose-5-phosphate and NADPH are generated. Inactivation of the first stage of ADP-heptose synthesis (ΔgmhA) prevents the outflow of S7P from the PPP, and this mutant is characterized by a reduced biosynthesis of NADPH and of the Glu-Cys-Gly tripeptide, glutathione, molecules known to be involved in the resistance to oxidative stress. We found that the derepression of purine biosynthesis (∆purR) normalizes the metabolic equilibrium in PPP in ΔgmhA mutants, suppressing the negative effects of gmhA mutation likely via the over-expression of the glycine-serine pathway that is under the negative control of PurR and might be responsible for the enhanced synthesis of NADPH and glutathione. Consistently, the activity of the soxRS system, as well as the level of glutathionylation and oxidation of proteins, indicative of oxidative stress, were reduced in the double ΔgmhAΔpurR mutant compared to the ΔgmhA mutant.

Zn-dependent ß-amyloid Aggregation and its Reversal by the Tetrapeptide HAEE.

The pathogenesis of Alzheimer's disease (AD) is associated with the formation of cerebral amyloid plaques, the main components of which are the modified Aß molecules as well as the metal ions. Aß isomerized at Asp7 residue (isoD7-Aß) is the most abundant isoform in amyloid plaques. We hypothesized that the pathogenic effect of isoD7-Aß is due to the formation of zinc-dependent oligomers, and that this interaction can be disrupted by the rationally designed tetrapeptide (HAEE). Here, we utilized surface plasmon resonance, nuclear magnetic resonance, and molecular dynamics simulation to demonstrate Zn2+-dependent oligomerization of isoD7-Aß and the formation of a stable isoD7-Aß:Zn2+:HAEE complex incapable of forming oligomers. To demonstrate the physiological importance of zinc-dependent isoD7-Aß oligomerization and the ability of HAEE to interfere with this process at the organismal level, we employed transgenic nematodes overexpressing human Aß. We show that the presence of isoD7-Aß in the medium triggers extensive amyloidosis that occurs in a Zn2+-dependent manner, enhances paralysis, and shortens the animals' lifespan. Exogenous HAEE completely reverses these pathological effects of isoD7-Aß. We conclude that the synergistic action of isoD7-Aß and Zn2+ promotes Aß aggregation and that the selected small molecules capable of interrupting this process, such as HAEE, can potentially serve as anti-amyloid therapeutics.

The Inactivation of LPS Biosynthesis Genes in E. coli Cells Leads to Oxidative Stress.

Impaired lipopolysaccharide biosynthesis in Gram-negative bacteria results in the "deep rough" phenotype, which is characterized by increased sensitivity of cells to various hydrophobic compounds, including antibiotics novobiocin, actinomycin D, erythromycin, etc. The present study showed that E. coli mutants carrying deletions of the ADP-heptose biosynthesis genes became hypersensitive to a wide range of antibacterial drugs: DNA gyrase inhibitors, protein biosynthesis inhibitors (aminoglycosides, tetracycline), RNA polymerase inhibitors (rifampicin), and ß-lactams (carbenicillin). In addition, it was found that inactivation of the gmhA, hldE, rfaD, and waaC genes led to dramatic changes in the redox status of cells: a decrease in the pool of reducing NADPH and ATP equivalents, the concentration of intracellular cysteine, a change in thiol homeostasis, and a deficiency in the formation of hydrogen sulfide. In "deep rough" mutants, intensive formation of reactive oxygen species was observed, which, along with a lack of reducing agents, such as reactive sulfur species or NADPH, leads to oxidative stress and an increase in the number of dead cells in the population. Within the framework of modern ideas about the role of oxidative stress as a universal mechanism of the bactericidal action of antibiotics, inhibition of the enzymes of ADP-heptose biosynthesis is a promising direction for increasing the effectiveness of existing antibiotics and solving the problem of multidrug resistance.

Structural investigation of the thymidine phosphorylase from Salmonella typhimurium in the unliganded state and its complexes with thymidine and uridine.

Highly specific thymidine phosphorylases catalyze the phosphorolytic cleavage of thymidine, with the help of a phosphate ion, resulting in thymine and 2-deoxy-α-D-ribose 1-phosphate. Thymidine phosphorylases do not catalyze the phosphorolysis of uridine, in contrast to nonspecific pyrimidine nucleoside phosphorylases and uridine phosphorylases. Understanding the mechanism of substrate specificity on the basis of the nucleoside is essential to support rational drug-discovery investigations of new antitumour and anti-infective drugs which are metabolized by thymidine phosphorylases. For this reason, X-ray structures of the thymidine phosphorylase from Salmonella typhimurium were solved and refined: the unliganded structure at 2.05 Å resolution (PDB entry 4xr5), the structure of the complex with thymidine at 2.55 Å resolution (PDB entry 4yek) and that of the complex with uridine at 2.43 Å resolution (PDB entry 4yyy). The various structural features of the enzyme which might be responsible for the specificity for thymidine and not for uridine were identified. The presence of the 2'-hydroxyl group in uridine results in a different position of the uridine furanose moiety compared with that of thymidine. This feature may be the key element of the substrate specificity. The specificity might also be associated with the opening/closure mechanism of the two-domain subunit structure of the enzyme.

X-ray structure of Salmonella typhimurium uridine phosphorylase complexed with 5-fluorouracil and molecular modelling of the complex of 5-fluorouracil with uridine phosphorylase from Vibrio cholerae.

Uridine phosphorylase (UPh), which is a key enzyme in the reutilization pathway of pyrimidine nucleoside metabolism, is a validated target for the treatment of infectious diseases and cancer. A detailed analysis of the interactions of UPh with the therapeutic ligand 5-fluorouracil (5-FUra) is important for the rational design of pharmacological inhibitors of these enzymes in prokaryotes and eukaryotes. Expanding on the preliminary analysis of the spatial organization of the active centre of UPh from the pathogenic bacterium Salmonella typhimurium (StUPh) in complex with 5-FUra [Lashkov et al. (2009), Acta Cryst. F65, 601-603], the X-ray structure of the StUPh-5-FUra complex was analysed at atomic resolution and an in silico model of the complex formed by the drug with UPh from Vibrio cholerae (VchUPh) was generated. These results should be considered in the design of selective inhibitors of UPhs from various species.

Comparison of the structure and regulation of the udp gene of Vibrio cholerae, Yersinia pseudotuberculosis, Salmonella typhimurium, and Escherichia coli.

The nucleotide sequences of the udp gene encoding uridine phosphorylase of Yersinia pseudotuberculosis and Vibrio cholerae are presented and compared with the udp sequences of Salmonella typhimurium and Escherichia coli. Both genes contain 759 bases and encode a 253 amino acid polypeptide, which is the same as for E. coli and S. typhimurium. The amino acid sequence derived from S. typhimurium gene was more similar to the derived E. coli sequence, with only a 7 amino acid difference. The Y. pseudotuberculosis and V. cholerae uridine phosphorylases presented a higher degree of divergence in their amino acid sequence as compared to the corresponding E. coli amino acid sequence, with 20 and 64 changes, respectively. The promoter regions of the udp gene for S. typhimurium (udpPSt), Y. pseudotuberculosis (udpPYp) and V. cholerae (udpPVc) were identified by primer extension analysis. Comparative analysis of the udpP promoter region from Y. pseudotuberculosis, V. cholerae, S. typhimurium and E. coli revealed that location, spacing and orientation of putative binding sites for CRP protein are highly conserved, whereas CytR protein recognition sequences of udpPYp and udpPVc deviate markedly from the E. coli and S. typhimurium CytR binding site. In vitro studies demonstrated that the CytR protein from E. coli shows different affinity for each promoter region analyzed. According to this, the degree of CytR derepression after introduction of heterologous promoters into E. coli cells is different.

The riboswitch-mediated control of sulfur metabolism in bacteria.

Many operons in Gram-positive bacteria that are involved in methionine (Met) and cysteine (Cys) biosynthesis possess an evolutionarily conserved regulatory leader sequence (S-box) that positively controls these genes in response to methionine starvation. Here, we demonstrate that a feed-back regulation mechanism utilizes S-adenosyl-methionine as an effector. S-adenosyl-methionine directly and specifically binds to the nascent S-box RNA, causing an intrinsic terminator to form and interrupt transcription prematurely. The S-box leader RNA thus expands the family of newly discovered riboswitches, i.e., natural regulatory RNA aptamers that seem to sense small molecules ranging from amino acid derivatives to vitamins.