Expression of Aeromonas caviae ST pyruvate dehydrogenase complex components mediate tellurite resistance in Escherichia coli

Potassium tellurite (K₂TeO₃) is harmful to most organisms and specific mechanisms explaining its toxicity are not well known to date. We previously reported that the lpdA gene product of the tellurite-resistant environmental isolate Aeromonas caviae ST is involved in the reduction of tellurite to elemental tellurium. In this work, we show that expression of A. caviae ST aceE, aceF, and lpdA genes, encoding pyruvate dehydrogenase, dihydrolipoamide transacetylase, and dihydrolipoamide dehydrogenase, respectively, results in tellurite resistance and decreased levels of tellurite-induced superoxide in Escherichia coli. In addition to oxidative damage resulting from tellurite exposure, a metabolic disorder would be simultaneously established in which the pyruvate dehydrogenase complex would represent an intracellular tellurite target. These results allow us to widen our vision regarding the molecular mechanisms involved in bacterial tellurite resistance by correlating tellurite toxicity and key enzymes of aerobic metabolism.     

Analysis of the tellurite resistance determinant on the pNT3B derivative of the pTE53 plasmid from uropathogenic Escherichia coli

We have found and sequenced a significant part of the previously described tellurite resistance determinant on mini-Mu derivative pPR46, named pNT3B, originally cloned from a large conjugative plasmid pTE53, found in Escherichia coli. This plasmid contains genes essential for tellurite resistance, together with the protective region bearing genes terX, Y, W, and the conserved spacing region bearing several ORFs of unknown function. Computer analysis of obtained sequence revealed a close similarity to the formerly described ter operons found on the Serratia marcescens plasmid R478 and the chromosome of Escherichia coli O157:H7. This finding confirms the presence of a whole region on the large conjugative plasmid that pTE53 originated from a uropathogenic E. coli strain, and suggests its possible role in horizontal gene transfer, resulting in the development of new pathogenic E. coli strains.     

Cysteine metabolism-related genes and bacterial resistance to potassium tellurite

Tellurite exerts a deleterious effect on a number of small molecules containing sulfur moieties that have a recognized role in cellular oxidative stress. Because cysteine is involved in the biosynthesis of glutathione and other sulfur-containing compounds, we investigated the expression of Geobacillus stearothermophilus V cysteine-related genes cobA, cysK, and iscS and Escherichia coli cysteine regulon genes under conditions that included the addition of K₂TeO₃ to the culture medium. Results showed that cell tolerance to tellurite correlates with the expression level of the cysteine metabolic genes and that these genes are up-regulated when tellurite is present in the growth medium.     

In Vivo 31P Nuclear Magnetic Resonance Investigation of Tellurite Toxicity in Escherichia coli

Here we compare the physiological state of Escherichia coli exposed to tellurite or selenite by using the noninvasive technique of phosphorus-31 nuclear magnetic resonance (NMR) spectroscopy. We studied glucose-fed Escherichia coli HB101 cells containing either a normal pUC8 plasmid with no tellurite resistance determinants present or the pTWT100 plasmid which contains the resistance determinants tehAB. No differences could be observed in intracellular ATP levels, the presence or absence of a transmembrane pH gradient, or the levels of phosphorylated glycolytic intermediates when resistant cells were studied by ³¹P NMR in the presence or absence of tellurite. In the sensitive strain, we observed that the transmembrane pH gradient was dissipated and intracellular ATP levels were rapidly depleted upon exposure to tellurite. Only the level of phosphorylated glycolytic intermediates remained the same as observed with resistant cells. Upon exposure to selenite, no differences could be observed by ³¹P NMR between resistant and sensitive strains, suggesting that the routes for selenite and tellurite reduction within the cells differ significantly, since only tellurite is able to collapse the transmembrane pH gradient and lower ATP levels in sensitive cells. The presence of the resistance determinant tehAB, by an as yet unidentified detoxification event, protects the cells from uncoupling by tellurite.     

Depletion of reduction potential and key energy generation metabolic enzymes underlies tellurite toxicity in Deinococcus radiodurans

Oxidative stress resistant Deinococcus radiodurans surprisingly exhibited moderate sensitivity to tellurite induced oxidative stress (LD₅₀ = 40 μM tellurite, 40 min exposure). The organism reduced 70% of 40 μM potassium tellurite within 5 h. Tellurite exposure significantly modulated cellular redox status. The level of ROS and protein carbonyl contents increased while the cellular reduction potential substantially decreased following tellurite exposure. Cellular thiols levels initially increased (within 30 min) of tellurite exposure but decreased at later time points. At proteome level, tellurite resistance proteins (TerB and TerD), tellurite reducing enzymes (pyruvate dehydrogense subunits E1 and E3), ROS detoxification enzymes (superoxide dismutase and thioredoxin reductase), and protein folding chaperones (DnaK, EF‐Ts, and PPIase) displayed increased abundance in tellurite‐stressed cells. However, remarkably decreased levels of key metabolic enzymes (aconitase, transketolase, 3‐hydroxy acyl‐CoA dehydrogenase, acyl‐CoA dehydrogenase, electron transfer flavoprotein alpha, and beta) involved in carbon and energy metabolism were observed upon tellurite stress. The results demonstrate that depletion of reduction potential in intensive tellurite reduction with impaired energy metabolism lead to tellurite toxicity in D. radiodurans.     

DNA sequence analysis of the tellurite-resistance determinant from clinical strain of Escherichia Coli and identification of essential genes

The tellurite-resistant Escherichia coli strain KL53 was found during testing of the group of clinical isolates for antibiotics and heavy metal ion resistance (Burian et al. 1990). Determinant of the tellurite resistance of the strain was located on the large conjugative plasmid pTE53 and cloned into pACYC184. Three different Te^r clones harboring pLK2, pLK18 and pLK20 were isolated (Burian et al. 1998). The smallest functional Te^r clone harboring pLK18 was chosen for further analysis. Plasmid pLK18 have been subcloned to obtain convenient DNA fragments for sequencing of tellurite-resistance determinant. Sequencing of this DNA fragments provided complete DNA sequence of the determinant, 5250 bp in size. The sequence has been compared with nucleotide and protein databank (BLAST programs) and significant homology with the three known operons coding for tellurite resistance has been found (determinat on plasmid pR478 from Serratia marcescens, on plasmid pMER610 from Alcaligenes sp. and chromosomal tellurite resistance genes from Proteus mirabilis). We identified 5 ORFs coding for 5 genes named terB to terF. The clone harboring pLK18 was subjected to the transposition with Tn1737Km to disrupt determinant of the tellurite resistance. Plasmid DNA of several clones containing pLK18 with Tn1737Km was isolated to locate the target site of Tn1737Km. Analyses showed, the genes terB, terC, terD and terE are essential for conservation of the resistance whereas the gene terF is not important in this respect.     

基于转录组分析大肠杆菌响应亚碲酸盐的机制

亚碲酸盐对绝大多数微生物有高毒性,可用作抗菌剂;但其具体毒性机制仍不清楚。【目的】理解亚碲酸盐的毒性机制,揭示亚碲酸盐处理导致的代谢变化。【方法】本研究通过比较转录组分析与挖掘差异转录基因,探讨了大肠杆菌响应亚碲酸盐胁迫的机制。【结果】Escherichia coli MG1655在10μg/mL亚碲酸盐处理1 h后,比较和分析了亚碲酸盐处理组与对照组的转录水平差异,发现细胞呈现一种明显的适应性变化,许多参与重要代谢途径的基因转录水平改变。其中,与核糖体代谢和鞭毛组装相关基因的转录水平发生显著变化,表明这两条途径很可能是亚碲酸盐作用的主要途径。与细胞能动性、金属离子代谢、细胞膜功能相关的基因的转录水平也发生了明显变化,可能是由于其参与了抵抗亚碲酸盐毒性的细胞代谢调节和损伤修复。【结论】本项工作有助于推动亚碲酸盐毒性机理的研究,促进亚碲酸盐的临床应用。     

Bile Salt Activation of Stress Response Promoters in Escherichia coli

Bile salts are prevalent in the mammalian intestine, a natural habitat of Escherichia coli. The bile salts deoxycholate, chenodeoxycholate, ursodeoxycholate, and glycocholate were tested for their effect on induction of 13 specific stress response genes. The most consistently activated E. coli promoters were those for genes micF, osmY, and dinD. MicF and osmY gene products are associated with membrane functions and are responsive to oxidative stress. DinD is induced by DNA damage as part of the SOS response. These results indicate that bile acids, to which E. coli are naturally exposed, induce expression of specific stress response genes, possibly in response to membrane perturbation, oxidative stress, and DNA damage. Altered expression of stress-response genes may also promote interaction of E. coli with cells of the colonic epithelium. Received: 5 March 1999 / Accepted: 2 April 1999     

Proteomic Differences between Tellurite-Sensitive and Tellurite–Resistant E.coli

Tellurite containing compounds are in use for industrial processes and increasing delivery into the environment generates specific pollution that may well result in contamination and subsequent potential adverse effects on public health. It was the aim of the current study to reveal mechanism of toxicity in tellurite-sensitive and tellurite-resistant E. coli at the protein level.In this work an approach using gel-based mass spectrometrical analysis to identify a differential protein profile related to tellurite toxicity was used and the mechanism of ter operon-mediated tellurite resistance was addressed. E. coli BL21 was genetically manipulated for tellurite-resistance by the introduction of the resistance-conferring ter genes on the pLK18 plasmid. Potassium tellurite was added to cultures in order to obtain a final 3.9 micromolar concentration. Proteins from tellurite-sensitive and tellurite-resistant E. coli were run on 2-D gel electrophoresis, spots of interest were picked, in-gel digested and subsequently analysed by nano-LC-MS/MS (ion trap). In addition, Western blotting and measurement of enzymatic activity were performed to verify the expression of certain candidate proteins.Following exposure to tellurite, in contrast to tellurite-resistant bacteria, sensitive cells exhibited increased levels of antioxidant enzymes superoxide dismutases, catalase and oxidoreductase YqhD. Cysteine desulfurase, known to be related to tellurite toxicity as well as proteins involved in protein folding: GroEL, DnaK and EF-Tu were upregulated in sensitive cells. In resistant bacteria, several isoforms of four essential Ter proteins were observed and following tellurite treatment the abovementioned protein levels did not show any significant proteome changes as compared to the sensitive control.The absence of general defense mechanisms against tellurite toxicity in resistant bacteria thus provides further evidence that the four proteins of the ter operon function by a specific mode of action in the mechanism of tellurite resistance probably involving protein cascades from antioxidant and protein folding pathways.     

The highly toxic oxyanion tellurite (TeO<Stack><Subscript>3</Subscript><Superscript>2−</Superscript></Stack>) enters the phototrophic bacterium <Emphasis Type="Italic">Rhodobacter capsulatus</Emphasis> via an as yet uncharacterized monocarboxylate transport system

The facultative phototroph Rhodobacter capsulatus takes up the highly toxic oxyanion tellurite when grown under both photosynthetic and respiratory growth conditions. Previous works on Escherichia coli and R. capsulatus suggested that tellurite uptake occurred through a phosphate transporter. Here we present evidences indicating that tellurite enters R. capsulatus cells via a monocarboxylate transport system. Indeed, intracellular accumulation of tellurite was inhibited by the addition of monocarboxylates such as pyruvate, lactate and acetate, but not by dicarboxylates like malate or succinate. Acetate was the strongest tellurite uptake antagonist and this effect was concentration dependent, being already evident at 1 μM acetate. Conversely, tellurite at 100 μM was able to restrict the acetate entry into the cells. Both tellurite and acetate uptakes were energy dependent processes, since they were abolished by the protonophore FCCP and by the respiratory electron transport inhibitor KCN. Interestingly, cells grown on acetate, lactate or pyruvate showed a high level resistance to tellurite, whereas cells grown on malate or succinate proved to be very sensitive to the oxyanion. Taking these data together, we propose that: (a) tellurite enters R. capsulatus cells via an as yet uncharacterized monocarboxylate(s) transporter, (b) competition between acetate and tellurite results in a much higher level of tolerance against the oxyanion and (c) the toxic action of tellurite at the cytosolic level is significantly restricted by preventing tellurite uptake.     

The Role of Antioxidant Systems in the Cold Stress Response of Escherichia coli

The response of aerobically grown Escherichia coli cells to the cold shock induced by the rapid lowering of growth temperature from 37 to 20°C was found to be basically the same as the oxidative stress response. The enhanced sensitivity of cells deficient in two superoxide dismutases, Mn-SOD and Fe-SOD, and the increased expression of the Mn-SOD gene, sodA, in response to cold stress were interpreted as both oxidative and cold stresses are due to a rise in the intracellular level of superoxide anion. The long-term cultivation of E. coli at 20°C was also accompanied by the typical oxidative stress response reactions—an enhanced expression of the Mn-SOD and catalase HPI genes and a decrease in the intracellular level of reduced glutathione (GSH) and in the GSH/GSSG ratio.     

Polyamines as modulators of gene expression under oxidative stress in Escherichia coli

Activity of enzymes of polyamine synthesis and contents of their products increased in E. coli cells in response to oxidative stress caused by addition of hydrogen peroxide to an exponentially growing culture. Putrescine and spermidine added to the culture medium in physiological concentrations significantly increased expression of genes oxyR and katG responsible for defense against oxidative stress, whereas cadaverine had no effect. The role of polyamines as modulators of the gene expression was confirmed by experiments with an inhibitor of polyamine synthesis, 1,3-diaminopropane, which decreased the level of cell polyamines and thus abolished the ability of the cell to induce oxyR expression under oxidative stress. A genetic method gave similar results: under oxidative stress mutants with disorders in polyamine synthesis displayed a significantly decreased level of induction of the oxyR and katG genes, and this level was recovered on addition of putrescine. In the presence of inhibitors of DNA-gyrase, nalidixic acid and novobiocin, the oxyR expression depended on the extent of DNA supercoiling. Putrescine decreased the inhibitory effects of nalidixic acid and novobiocin, and this confirmed its properties of a stimulator of DNA supercoiling. Resistance to rifampicin was studied to exemplify the mutation rate under oxidative stress. Putrescine decreased twofold the level of mutations and increased the number of viable cells in the culture exposed to oxidative stress.     

Tellurite-induced carbonylation of the Escherichia coli pyruvate dehydrogenase multienzyme complex

The soluble tellurium oxyanion, tellurite, is toxic for most organisms. At least in part, tellurite toxicity involves the generation of oxygen-reactive species which induce an oxidative stress status that damages different macromolecules with DNA, lipids and proteins as oxidation targets. The objective of this work was to determine the effects of tellurite exposure upon the Escherichia coli pyruvate dehydrogenase (PDH) complex. The complex displays two distinct enzymatic activities: pyruvate dehydrogenase that oxidatively decarboxylates pyruvate to acetylCoA and tellurite reductase, which reduces tellurite (Te⁴⁺) to elemental tellurium (Te^o). PDH complex components (AceE, AceF and Lpd) become oxidized upon tellurite exposure as a consequence of increased carbonyl group formation. When the individual enzymatic activities from each component were analyzed, AceE and Lpd did not show significant changes after tellurite treatment. AceF activity (dihydrolipoil acetyltransferase) decreased ~30% when cells were exposed to the toxicant. Finally, pyruvate dehydrogenase activity decreased >80%, while no evident changes were observed in complex′s tellurite reductase activity.     

Metabolomic Investigation of the Bacterial Response to a Metal Challenge

Pseudomonas pseudoalcaligenes KF707 is naturally resistant to the toxic metalloid tellurite, but the mechanisms of resistance are not known. In this study we report the isolation of a KF707 mutant (T5) with hyperresistance to tellurite. In order to characterize the bacterial response and the pathways leading to tolerance, we utilized Phenotype MicroArray technology (Biolog) and a metabolomic technique based on nuclear magnetic resonance spectroscopy. The physiological states of KF707 wild-type and T5 cells exposed to tellurite were also compared in terms of viability and reduced thiol content. Our analyses showed an extensive change in metabolism upon the addition of tellurite to KF707 cultures as well as different responses when the wild-type and T5 strains were compared. Even in the absence of tellurite, T5 cells displayed a “poised” physiological status, primed for tellurite exposure and characterized by altered intracellular levels of glutathione, branched-chain amino acids, and betaine, along with increased resistance to other toxic metals and metabolic inhibitors. We conclude that hyperresistance to tellurite in P. pseudoalcaligenes KF707 is correlated with the induction of the oxidative stress response, resistance to membrane perturbation, and reconfiguration of cellular metabolism.     

The Product of the cysK Gene of Bacillus stearothermophilus V Mediates Potassium Tellurite Resistance in Escherichia coli

The nucleotide sequence of a 4,539 bp fragment of Bacillus stearothermophilus V mediating tellurite resistance in Escherichia coli was determined. Four ORFs of more than 150 amino acids encoding polypeptides of 244, 258, 308, and 421 residues were found in the restriction fragment. E. coli cells harboring a recombinant plasmid containing the Te^r determinant express, when challenged with tellurite, a 32 kDa protein with an amino terminal sequence identical to the ten first residues of the 308 ORF. This ORF shows great similarity with the cysteine synthase gene (cysK) of a number of organisms. Recombinant clones carrying the active cysK gene have minimal inhibitory concentrations to K₂TeO₃ that were tenfold higher than those determined for the host strain or that of clones carrying ORFs 244, 258, and 421. Introduction of the B. stearothermophilus V cysK gene into a cysK strain of Salmonella typhimurium LT2 resulted in complementation of the mutation as well as transfer of tellurite resistance. Received: 28 March 2001 / Accepted: 17 April 2001     

Hsp33 confers bleach resistance by protecting elongation factor Tu against oxidative degradation in Vibrio cholerae

The redox‐regulated chaperone Hsp33 protects bacteria specifically against stress conditions that cause oxidative protein unfolding, such as treatment with bleach or exposure to peroxide at elevated temperatures. To gain insight into the mechanism by which expression of Hsp33 confers resistance to oxidative protein unfolding conditions, we made use of Vibrio cholerae strain O395 lacking the Hsp33 gene hslO. We found that this strain, which is exquisitely bleach‐sensitive, displays a temperature‐sensitive (ts) phenotype during aerobic growth, implying that V. cholerae suffers from oxidative heat stress when cultivated at 43°C. We utilized this phenotype to select for Escherichia coli genes that rescue the ts phenotype of V. cholerae ΔhslO when overexpressed. We discovered that expression of a single protein, the elongation factor EF‐Tu, was sufficient to rescue both the ts and bleach‐sensitive phenotypes of V. cholerae ΔhslO. In vivo studies revealed that V. cholerae EF‐Tu is highly sensitive to oxidative protein degradation in the absence of Hsp33, indicating that EF‐Tu is a vital chaperone substrate of Hsp33 in V. cholerae. These results suggest an ‘essential client protein’ model for Hsp33's chaperone action in Vibrio in which stabilization of a single oxidative stress‐sensitive protein is sufficient to enhance the oxidative stress resistance of the whole organism.     

The Escherichia coli btuE gene, encodes a glutathione peroxidase that is induced under oxidative stress conditions

Most aerobic organisms are exposed to oxidative stress. Looking for enzyme activities involved in the bacterial response to this kind of stress, we focused on the btuE-encoded Escherichia coli BtuE, an enzyme that shares homology with the glutathione peroxidase (GPX) family. This work deals with the purification and characterization of the btuE gene product.Purified BtuE decomposes in vitro hydrogen peroxide in a glutathione-dependent manner. BtuE also utilizes preferentially thioredoxin A to decompose hydrogen peroxide as well as cumene-, tert-butyl-, and linoleic acid hydroperoxides, confirming that its active site confers non-specific peroxidase activity. These data suggest that the enzyme may have one or more organic hydroperoxide as its physiological substrate.The btuE gene was induced when cells were exposed to oxidative stress elicitors that included potassium tellurite, menadione and hydrogen peroxide, among others, suggesting that BtuE could participate in the E. coli response to reactive oxygen species. To our knowledge, this is the first report describing a glutathione peroxidase in E. coli.     

Role of Tellurite Resistance Operon in Filamentous Growth of Yersinia pestis in Macrophages

Background

Yersinia pestis initiates infection by parasitism of host macrophages. In response to macrophage infections, intracellular Y. pestis can assume a filamentous cellular morphology which may mediate resistance to host cell innate immune responses. We previously observed the expression of Y. pestis tellurite resistance proteins TerD and TerE from the terZABCDE operon during macrophage infections. Others have observed a filamentous response associated with expression of tellurite resistance operon in Escherichia coli exposed to tellurite. Therefore, in this study we examine the potential role of Y. pestis tellurite resistance operon in filamentous cellular morphology during macrophage infections.

Principal Findings

In vitro treatment of Y. pestis culture with sodium tellurite (Na₂TeO₃) caused the bacterial cells to assume a filamentous phenotype similar to the filamentous phenotype observed during macrophage infections. A deletion mutant for genes terZAB abolished the filamentous morphologic response to tellurite exposure or intracellular parasitism, but without affecting tellurite resistance. However, a terZABCDE deletion mutant abolished both filamentous morphologic response and tellurite resistance. Complementation of the terZABCDE deletion mutant with terCDE, but not terZAB, partially restored tellurite resistance. When the terZABCDE deletion mutant was complemented with terZAB or terCDE, Y. pestis exhibited filamentous morphology during macrophage infections as well as while these complemented genes were being expressed under an in vitro condition. Further in E. coli, expression of Y. pestis terZAB, but not terCDE, conferred a filamentous phenotype.

Conclusions

These findings support the role of Y. pestis terZAB mediation of the filamentous response phenotype; whereas, terCDE confers tellurite resistance. Although the beneficial role of filamentous morphological responses by Y. pestis during macrophage infections is yet to be fully defined, it may be a bacterial adaptive strategy to macrophage associated stresses.     

Isolation of oxidative stress response mutants in Escherichia coli for their use as a genetic screen to identify new anti-mycobacterials as functional analogues of isoniazid

Summary Tuberculosis is a leading killer disease of the world with increasing mortality due to HIV-infected individuals becoming highly prone to this infection. An attempt has been made in the present work to identify novel plant-derived compounds active against Mycobacterium tuberculosis (MTB) through construction of a target based bio-screen to facilitate rapid screening of anti-TB plant compounds. To achieve this, construction of a genetically modified model system was attempted in fast growing, non-pathogenic, Escherichia coli in which experimental testing is relatively easier and rapid as compared to M. tuberculosis, which is pathogenic and slow growing in nature. The exquisitely high sensitivity of M. tuberculosis to isoniazid (INH) has been attributed to lesions in oxyR, a gene that positively regulates the expression of a set of hydrogen peroxide-inducible genes in E. coli and S. typhimurium. Moreover in the mechanism of emergence of INH resistance in M. tuberculosis, oxidative stress response has been implicated. In this study, mutants of E. coli defective in oxidative stress response function were derived and used to screen plant compounds, which might interfere with the oxidative stress response in MTB. Since MTB is inherently known to be oxyR defective and thus being highly sensitive to INH, mutants defective in oxidative stress response were isolated to construct a model system in E. coli, which is otherwise INH resistant, having functional oxyR. These mutants showed simultaneous sensitivity to oxidative stress-causing agents like hydrogen peroxide and cumene hydroperoxide. To further define the mutational lesions, complementation studies were carried out through mobilization of cloned wild type genes involved in the oxidative stress response and in this way a biological screen was constructed to identify plant compounds/essential oils/extracts/oil components which induce oxidative stress. The positives were finally tested for activity against M. tuberculosis strain H37Rv using the radiometric BACTEC 460 TB system. Interestingly, the bioactives were found to be active against the pathogen with marked potency, as the reduction in δGI values for the identified bioactives against M. tuberculosis were significant. The study demonstrates application of a specific target-based genetic model system in E. coli as a rapid high throughput screen in identifying anti-mycobacterials from plants.