Your search keyword '"SOS response"' showing total 2,589 results

101. Ultrasonic cavitation induced Vibrio parahaemolyticus entering an apoptosis-like death process through SOS response.

Author

Liu, Chunhui, Xu, Qi, Ma, Jiaqi, Wang, Sai, Li, Jiao, and Mao, Xiangzhao

Subjects

*VIBRIO parahaemolyticus, *ULTRASONICS, *CAVITATION, *APOPTOSIS, *CHOICE (Psychology)

Abstract

• Ultrasonic stress could cause active programmed death of Vibrio parahaemolyticus. • Ultrasonic stress disrupted the balance of redox reactions, mediating DNA damage. • Involvement of SOS response in the activation of apoptosis in Vibrio parahaemolyticus. • Diversity in lethal modes of Vibrio parahaemolyticus induced by ultrasonic cavitation. As an effective non-thermal sterilization method, ultrasound remains at the level of passive bacterial death despite the initial understanding of its sterilization mechanism. Here, we present the perspective that bacteria can choose to actively enter an apoptosis-like death state in response to external ultrasonic stress. In this study, Vibrio parahaemolyticus exhibited apoptotic markers such as phosphatidylserine ectropion and activated caspases when subjected to ultrasound stress. Additionally, the accumulation of reactive oxygen species (ROS) and enhanced calcium signaling were observed. Further transcriptomic analysis was conducted to investigate the regulatory mechanism of the SOS response in Vibrio parahaemolyticus during an apoptosis-like state. The results showed that the genes encoding the citrate cycle were down-regulated in Vibrio parahaemolyticus cells adapted to ultrasonic stress, leading to an apoptosis-like state and a decrease in production capacity and ability to catabolize carbon dioxide. Furthermore, the level of oxidized glutathione increased, suggesting that the bacteria were engaged in various anti-oxidative stress responses, ultimately leading to apoptosis. Moreover, the ultrasound field activated the regulatory factor CsrA, which facilitates stress survival as cells transition from rapid growth to an apoptotic state through a stringent response and catabolic inhibition system. Parallel reaction monitoring (PRM) revealed that the expression of certain key SOS proteins in Vibrio parahaemolyticus was up-regulated following ultrasound treatment, resulting in a gradual adaptation of the cells to external stress and ultimately leading to active cell death. In conclusion, the biological lethal effect of ultrasound treatment is not solely a mechanical cell necrosis process as traditionally viewed, but also a programmed cell death process regulated by cellular adaptation. This enriched the biological effect pathway of ultrasound sterilization. [ABSTRACT FROM AUTHOR]

Published

2024

102. RecA inhibitor epicatechin prolongs the development of fluoroquinolone resistance in Pasteurella multocida.

Author

Xu, Guanyi, Li, Penghui, Xue, Zhiyang, Qi, Yu, Li, Xuesong, Zhu, Daomi, Ma, Hongxia, and Kong, Lingcong

Subjects

*EPICATECHIN, *CIPROFLOXACIN, *PASTEURELLA multocida, *HIGH throughput screening (Drug development), *DRUG resistance in bacteria, *MOLECULAR docking, *ANTI-infective agents

Abstract

Pasteurella multocida (P. multocida), a primary pathogen of bovine respiratory diseases, has become resistant to many antibiotics, including fluoroquinolones and aminoglycosides. A large number of studies have proved that SOS reaction plays a crucial role in the development of antibiotic resistance. We have shown that the deletion of SOS response-related genes (recA , recO) can delay the development of fluoroquinolone resistance in P. multocida , therefore, it can be used as potential targets for antibiotic resistance inhibitors. In this study, we have used molecular docking to screen RecA protein inhibitors with high throughput screening, and found that epicatechin as an inhibitor significantly inhibited the formation of fluoroquinolone resistance in P. multocida , while in vitro coadministration of epicatechin with and without ciprofloxacin improved the efficacy of the antimicrobial agent. In conclusion, our results indicate that epicatechin is an efficient RecA inhibitor, implying that combining it with ciprofloxacin is a highly promising method for treating P. multocida resistant to fluoroquinolones. [Display omitted] • The combination of epicatechin and ciprofloxacin can reduce ATPase required for the initiation of SOS response of P. multocida and inhibit the occurrence of SOS response. • Epicatechin as an inhibitor significantly inhibited the formation of fluoroquinolone resistance in P. multocida. • Epicatechin acts as an adjuvant for ciprofloxacin, significant efficacy in treating P. multocida in vivo in mouse infection model. [ABSTRACT FROM AUTHOR]

Published

2024

103. SulA does not sequester FtsZ in Escherichia coli cells during the SOS response.

Author

Rumyantseva, Natalia A., Golofeeva, Daria M., and Vedyaykin, Alexey D.

Subjects

*FLUORESCENT proteins, *FLUORESCENCE microscopy, *CELL division, *CELL fusion, *WESTERN immunoblotting

Abstract

In Escherichia coli , the SulA protein is synthesized during the SOS response to arrest cell division. Two possible models of SulA action were proposed: the sequestration and the capping. In current paper, to clarify which model better reflects the SulA effect on cell division upon the SOS response, the FtsZ/SulA ratio was estimated inside cells based on fusion of both FtsZ and SulA to fluorescent protein mNeonGreen. This allowed to quantify this ratio by fluorescence microscopy as well as western blotting; moreover, the effect of SulA on FtsZ distribution patterns in cells was analyzed based on fluorescence microscopy images. The SulA concentration in cells under the SOS response was shown to be several times (about 10) lower than that of FtsZ. The effect of SulA was unequal to corresponding decrease in FtsZ concentration. These results are supported by uneven FtsZ distribution in cells under the SOS response. Together the results of current work indicate that the division arrest by SulA protein in E. coli cells could not be explained by the sequestration model. • FtsZ/SulA ratio is about 10 under the SOS response in E. coli. • SulA action on FtsZ is unequal to corresponding decrease in FtsZ amount. • FtsZ demonstrates uneven distribution in cells under the SOS response. [ABSTRACT FROM AUTHOR]

Published

2024

104. Direct evidence of the ability of Pseudomonas aeruginosa and E. coli SulA to dimerize.

Author

Rumyantseva, N.A., Golofeeva, D.M., Shabalina, A.V., and Vedyaykin, A.D.

Subjects

*ESCHERICHIA coli, *PSEUDOMONAS aeruginosa, *X-ray crystallography, *DIMERIZATION, *CELL division

Abstract

The SulA protein of Escherichia coli and related bacteria interacts directly with FtsZ, blocking cell division by disrupting Z-ring formation, yet the precise mechanism remains not fully understood. Previous demonstrations of Pseudomonas aeruginosa SulA's dimerization capability were confined to X-ray crystallography and lacked confirmation under in vivo conditions. Additionally, uncertainty persisted regarding the dimerization potential of E. coli's SulA protein. This paper employs a bacterial two-hybrid system to establish that both P. aeruginosa and E. coli SulA proteins indeed possess the capacity for dimerization. [Display omitted] • SulA proteins from E. coli and P. aeruginosa are capable of dimerization. • N-terminal fusion of Venus to E. coli SulA impairs dimerization of SulA. • SulA proteins from E. coli and P. aeruginosa demonstrate similar dimerization interfaces. [ABSTRACT FROM AUTHOR]

Published

2024

105. Characterization of a unique repression system present in arbitrium phages of the SPbeta family.

Author

Brady, Aisling, Cabello-Yeves, Elena, Gallego del Sol, Francisca, Chmielowska, Cora, Mancheño-Bonillo, Javier, Zamora-Caballero, Sara, Omer, Shira Bendori, Torres-Puente, Manuela, Eldar, Avigdor, Quiles-Puchalt, Nuria, Marina, Alberto, and Penadés, José R.

Abstract

Arbitrium-coding phages use peptides to communicate and coordinate the decision between lysis and lysogeny. However, the mechanism by which these phages establish lysogeny remains unknown. Here, focusing on the SPbeta phage family's model phages phi3T and SPβ, we report that a six-gene operon called the "SPbeta phages repressor operon" (sro) expresses not one but two master repressors, SroE and SroF, the latter of which folds like a classical phage integrase. To promote lysogeny, these repressors bind to multiple sites in the phage genome. SroD serves as an auxiliary repressor that, with SroEF, forms the repression module necessary for lysogeny establishment and maintenance. Additionally, the proteins SroABC within the operon are proposed to constitute the transducer module, connecting the arbitrium communication system to the activity of the repression module. Overall, this research sheds light on the intricate and specialized repression system employed by arbitrium SPβ-like phages in making lysis-lysogeny decisions. [Display omitted] • SPbeta phages encode two master repressors, SroF and SroE, in the sro operon • Multiple SroF binding sites required for repression and maintenance of lysogeny • The sro operon consists of conserved repressor and variable transducer modules • The transducer module bridges the arbitrium signal to the repression module SPbeta Bacillus phages use arbitrium to coordinate lysis-lysogeny decisions via the sro operon. Brady et al. show that the operon encodes two master repressors that bind multiple sites of the phage genome to promote lysogeny. Three accessory proteins connecting the arbitrium signal to the repression module constitute the transducer module. [ABSTRACT FROM AUTHOR]

Published

2023

106. Bacterial worth in genotoxicity assessment studies.

Author

Mishra, Nidhi and Srivastava, Rashmi

Subjects

*GENETIC toxicology, *DNA repair, *GENETIC engineering, *MOLECULES, *TEST systems, *HAZARDOUS substances, *BIOLOGICAL assay

Abstract

Bacterial-based genotoxicity test systems play a significant role in the detection and evaluation of genotoxicity in vitro and have gained importance due to attributes like wide applicability, speed, high sensitivity, good reproducibility, and simplicity. The Salmonella microsomal mutagenicity assay was created by Ames and colleagues at the beginning of the 1970s, and it was based on the fundamental notion that in auxotrophic bacterial strains with inhibited growth, a mutant gene would revert to its original state on exposure to genotoxicants. This is the most successful and widely used in vitro genotoxicity test. Later, a number of additional test systems that incorporated DNA repair mechanisms including the bacterial SOS response were created. Genetic engineering has further provided significant advancement in these test systems with the development of highly sophisticated bacterial tester strains with significantly increased sensitivity to evaluate the chemical nature of hazardous substances and pollutants. These bacterial bioassays render an opportunity to detect the defined effects of compounds at the molecular level. In this review, all the aspects related to the bacterial system in genotoxicity assessment have been summarized and their role is elaborated concerning real-time requirements and future perspectives. • Bacteria have always been worthy in biological research. • Bacterial genotoxicity assays are cost-effective and highly sensitive in vitro assays. • These assays have been categorized into reverse/forward mutation, DNA repair deficiency, and promoter–reporter test systems. • These bacterial bioassays render an opportunity to detect the defined effects of compounds at the molecular level. • Further advancements are heading toward the development of bacterial sensor systems like lux biosensors. [ABSTRACT FROM AUTHOR]

Published

2023

107. Interplay between Sublethal Aminoglycosides and Quorum Sensing: Consequences on Survival in V. cholerae

Author

André Carvalho, Evelyne Krin, Chloé Korlowski, Didier Mazel, and Zeynep Baharoglu

Subjects

quorum sensing, aminoglycosides, SOS response, Vibrio cholerae, bacterial signaling, antibiotic tolerance, Cytology, QH573-671

Abstract

Antibiotics are well known drugs which, when present above certain concentrations, are able to inhibit the growth of certain bacteria. However, a growing body of evidence shows that even when present at lower doses (subMIC, for sub-minimal inhibitory concentration), unable to inhibit or affect microbial growth, antibiotics work as signaling molecules, affect gene expression and trigger important bacterial stress responses. However, how subMIC antibiotic signaling interplays with other well-known signaling networks in bacteria (and the consequences of such interplay) is not well understood. In this work, through transcriptomic and genetic approaches, we have explored how quorum-sensing (QS) proficiency of V. cholerae affects this pathogen’s response to subMIC doses of the aminoglycoside tobramycin (TOB). We show that the transcriptomic signature of V. cholerae in response to subMIC TOB depends highly on the presence of QS master regulator HapR. In parallel, we show that subMIC doses of TOB are able to negatively interfere with the AI-2/LuxS QS network of V. cholerae, which seems critical for survival to aminoglycoside treatment and TOB-mediated induction of SOS response in this species. This interplay between QS and aminoglycosides suggests that targeting QS signaling may be a strategy to enhance aminoglycoside efficacy in V. cholerae.

Published

2021

108. Contribution of SOS genes to H2O2-induced apoptosis-like death in Escherichia coli

Author

Kim, Heesu and Lee, Dong Gun

Published

2021

109. Spatial and temporal organization of RecA in the Escherichia coli DNA-damage response

Author

Harshad Ghodke, Bishnu P Paudel, Jacob S Lewis, Slobodan Jergic, Kamya Gopal, Zachary J Romero, Elizabeth A Wood, Roger Woodgate, Michael M Cox, and Antoine M van Oijen

Subjects

SOS response, RecA, DNA damage, DNA repair intermediates, live cell imaging, single molecule imaging, Medicine, Science, Biology (General), QH301-705.5

Abstract

The RecA protein orchestrates the cellular response to DNA damage via its multiple roles in the bacterial SOS response. Lack of tools that provide unambiguous access to the various RecA states within the cell have prevented understanding of the spatial and temporal changes in RecA structure/function that underlie control of the damage response. Here, we develop a monomeric C-terminal fragment of the λ repressor as a novel fluorescent probe that specifically interacts with RecA filaments on single-stranded DNA (RecA*). Single-molecule imaging techniques in live cells demonstrate that RecA is largely sequestered in storage structures during normal metabolism. Upon DNA damage, the storage structures dissolve and the cytosolic pool of RecA rapidly nucleates to form early SOS-signaling complexes, maturing into DNA-bound RecA bundles at later time points. Both before and after SOS induction, RecA* largely appears at locations distal from replisomes. Upon completion of repair, RecA storage structures reform.

Published

2019

110. Protozoan predation enhances stress resistance and antibiotic tolerance in Burkholderia cenocepacia by triggering the SOS response.

Author

Morón Á, Tarhouchi AE, Belinchón I, Valenzuela JM, de Francisco P, Martín-González A, and Amaro F

Subjects

Animals, Humans, SOS Response, Genetics, Predatory Behavior, Oxidative Stress, Anti-Bacterial Agents pharmacology, Burkholderia cenocepacia genetics

Abstract

Bacterivorous protists are thought to serve as training grounds for bacterial pathogens by subjecting them to the same hostile conditions that they will encounter in the human host. Bacteria that survive intracellular digestion exhibit enhanced virulence and stress resistance after successful passage through protozoa but the underlying mechanisms are unknown. Here we show that the opportunistic pathogen Burkholderia cenocepacia survives phagocytosis by ciliates found in domestic and hospital sink drains, and viable bacteria are expelled packaged in respirable membrane vesicles with enhanced resistance to oxidative stress, desiccation, and antibiotics, thereby contributing to pathogen dissemination in the environment. Reactive oxygen species generated within the protozoan phagosome promote the formation of persisters tolerant to ciprofloxacin by activating the bacterial SOS response. In addition, we show that genes encoding antioxidant enzymes are upregulated during passage through ciliates increasing bacterial resistance to oxidative radicals. We prove that suppression of the SOS response impairs bacterial intracellular survival and persister formation within protists. This study highlights the significance of protozoan food vacuoles as niches that foster bacterial adaptation in natural and built environments and suggests that persister switch within phagosomes may be a widespread phenomenon in bacteria surviving intracellular digestion., (© The Author(s) 2024. Published by Oxford University Press on behalf of the International Society for Microbial Ecology.)

Published

2024

111. Advancement of the 5-Amino-1-(Carbamoylmethyl)-1H-1,2,3-Triazole-4-Carboxamide Scaffold to Disarm the Bacterial SOS Response

Author

Trevor Selwood, Brian J. Larsen, Charlie Y. Mo, Matthew J. Culyba, Zachary M. Hostetler, Rahul M. Kohli, Allen B. Reitz, and Simon D. P. Baugh

Subjects

SOS response, antibiotic resistance, structure activity analysis, Pseudomonas aeruginosa, DNA damage, Microbiology, QR1-502

Abstract

Many antibiotics, either directly or indirectly, cause DNA damage thereby activating the bacterial DNA damage (SOS) response. SOS activation results in expression of genes involved in DNA repair and mutagenesis, and the regulation of the SOS response relies on two key proteins, LexA and RecA. Genetic studies have indicated that inactivating the regulatory proteins of this response sensitizes bacteria to antibiotics and slows the appearance of resistance. However, advancement of small molecule inhibitors of the SOS response has lagged, despite their clear promise in addressing the threat of antibiotic resistance. Previously, we had addressed this deficit by performing a high throughput screen of ∼1.8 million compounds that monitored for inhibition of RecA-mediated auto-proteolysis of Escherichia coli LexA, the reaction that initiates the SOS response. In this report, the refinement of the 5-amino-1-(carbamoylmethyl)-1H-1,2,3-triazole-4-carboxamide scaffold identified in the screen is detailed. After development of a modular synthesis, a survey of key activity determinants led to the identification of an analog with improved potency and increased breadth, targeting auto-proteolysis of LexA from both E. coli and Pseudomonas aeruginosa. Comparison of the structure of this compound to those of others in the series suggests structural features that may be required for activity and cross-species breadth. In addition, the feasibility of small molecule modulation of the SOS response was demonstrated in vivo by the suppression of the appearance of resistance. These structure activity relationships thus represent an important step toward producing Drugs that Inhibit SOS Activation to Repress Mechanisms Enabling Resistance (DISARMERs).

Published

2018

112. Funkcija in molekularni mehanizmi malih proteinov pri uravnavanju odziva SOS bakterij na poškodbe genomske DNA

Author

Pavlin, Anja and Butala, Matej

Subjects

resistance, SOS response, bacteriophage, odpornost, coregulator, polylysogeny, Bacillus thuringiensis, odziv SOS, polilizogenija, koregulator, bakteriofag, LexA

Abstract

Porast bakterijskih patogenov, odpornih proti več antibiotikom, je velik zdravstveni problem. Ker novih antibiotikov ni lahko najti, se veliko raziskav usmerja v iskanje možnosti za povečanje učinkovitosti že znanih antibiotikov. Številni antibiotiki v subinhibitornih koncentracijah izzovejo poškodbe DNA v bakterijah. Te v odgovor na poškodovano DNA sprožijo odziv SOS, pri katerem najprej sintetizirajo encime, ki natančno popravijo DNA. Ob hujših poškodbah DNA, če te niso bile odpravljene, pa se kasneje v odzivu SOS zgodi sinteza mutagenih DNA-polimeraz, ki omogočajo popravljanje DNA, podvrženo napakam. Tako uvedene mutacije v bakterijskem genomu pa lahko vodijo do razvoja odpornosti proti antibiotikom. Dolgo je veljala predpostavka, da sta transkripcijski faktor LexA in protein RecA edina regulatorja odziva SOS. Nedavno je bilo dokazano, da bakteriofag GIL01, ki okužuje bakterijo Bacillus thuringiensis serovar israelenis, nosi zapis za mali protein gp7, ki se neposredno veže z represorjem LexA in zveča njegovo afiniteto do tarčnih nukleotidnih zaporedij. Prepoznava funkcije proteina gp7 je spodbudila teorijo o obstoju malih proteinov, ki delujejo kot koregulatorji LexA in s tem zagotavljajo dodatno raven regulacije odziva SOS. V doktorskem delu smo dokazali, da je protein gp7 globalni regulator prepisa genov v bakteriji B. thuringiensis, saj zavira prepis 1,2 % bakterijskih genov. Naši rezultati so pokazali, da je gp7 ključni dejavnik za inhibicijo prehoda faga pBtic235, ki z GIL01 sobiva v bakteriji, v litični cikel. Protein gp7 tako zagotovi fagu GIL01, da po poškodbi DNA proizvede več potomcev kot fag pBtic235. Razrešili smo mehanizem delovanja proteina gp7, ki z vezavo na LexA reorientira DNA-vezavni domeni v dimeru LexA v konformacijo, potrebno za vezavo na DNA, kar zviša afiniteto represorja LexA do DNA. Naši rezultati dokazujejo obstoj po funkciji podobnih proteinov, kot je protein gp7, tudi v drugih bakterijah: (i) homologov gp7 nekaterih drugih tektivirusov, ki okužujejo bakterije iz skupine Bacillus cereus sensu lato, in (ii) proteina DdrR bakterije Acinetobater baumannii. Naši rezultati torej nakazujejo obstoj malih proteinov s podobnim delovanjem, kot ga ima gp7, tudi v drugih bakterijah, ki kot koregulatorji LexA in LexA podobnih proteinov predstavljajo dodatno raven uravnavanja prepisa genov v odzivu SOS. The increase in bacterial pathogens resistant to multiple antibiotics is a major health problem. Since new antibiotics are not easy to find, much of the research is focused on finding ways to increase the effectiveness of already known antibiotics. At subinhibitory concentrations, many antibiotics induce DNA damage in bacteria. In response to the damaged DNA, bacteria initiate a SOS response in which they first produce enzymes that precisely repair the DNA. In the case of severe DNA damage, and later in the SOS response, if the DNA damage has not been repaired, synthesis of error-prone DNA polymerases occurs that support replicative bypass of damaged bases that arrest high-fidelity repair. Mutations introduced into the bacterial genome in this manner can lead to the development of antibiotic resistance. For a long time, it was assumed that the transcription factor LexA and the protein RecA were the only regulators of the SOS response. Recently, it was shown that the bacteriophage GIL01 infecting Bacillus thuringiensis serovar israelenis carries a gene for the small protein gp7 that binds directly to the LexA repressor and increases its affinity for target nucleotide sequences. Recognition of the gp7 protein suggested the existence of small proteins that act as coregulators of LexA, providing an additional level of regulation of the SOS response. In this dissertation, we demonstrated that the gp7 protein is a global regulator of gene transcription in the bacterium B. thuringiensis, as it inhibits the transcription of 1.2 % of bacterial genes. Our results show that gp7 is the key factor that inhibits the transition of phage pBtic235, which coexists with GIL01 in the bacterium, into the lytic cycle. Thus, the gp7 protein ensures that the phage GIL01 produces more progeny than the phage pBtic235 after DNA damage. We have elucidated the mechanism of action of the gp7 protein, which, by binding to LexA, reorients the DNA binding domain of the LexA dimer into the conformation required for binding to DNA, which increases the affinity of the LexA repressor for DNA. Our results show that functionally similar proteins, such as the gp7 protein, exist in other bacteria: (i) gp7 homologs of other tectiviruses infecting bacteria from the group Bacillus cereus sensu lato and (ii) the DdrR protein of the bacterium Acinetobater baumannii. Thus, our results suggest the existence of small proteins with a similar function to gp7 in other bacteria as well, which, as co-regulators of LexA and LexA-like proteins, represent an additional level of regulation of gene transcription in the SOS response.

Published

2023

113. Identifikacija molekul, ki inhibirajo aktivnost proteina LexA bakterij Escherichia coli ali Staphylococcus aureus

Author

Halas, Barbara and Butala, Matej

Subjects

Staphylococcus aureus, SOS response, gp8, LexA repressor, udc:577, Escherichia coli, Bacillus thuringiensis, odziv SOS, SPR, LexA represor, OrbA, Vibrio cholerae

Abstract

Odziv SOS pri bakterijah se sproži ob poškodbah DNA in bakteriji omogoči, da ohrani integriteto lastnega genoma. Poglavitni regulator odziva je transkripcijski faktor LexA, ki z vezavo na promotorska področja prepreči prepis genov, katerih produkti so vključeni v popravilo DNA. Genom bakteriofaga GIL01 vključuje gen za protein gp7, ki se veže s proteinom LexA bakterije Bacillus thuringiensis. Protein gp7 zveča afiniteto LexA do specifičnih nukleotidnih zaporedij in inhibira s proteinom RecA sproženo inaktivacijo LexA. Posledično protein gp7 vpliva na aktivacijo odziva SOS, kar potencialno zavre prilagoditev bakterij na stresne razmere v okolju, tudi pridobitev odpornosti proti antibiotikom. Namen magistrskega dela je bil prepoznati molekule, ki vplivajo na delovanje represorja LexA, podobno kot protein gp7. V ta namen smo izolirali protein gp8 temperatnega bakteriofaga GIL01 bakterije B. thuringiensis in protein OrbA temperatnega bakteriofaga ICP1 bakterije Vibrio cholerae. Rezultati nakazujejo, da se izolirana rekombinantna proteina ne vežeta s proteinom LexA gostiteljske bakterije in ne vplivata na cepitev proteina LexA. V nadaljevanju smo analizirali vpliv nekaterih izbranih malih molekul, pridobljenih iz laboratorija prof. dr. Stanislava Gobca iz Fakultete za farmacijo, na aktivnost LexA. Z uporabo površinske plazmonske resonance smo dokazali, da se učinkovina 6-hidroksiflavon (U5) s šibko afiniteto veže s proteinom LexA bakterij Escherichia coli in Staphylococcus aureus ter inhibira vezavo LexA bakterije E. coli na DNA. S poskusi in vivo, v tekoči kulturi, smo dokazali, da dodatek U5 upočasni rast bakterijske kulture E. coli ΔacrB in deluje sinergistično z antibiotikom ciprofloksacin. Učinkovina U5 je šibko zavrla tudi rast seva E. coli RW542, ki ima okvarjen gen za LexA in okvarjen promotorski element gena sulA, zato predvidevamo, da U5 inhibitorno vpliva tudi na procese, ki niso del odziva SOS. SOS response in bacteria is triggered upon DNA damage. It enables bacteria to maintain the integrity of their genome. The key regulator of the SOS response is the transcription factor LexA. LexA binds to promoter regions and represses the induction of SOS genes involved in DNA damage repair. The bacteriophage GIL01 encodes the gp7 protein, which interacts with LexA from the bacterium Bacillus thuringiensis. The gp7 protein increases the affinity of LexA for target DNA sites and inhibits RecA-induced self-cleavage of LexA. Therefore, the gp7 protein affects the induction of the SOS response which presumably inhibits the adaptation of bacteria to harsh environmental conditions, such as antibiotic stress. The aim of this work was to identify molecules that have the potential to affect the activities of LexA, similar to the gp7 protein. Therefore, we purified the recombinant proteins: the gp8 protein of the temperate bacteriophage GIL01, which infects the bacterium B. thuringiensis and the recombinant protein OrbA of the bacteriophage ICP1 that infects bacterium Vibrio cholerae. Our results indicate that the OrbA and gp8 proteins do not interact with the protein LexA of the host bacterium and do not affect the self-cleavage activity of LexA. Next, we tested the effect of selected small compounds that we obtained from the laboratory of Prof. Dr. Stanislav Gobec of the Faculty of Pharmacy, on LexA activity. Using surface plasmon resonance spectroscopy, we showed that the molecule 6-hydroxyflavone (U5) has a low affinity for the LexA protein of Escherichia coli and Staphylococcus aureus and inhibits the binding of LexA from E. coli to the target DNA sites. Using in vivo experiments, we demonstrated that U5 inhibits the growth of the E. coli ΔacrB strain and acts synergistically with the antibiotic ciprofloxacin. Furthermore, the molecule U5 weakly inhibited the growth of strain E. coli RW542, which carries the frameshift mutation in the lexA gene and the deleted promoter element of the sulA gene. Therefore, we hypothesize that compound U5 also affects processes other than the SOS response.

Published

2023

114. Dissecting the RecA-(In)dependent Response to Mitomycin C in Mycobacterium tuberculosis Using Transcriptional Profiling and Proteomics Analyses

Author

Anna Brzostek, Przemysław Płociński, Alina Minias, Aneta Ciszewska, Filip Gąsior, Jakub Pawełczyk, Bożena Dziadek, Marcin Słomka, and Jarosław Dziadek

Subjects

DNA damage repair, SOS response, tuberculosis, Cytology, QH573-671

Abstract

Mycobacteria exploit at least two independent global systems in response to DNA damage: the LexA/RecA-dependent SOS response and the PafBC-regulated pathway. Intracellular pathogens, such as Mycobacterium tuberculosis, are exposed to oxidative and nitrosative stress during the course of infection while residing inside host macrophages. The current understanding of RecA-independent responses to DNA damage is based on the saprophytic model of Mycobacterium smegmatis, a free-living and nonpathogenic mycobacterium. The aim of the present study was to identify elements of RecA-independent responses to DNA damage in pathogenic intracellular mycobacteria. With the help of global transcriptional profiling, we were able to dissect RecA-dependent and RecA-independent pathways. We profiled the DNA damage responses of an M. tuberculosis strain lacking the recA gene, a strain with an undetectable level of the PafBC regulatory system, and a strain with both systems tuned down simultaneously. RNA-Seq profiling was correlated with the evaluation of cell survival in response to DNA damage to estimate the relevance of each system to the overall sensitivity to genotoxic agents. We also carried out whole-cell proteomics analysis of the M. tuberculosis strains in response to mitomycin C. This approach highlighted that LexA, a well-defined key element of the SOS system, is proteolytically inactivated during RecA-dependent DNA repair, which we found to be transcriptionally repressed in response to DNA-damaging agents in the absence of RecA. Proteomics profiling revealed that AlkB was significantly overproduced in the ΔrecA pafBCCRISPRi/dCas9 strain and that Holliday junction resolvase RuvX was a DNA damage response factor that was significantly upregulated regardless of the presence of functional RecA and PafBC systems, thus falling into a third category of DNA damage factors: RecA- and PafBC-independent. While invisible to the mass spectrometer, the genes encoding alkA, dnaB, and dnaE2 were significantly overexpressed in the ΔrecA pafBCCRISPRi/dCas9 strain at the transcript level.

Published

2021

115. Coexistence of SOS-Dependent and SOS-Independent Regulation of DNA Repair Genes in Radiation-Resistant Deinococcus Bacteria

Author

Laurence Blanchard and Arjan de Groot

Subjects

Deinococcus, radiation resistance, DNA repair, SOS response, SOS mutagenesis, translesion polymerase, Cytology, QH573-671

Abstract

Deinococcus bacteria are extremely resistant to radiation and able to repair a shattered genome in an essentially error-free manner after exposure to high doses of radiation or prolonged desiccation. An efficient, SOS-independent response mechanism to induce various DNA repair genes such as recA is essential for radiation resistance. This pathway, called radiation/desiccation response, is controlled by metallopeptidase IrrE and repressor DdrO that are highly conserved in Deinococcus. Among various Deinococcus species, Deinococcus radiodurans has been studied most extensively. Its genome encodes classical DNA repair proteins for error-free repair but no error-prone translesion DNA polymerases, which may suggest that absence of mutagenic lesion bypass is crucial for error-free repair of massive DNA damage. However, many other radiation-resistant Deinococcus species do possess translesion polymerases, and radiation-induced mutagenesis has been demonstrated. At least dozens of Deinococcus species contain a mutagenesis cassette, and some even two cassettes, encoding error-prone translesion polymerase DnaE2 and two other proteins, ImuY and ImuB-C, that are probable accessory factors required for DnaE2 activity. Expression of this mutagenesis cassette is under control of the SOS regulators RecA and LexA. In this paper, we review both the RecA/LexA-controlled mutagenesis and the IrrE/DdrO-controlled radiation/desiccation response in Deinococcus.

Published

2021

116. Genome-Wide Identification and Expression Analysis of SOS Response Genes in Salmonella enterica Serovar Typhimurium

Author

Angela Mérida-Floriano, Will P. M. Rowe, and Josep Casadesús

Subjects

SOS response, LexA, LexA box, heterology index, phenotypic heterogeneity, Cytology, QH573-671

Abstract

A bioinformatic search for LexA boxes, combined with transcriptomic detection of loci responsive to DNA damage, identified 48 members of the SOS regulon in the genome of Salmonella enterica serovar Typhimurium. Single cell analysis using fluorescent fusions revealed that heterogeneous expression is a common trait of SOS response genes, with formation of SOSOFF and SOSON subpopulations. Phenotypic cell variants formed in the absence of external DNA damage show gene expression patterns that are mainly determined by the position and the heterology index of the LexA box. SOS induction upon DNA damage produces SOSOFF and SOSON subpopulations that contain live and dead cells. The nature and concentration of the DNA damaging agent and the time of exposure are major factors that influence the population structure upon SOS induction. An analogy can thus be drawn between the SOS response and other bacterial stress responses that produce phenotypic cell variants.

Published

2021

117. Elevated Expression of Toxin TisB Protects Persister Cells against Ciprofloxacin but Enhances Susceptibility to Mitomycin C

Author

Daniel Edelmann, Florian H. Leinberger, Nicole E. Schmid, Markus Oberpaul, Till F. Schäberle, and Bork A. Berghoff

Subjects

toxin-antitoxin systems, DNA damage, SOS response, fluoroquinolones, mitomycin C, persistence, Biology (General), QH301-705.5

Abstract

Bacterial chromosomes harbor toxin-antitoxin (TA) systems, some of which are implicated in the formation of multidrug-tolerant persister cells. In Escherichia coli, toxin TisB from the tisB/istR-1 TA system depolarizes the inner membrane and causes ATP depletion, which presumably favors persister formation. Transcription of tisB is induced upon DNA damage due to activation of the SOS response by LexA degradation. Transcriptional activation of tisB is counteracted on the post-transcriptional level by structural features of tisB mRNA and RNA antitoxin IstR-1. Deletion of the regulatory RNA elements (mutant Δ1-41 ΔistR) uncouples TisB expression from LexA-dependent SOS induction and causes a ‘high persistence’ (hip) phenotype upon treatment with different antibiotics. Here, we demonstrate by the use of fluorescent reporters that TisB overexpression in mutant Δ1-41 ΔistR inhibits cellular processes, including the expression of SOS genes. The failure in SOS gene expression does not affect the hip phenotype upon treatment with the fluoroquinolone ciprofloxacin, likely because ATP depletion avoids strong DNA damage. By contrast, Δ1-41 ΔistR cells are highly susceptible to the DNA cross-linker mitomycin C, likely because the expression of SOS-dependent repair systems is impeded. Hence, the hip phenotype of the mutant is conditional and strongly depends on the DNA-damaging agent.

Published

2021

118. A phylogenomic study of DNA repair genes, proteins, and processes

Author

Eisen, Jonathan A and Hanawalt, Philip C

Subjects

Microbiology, Biological Sciences, Bioinformatics and Computational Biology, Genetics, Adenosine Triphosphatases, Alkylation, Bacterial Proteins, Base Pair Mismatch, DNA Damage, DNA Glycosylases, DNA Helicases, DNA Ligases, DNA Nucleotidyltransferases, DNA Repair, DNA Replication, DNA, Bacterial, DNA-Binding Proteins, DNA-Formamidopyrimidine Glycosylase, Deoxyribonuclease (Pyrimidine Dimer), Deoxyribonucleases, Endodeoxyribonucleases, Escherichia coli Proteins, Eukaryotic Cells, Exodeoxyribonuclease V, Exodeoxyribonucleases, Exonucleases, Genes, Bacterial, Genes, p53, Genome, Genome, Archaeal, Integrases, Multigene Family, N-Glycosyl Hydrolases, Phylogeny, Rad52 DNA Repair and Recombination Protein, Recombinases, Recombination, Genetic, SOS Response, Genetics, Serine Endopeptidases, Uracil-DNA Glycosidase, DNA repair, molecular evolution, phylogenomics, gene duplication and gene loss, orthology and paralogy, comparative genomics, Oncology & Carcinogenesis

Abstract

The ability to recognize and repair abnormal DNA structures is common to all forms of life. Studies in a variety of species have identified an incredible diversity of DNA repair pathways. Documenting and characterizing the similarities and differences in repair between species has important value for understanding the origin and evolution of repair pathways as well as for improving our understanding of phenotypes affected by repair (e.g., mutation rates, lifespan, tumorigenesis, survival in extreme environments). Unfortunately, while repair processes have been studied in quite a few species, the ecological and evolutionary diversity of such studies has been limited. Complete genome sequences can provide potential sources of new information about repair in different species. In this paper, we present a global comparative analysis of DNA repair proteins and processes based upon the analysis of available complete genome sequences. We use a new form of analysis that combines genome sequence information and phylogenetic studies into a composite analysis we refer to as phylogenomics. We use this phylogenomic analysis to study the evolution of repair proteins and processes and to predict the repair phenotypes of those species for which we now know the complete genome sequence.

Published

1999

119. The SOS system: A complex and tightly regulated response to DNA damage.

Author

Maslowska, Katarzyna H., Makiela‐Dzbenska, Karolina, and Fijalkowska, Iwona J.

Subjects

DNA damage, ESCHERICHIA coli, MUTAGENS, GENOMES, DNA replication, MUTAGENESIS

Abstract

Genomes of all living organisms are constantly threatened by endogenous and exogenous agents that challenge the chemical integrity of DNA. Most bacteria have evolved a coordinated response to DNA damage. In Escherichia coli, this inducible system is termed the SOS response. The SOS global regulatory network consists of multiple factors promoting the integrity of DNA as well as error‐prone factors allowing for survival and continuous replication upon extensive DNA damage at the cost of elevated mutagenesis. Due to its mutagenic potential, the SOS response is subject to elaborate regulatory control involving not only transcriptional derepression, but also post‐translational activation, and inhibition. This review summarizes current knowledge about the molecular mechanism of the SOS response induction and progression and its consequences for genome stability. Environ. Mol. Mutagen. 60:368–384, 2019. © 2018 The Authors. Environmental and Molecular Mutagenesis published by Wiley Periodicals, Inc. on behalf of Environmental Mutagen Society. [ABSTRACT FROM AUTHOR]

Published

2019

120. Ordering up gene expression by slowing down transcription factor binding kinetics.

Author

Culyba, Matthew J.

Subjects

*GENE expression, *TRANSCRIPTION factors, *GENE regulatory networks

Abstract

Efficient regulation of a complex genetic response requires that the gene products, which catalyze the response, be synthesized in a temporally ordered manner to match the sequential nature of the reaction pathway they act upon. Transcription regulation networks coordinate this aspect of cellular control by modulating transcription factor (TF) concentrations through time. The effect a TF has on the timing of gene expression is often modeled assuming that the TF-promoter binding reaction is in thermodynamic equilibrium with changes in TF concentration over time; however, non-equilibrium dynamics resulting from relatively slow TF-binding kinetics can result in different network behavior. Here, I highlight a recent study of the bacterial SOS response, where a single TF regulates multiple target promoters, to show how a disequilibrium of TF binding at promoters results in a more complex behavior, enabling a larger temporal separation of promoter activities that depends not only upon slow TF binding kinetics at promoters, but also on the magnitude of the response stimulus. I also discuss the dependence of network behavior on specific TF regulatory mechanisms and the implications non-equilibrium dynamics have for stochastic gene expression. [ABSTRACT FROM AUTHOR]

Published

2019

121. The response of Escherichia coli to the alkylating agents chloroacetaldehyde and styrene oxide.

Author

Muenter, Mark M., Aiken, Ariel, Akanji, Jadesola O., Baig, Samir, Bellou, Sirine, Carlson, Alyssa, Conway, Charles, Cowell, Courtney M., DeLateur, Nicholas A., Hester, Alexis, Joshi, Christopher, Kramer, Caitlin, Leifer, Becky S., Nash, Emma, Qi, Macee H., Travers, Meghan, Wong, Kelly C., Hu, Man, Gou, Na, and Giese, Roger W.

Subjects

*PHYSIOLOGICAL stress, *ALKYLATING agents, *DNA damage, *DNA repair, *STYRENE oxide, *CHLOROACETALDEHYDE, *REPORTER genes, *ESCHERICHIA coli

Abstract

Graphical abstract Highlights • Numerous stress responses are induced by chloroacetaldehyde and styrene oxide. • DNA damage is most prominent category of stress responses. • Strains lacking recA, ruvA , and ybfE are sensitive to chloroacetaldehyde. • Strains lacking recA , mutM , nfo , uvrA , uvrD , ybfE are sensitive to styrene oxide. Abstract DNA damage is ubiquitous and can arise from endogenous or exogenous sources. DNA-damaging alkylating agents are present in environmental toxicants as well as in cancer chemotherapy drugs and are a constant threat, which can lead to mutations or cell death. All organisms have multiple DNA repair and DNA damage tolerance pathways to resist the potentially negative effects of exposure to alkylating agents. In bacteria, many of the genes in these pathways are regulated as part of the SOS reponse or the adaptive response. In this work, we probed the cellular responses to the alkylating agents chloroacetaldehyde (CAA), which is a metabolite of 1,2-dichloroethane used to produce polyvinyl chloride, and styrene oxide (SO), a major metabolite of styrene used in the production of polystyrene and other polymers. Vinyl chloride and styrene are produced on an industrial scale of billions of kilograms annually and thus have a high potential for environmental exposure. To identify stress response genes in E. coli that are responsible for tolerance to the reactive metabolites CAA and SO, we used libraries of transcriptional reporters and gene deletion strains. In response to both alkylating agents, genes associated with several different stress pathways were upregulated, including protein, membrane, and oxidative stress, as well as DNA damage. E. coli strains lacking genes involved in base excision repair and nucleotide excision repair were sensitive to SO, whereas strains lacking recA and the SOS gene ybfE were sensitive to both alkylating agents tested. This work indicates the varied systems involved in cellular responses to alkylating agents, and highlights the specific DNA repair genes involved in the responses. [ABSTRACT FROM AUTHOR]

Published

2019

122. Using mRNA to investigate the effect of low-pressure ultraviolet disinfection on the viability of E. coli.

Author

Yang, Chao, Sun, Wenjun, and Ao, Xiuwei

Published

2019

123. SOS genes contribute to Bac8c induced apoptosis-like death in Escherichia coli.

Author

Lee, Heejeong and Lee, Dong Gun

Subjects

*PEPTIDE antibiotics, *ANTI-infective agents, *ESCHERICHIA coli, *APOPTOSIS, *CELL death, *PROTEOLYSIS

Abstract

Abstract Antimicrobial peptides are one of the promising substitutes for conventional antibiotics. To examine their potential usefulness for controlling bacterial infections, the present study aimed to determine the induction of the self-destruction of Escherichia coli mediated by bac8c, which was modified from template peptide bactenecin. The potential of bac8c (RIWVIWRR) was reflected by the change in physiological following exposure, which led to the accumulation of reactive oxygen species (ROS) with an imbalance in the antioxidant system and damage to the intracellular lipids. In addition, bac8c-mediated death exhibited typical features to bacterial apoptosis-like death (ALD). The pathway was not enhanced in the absence of autocleavage of RecA and LexA, the SOS response proteins. We observed that elevated levels of intracellular ROS induced ALD, but this effect was insufficient before preceding RecA activation and LexA autocleavage. Furthermore, dinF , which encodes a member of the toxic compound extrusion (MATE) family, was evaluated to examine the role of the ALD pathway. dinF protein was required to accelerate the ALD-mediated bac8c in combination with RecA. Taken together, bac8c-mediated cell death underlies the severe SOS response, leading to RecA activation, LexA proteolysis, and dinF overexpression. Since then, overproduction of intracellular ROS facilitated the cell death. Highlights • Antimicrobial peptide bac8c (RIWVIWRR) causes Escherichia coli apoptosis-like death (ALD). • Bac8c leads to reactive oxygen species accumulation and intracellular damage. • Bac8c-induced cell death stimulates SOS response genes. • Bac8c induces death by RecA activation, LexA proteolysis, and dinF overexpression. [ABSTRACT FROM AUTHOR]

Published

2019

124. Arenicin-1-induced apoptosis-like response requires RecA activation and hydrogen peroxide against Escherichia coli.

Author

Lee, Heejeong and Lee, Dong Gun

Subjects

*ESCHERICHIA coli, *HYDROGEN peroxide, *CELL death, *DNA damage, *CASPASES

Abstract

Arenicin-1, a 21-mer antimicrobial peptide exerts significant broad-spectrum antimicrobial activity with membrane-active mechanisms. However, owing to multiple mechanisms of cell death, the antibacterial mechanism of arenicin-1 requires detailed analysis. In the present study, arenicin-1-treated bacteria underwent an apoptosis-like response, which was mechanistically and morphologically similar to eukaryotic apoptosis. Changes in the physiological status of arenicin-1-treated bacterial cells involved accumulation of reactive oxygen species, imbalance of intracellular calcium gradients, disruption of membrane potential, bacterial caspase-like protein activation, and DNA damage. In arenicin-1-induced apoptosis-like death, autocleavage of LexA was observed because of the activation of the caspase-like activity of RecA. Additionally, typical reactive oxygen species such as superoxide, hydrogen peroxide, and hydroxyl radicals, were scavenged in arenicin-1-treated cells to assess the role of specific reactive oxygen species. Scavenging of hydrogen peroxide interfered with the activity of arenicin-1 in Escherichia coli, whereas the superoxide and hydroxyl radicals level did not affect arenicin-1-induced apoptosis-like death activity. Furthermore, inhibition of Fenton reaction attenuated apoptosis-like response. In conclusion, arenicin-1-induced apoptosis like death requires SOS response proteins and is mediated by hydrogen peroxide and Fenton reaction in E. coli. Arenicin-1 may be a representative antimicrobial peptide with potent apoptotic response against E. coli. [ABSTRACT FROM AUTHOR]

Published

2019

125. SetRICE391, a negative transcriptional regulator of the integrating conjugative element 391 mutagenic response.

Author

Gonzalez, Martín, Huston, Donald, McLenigan, Mary P., McDonald, John P., Garcia, Audrey M., Borden, Kylie S., and Woodgate, Roger

Subjects

*TRANSCRIPTION factors, *MUTAGENS, *GENETIC repressors, *DNA polymerases, *DNA damage

Abstract

Graphical abstract Highlights • SetR ICE391 is a member of the c I-like family of transcriptional repressors. • Expression of the ICE391 DNA polV ortholog, RumA' 2 B, is repressed by SetR ICE391. • SetR ICE391 activity is specific for rumAB and not related polV orthologs. • SetR ICE391 binding overlaps the -35 region of the rumAB operon promoter. Abstract The integrating conjugative element ICE391 (formerly known as IncJ R391) harbors an error-prone DNA polymerase V ortholog, polV ICE391 , encoded by the ICE391 rumAB operon. polV and its orthologs have previously been shown to be major contributors to spontaneous and DNA damage-induced mutagenesis in vivo. As a result, multiple levels of regulation are imposed on the polymerases so as to avoid aberrant mutagenesis. We report here, that the mutagenesis-promoting activity of polV ICE391 is additionally regulated by a transcriptional repressor encoded by SetR ICE391 , since Escherichia coli expressing SetR ICE391 demonstrated reduced levels of polV ICE391 –mediated spontaneous mutagenesis relative to cells lacking SetR ICE391. SetR ICE391 regulation was shown to be specific for the rumAB operon and in vitro studies with highly purified SetR ICE391 revealed that under alkaline conditions, as well as in the presence of activated RecA, SetR ICE391 undergoes a self-mediated cleavage reaction that inactivates repressor functions. Conversely, a non-cleavable SetR ICE391 mutant capable of maintaining repressor activity, even in the presence of activated RecA, exhibited low levels of polV ICE391 -dependent mutagenesis. Electrophoretic mobility shift assays revealed that SetR ICE391 acts as a transcriptional repressor by binding to a site overlapping the -35 region of the rumAB operon promoter. Our study therefore provides evidence indicating that SetR ICE391 acts as a transcriptional repressor of the ICE391-encoded mutagenic response. [ABSTRACT FROM AUTHOR]

Published

2019

126. Biochemical characterization of Mycobacterium tuberculosis LexA and structural studies of its C‐terminal segment.

Author

Chandran, A. V., Srikalaivani, R., Paul, A., and Vijayan, M.

Subjects

*MYCOBACTERIUM tuberculosis, *C-terminal residues, *OLIGOMERIZATION

Abstract

LexA is a protein that is involved in the SOS response. The protein from Mycobacterium tuberculosis and its mutants have been biochemically characterized and the structures of their catalytic segments have been determined. The protein is made up of an N‐terminal segment, which includes the DNA‐binding domain, and a C‐terminal segment encompassing much of the catalytic domain. The two segments are defined by a cleavage site. Full‐length LexA, the two segments, two point mutants involving changes in the active‐site residues (S160A and K197A) and another mutant involving a change at the cleavage site (G126D) were cloned and purified. The wild‐type protein autocleaves at basic pH, while the mutants do not. The wild‐type and the mutant proteins dimerize and bind DNA with equal facility. The C‐terminal segment also dimerizes, and it also shows a tendency to form tetramers. The C‐terminal segment readily crystallized. The crystals obtained from attempts involving the full‐length protein and its mutants contained only the C‐terminal segment including the catalytic core and a few residues preceding it, in a dimeric or tetrameric form, indicating protein cleavage during the long period involved in crystal formation. Modes of tetramerization of the full‐length protein similar to those observed for the catalytic core are feasible. A complex of M. tuberculosis LexA and the cognate SOS box could be modeled in which the mutual orientation of the two N‐terminal domains differs from that in the Escherichia coli LexA–DNA complex. These results represent the first thorough characterization of M. tuberculosis LexA and provide definitive information on its structure and assembly. They also provide leads for further exploration of this important protein. LexA, a protein that is involved in the SOS response, from Mycobacterium tuberculosis and its mutants have been biochemically characterized and the structures of their catalytic segments have been determined. [ABSTRACT FROM AUTHOR]

Published

2019

127. Nano-metal oxides induce antimicrobial resistance via radical-mediated mutagenesis.

Author

Zhang, Ye, Gu, April Z., Xie, Shanshan, Li, Xiangyang, Cen, Tianyu, Li, Dan, and Chen, Jianmin

Subjects

*ANTI-infective agents, *MUTAGENESIS, *ESCHERICHIA coli, *DRUG resistance in bacteria, *REACTIVE oxygen species

Abstract

Abstract The widespread use of nanoparticles has triggered increasing concern and interest due to the adverse effects on global public health and environmental safety. Whether the presence of nano-metal oxides (NMOs) could facilitate the formation of new antimicrobial resistance genes (ARGs) via de novo mutation is largely unknown. Here, we proved that two widely used NMOs could significantly improve the mutation frequencies of CIP- and CHL-resistant E. coli isolates; however, the corresponding metal ions have weaker effects. Distinct concentration-dependent increases of 1.0–14.2 and 1.1–456.3 folds were observed in the resistance mutations after treatment with 0.16–100 mg/L nano-Al 2 O 3 and 0.16–500 mg/L nano-ZnO, respectively, compared with those in the control. The resistant mutants showed resistance to multiple antibiotics and hereditary stability after sub-culturing for 5 days. We also explored the mechanism underlying the induction of antimicrobial resistance by NMOs. Whole-genome sequencing analysis showed that the mutated genes correlated with mono- and multidrug resistance, as well as undetected resistance to antibiotics. Furthermore, NMOs significantly promoted intracellular reactive oxygen species (ROS), which would lead to oxidative DNA damage and an error-prone SOS response, and consequently, mutation rates were enhanced. Our findings indicate that NMOs could accelerate the mutagenesis of multiple-antibiotic resistance and expanded the understanding of the mechanisms in nanoparticle-induced resistance, which may be significant for guiding the production and application of nanoparticles. Graphical abstract Unlabelled Image Highlights • NMOs can improve the mutation frequencies of CIP- and CHL-resistant E. coli isolates. • NMOs can facilitate the formation of new ARGs via de novo mutation. • Resistant mutants showed resistance to multiple antibiotics and hereditary stability. • Mutated genes correlated with mono- and multidrug resistance. • NMOs induce intracellular ROS, oxidative DNA damage and an error-prone SOS response. [ABSTRACT FROM AUTHOR]

Published

2018

128. Transcriptome Analysis Reveals the Genes Involved in Bifidobacterium Longum FGSZY16M3 Biofilm Formation

Author

Zongmin Liu, Lingzhi Li, Qianwen Wang, Faizan Ahmed Sadiq, Yuankun Lee, Jianxin Zhao, Hao Zhang, Wei Chen, Haitao Li, and Wenwei Lu

Subjects

biofilm, transcriptome, Bifidobacterium longum, protein–protein interaction network, SOS response, WGCNA, Biology (General), QH301-705.5

Abstract

Biofilm formation has evolved as an adaptive strategy for bacteria to cope with harsh environmental conditions. Currently, little is known about the molecular mechanisms of biofilm formation in bifidobacteria. A time series transcriptome sequencing analysis of both biofilm and planktonic cells of Bifidobacterium longum FGSZY16M3 was performed to identify candidate genes involved in biofilm formation. Protein–protein interaction network analysis of 1296 differentially expressed genes during biofilm formation yielded 15 clusters of highly interconnected nodes, indicating that genes related to the SOS response (dnaK, groS, guaB, ruvA, recA, radA, recN, recF, pstA, and sufD) associated with the early stage of biofilm formation. Genes involved in extracellular polymeric substances were upregulated (epsH, epsK, efp, frr, pheT, rfbA, rfbJ, rfbP, rpmF, secY and yidC) in the stage of biofilm maturation. To further investigate the genes related to biofilm formation, weighted gene co-expression network analysis (WGCNA) was performed with 2032 transcript genes, leading to the identification of nine WGCNA modules and 133 genes associated with response to stress, regulation of gene expression, quorum sensing, and two-component system. These results indicate that biofilm formation in B. longum is a multifactorial process, involving stress response, structural development, and regulatory processes.

Published

2021

129. Genome-Wide Identification of Resveratrol Intrinsic Resistance Determinants in Staphylococcus aureus

Author

Liping Liu, Hanne Ingmer, and Martin Vestergaard

Subjects

Staphylococcus aureus, resveratrol, intrinsic resistance, DNA damage, SOS response, Therapeutics. Pharmacology, RM1-950

Abstract

Resveratrol has been extensively studied due to its potential health benefits in multiple diseases, for example, cancer, obesity and cardiovascular diseases. Besides these properties, resveratrol displays inhibitory activity against a wide range of bacterial species; however, the cellular effects of resveratrol in bacteria remain incompletely understood, especially in the human pathogen, Staphylococcus aureus. In this study, we aimed to identify intrinsic resistance genes that aid S. aureus in tolerating the activity of resveratrol. We screened the Nebraska Transposon Mutant Library, consisting of 1920 mutants with inactivation of non-essential genes in S. aureus JE2, for increased susceptibly to resveratrol. On agar plates containing 0.5× the minimum inhibitory concentration (MIC), 17 transposon mutants failed to grow. Of these, four mutants showed a two-fold reduction in MIC, being the clpP protease mutant and three mutants with deficiencies in the electron transport chain (menD, hemB, aroC). The remaining 13 mutants did not show a reduction in MIC, but were confirmed by spot-assays to have increased susceptibility to resveratrol. Several genes were associated with DNA damage repair (recJ, xerC and xseA). Treatment of S. aureus JE2 with sub-inhibitory concentrations of resveratrol did not affect the expression of recJ, xerC and xseA, but increased expression of the SOS–stress response genes lexA and recA, suggesting that resveratrol interferes with DNA integrity in S. aureus. Expression of error-prone DNA polymerases are part of the SOS–stress response and we could show that sub-inhibitory concentrations of resveratrol increased overall mutation frequency as measured by formation of rifampicin resistant mutants. Our data show that DNA repair systems are important determinants aiding S. aureus to overcome the inhibitory activity of resveratrol. Activation of the SOS response by resveratrol could potentially facilitate the development of resistance towards conventional antibiotics in S. aureus.

Published

2021

130. Moxifloxacin Activates the SOS Response in Mycobacterium tuberculosis in a Dose- and Time-Dependent Manner

Author

Angelo Iacobino, Giovanni Piccaro, Manuela Pardini, Lanfranco Fattorini, and Federico Giannoni

Subjects

Mycobacterium tuberculosis, SOS response, DNA repair, fluoroquinolone, moxifloxacin, Biology (General), QH301-705.5

Abstract

Previous studies on Escherichia coli demonstrated that sub-minimum inhibitory concentration (MIC) of fluoroquinolones induced the SOS response, increasing drug tolerance. We characterized the transcriptional response to moxifloxacin in Mycobacterium tuberculosis. Reference strain H37Rv was treated with moxifloxacin and gene expression studied by qRT-PCR. Five SOS regulon genes, recA, lexA, dnaE2, Rv3074 and Rv3776, were induced in a dose- and time-dependent manner. A range of moxifloxacin concentrations induced recA, with a peak observed at 2 × MIC (0.25 μg/mL) after 16 h. Another seven SOS responses and three DNA repair genes were significantly induced by moxifloxacin. Induction of recA by moxifloxacin was higher in log-phase than in early- and stationary-phase cells, and absent in dormant bacilli. Furthermore, in an H37Rv fluoroquinolone-resistant mutant carrying the D94G mutation in the gyrA gene, the SOS response was induced at drug concentrations higher than the mutant MIC value. The 2 × MIC of moxifloxacin determined no significant changes in gene expression in a panel of 32 genes, except for up-regulation of the relK toxin and of Rv3290c and Rv2517c, two persistence-related genes. Overall, our data show that activation of the SOS response by moxifloxacin, a likely link to increased mutation rate and persister formation, is time, dose, physiological state and, possibly, MIC dependent.

Published

2021

131. Strain-Specific Gifsy-1 Prophage Genes Are Determinants for Expression of the RNA Repair Operon during the SOS Response in Salmonella enterica Serovar Typhimurium

Author

Jennifer E. Kurasz, Madison C. Crawford, Steffen Porwollik, Oliver Gregory, Katerina R. Tadlock, Eve C. Balding, Emily E. Weinert, Michael McClelland, Anna C. Karls, and Bondy-Denomy, Joseph

Subjects

Salmonella typhimurium, SOS response, RtcR, Prophages, RNA repair, Serogroup, Medical and Health Sciences, Microbiology, Vaccine Related, sigma54, Bacterial Proteins, Salmonella, Biodefense, Operon, Genetics, Escherichia coli, 2.2 Factors relating to the physical environment, Aetiology, LexA, Molecular Biology, Phylogeny, RpoN, Gifsy prophages, RecA, Agricultural and Veterinary Sciences, Prevention, bacterial enhancer binding protein, E. coli, Salmonella enterica, Biological Sciences, Foodborne Illness, Infectious Diseases, Emerging Infectious Diseases, RNA, transcription regulation, bEBP activation, Transcription Factors

Abstract

The adaptation of Salmonella enterica serovar Typhimurium to stress conditions involves expression of genes within the regulon of the alternative sigma factor RpoN (σ54). RpoN-dependent transcription requires an activated bacterial enhancer binding protein (bEBP) that hydrolyzes ATP to remodel the RpoN-holoenzyme-promoter complex for transcription initiation. The bEBP RtcR in S. Typhimurium strain 14028s is activated by genotoxic stress to direct RpoN-dependent expression of the RNA repair operon rsr-yrlBA-rtcBA. The molecular signal for RtcR activation is an oligoribonucleotide with a 3'-terminal 2',3'-cyclic phosphate. We show in S. Typhimurium 14028s that the molecular signal is not a direct product of nucleic acid damage, but signal generation is dependent on a RecA-controlled SOS-response pathway, specifically, induction of prophage Gifsy-1. A genome-wide mutant screen and utilization of Gifsy prophage-cured strains indicated that the nucleoid-associated protein Fis and the Gifsy-1 prophage significantly impact RtcR activation. Directed-deletion analysis and genetic mapping by transduction demonstrated that a three-gene region (STM14_3218-3220) in Gifsy-1, which is variable between S. Typhimurium strains, is required for RtcR activation in strain 14028s and that the absence of STM14_3218-3220 in the Gifsy-1 prophages of S. Typhimurium strains LT2 and 4/74, which renders these strains unable to activate RtcR during genotoxic stress, can be rescued by complementation in cis by the region encompassing STM14_3218-3220. Thus, even though RtcR and the RNA repair operon are highly conserved in Salmonella enterica serovars, RtcR-dependent expression of the RNA repair operon in S. Typhimurium is controlled by a variable region of a prophage present in only some strains. IMPORTANCE The transcriptional activator RtcR and the RNA repair proteins whose expression it regulates, RtcA and RtcB, are widely conserved in Proteobacteria. In Salmonella Typhimurium 14028s, genotoxic stress activates RtcR to direct RpoN-dependent expression of the rsr-yrlBA-rtcBA operon. This work identifies key elements of a RecA-dependent pathway that generates the signal for RtcR activation in strain 14028s. This signaling pathway requires the presence of a specific region within the prophage Gifsy-1, yet this region is absent in most other wild-type Salmonella strains. Thus, we show that the activity of a widely conserved regulatory protein can be controlled by prophages with narrow phylogenetic distributions. This work highlights an underappreciated phenomenon where bacterial physiological functions are altered due to genetic rearrangement of prophages.

Published

2023

132. Investigating a Potential Link Between Prophage Activation and the DNA Damage Response in the E. coli Long-Term Evolution Experiment

Author

Bhakta, Aneesa

Subjects

Long-Term Evolution Experiment, E. coli, Prophage, SOS Response

Abstract

The Long-Term Evolution Experiment (LTEE) is an open-ended endeavor to understand evolution through one of the simplest and quickest-replicating forms of life: Escherichia coli. Cultured in the lab since 1988, the 12 populations of E. coli in the LTEE have reached over 75,000 generations and accumulated many beneficial mutations in their genomes. One area of interest is a prophage from the P2/186 phage family called Rybb*B. Most prophage regions found in the genome of the ancestor of the LTEE are not functional, but Rybb*B was shown to be inducible by DNA damage. Additionally, past genome sequencing data showed evidence of more than one copy, on average, of the prophage region’s DNA per cell in the ancestor and clonal isolates from early generations, but not in later generations of all 12 LTEE populations. This extra sequencing coverage, as well as the presence of reads supporting a new junction in the DNA suggested that the prophage was stochastically replicating in these strains. However, the reason for the apparent decrease in the prophage copy number in later generations is unknown. I performed experiments to understand these unexplained changes in prophage activation. First, I measured prophage copy number in early strains of the LTEE using quantitative PCR (qPCR). Second, I used a reporter plasmid to test whether changes in the SOS DNA damage response evolved during the LTEE that might have affected stochastic prophage activation. Unlike in prior results, I found that Rybb*B prophage copy number remains relatively consistent throughout the early LTEE strains except for the ancestor which seems to have a higher prophage copy number. I also found that the SOS reporter is induced by azidothymidine similarly in strains from 5000 generations or earlier but does not appear to activate in strains from 10000 generations.

Published

2023

133. Cyclic AMP Regulates Bacterial Persistence through Repression of the Oxidative Stress Response and SOS-Dependent DNA Repair in Uropathogenic Escherichia coli

Author

Roberto C. Molina-Quiroz, Cecilia Silva-Valenzuela, Jennifer Brewster, Eduardo Castro-Nallar, Stuart B. Levy, and Andrew Camilli

Subjects

CRP, DNA damage, SOS response, Tn-Seq, antibiotics, cAMP, Microbiology, QR1-502

Abstract

ABSTRACT Bacterial persistence is a transient, nonheritable physiological state that provides tolerance to bactericidal antibiotics. The stringent response, toxin-antitoxin modules, and stochastic processes, among other mechanisms, play roles in this phenomenon. How persistence is regulated is relatively ill defined. Here we show that cyclic AMP, a global regulator of carbon catabolism and other core processes, is a negative regulator of bacterial persistence in uropathogenic Escherichia coli, as measured by survival after exposure to a β-lactam antibiotic. This phenotype is regulated by a set of genes leading to an oxidative stress response and SOS-dependent DNA repair. Thus, persister cells tolerant to cell wall-acting antibiotics must cope with oxidative stress and DNA damage and these processes are regulated by cyclic AMP in uropathogenic E. coli. IMPORTANCE Bacterial persister cells are important in relapsing infections in patients treated with antibiotics and also in the emergence of antibiotic resistance. Our results show that in uropathogenic E. coli, the second messenger cyclic AMP negatively regulates persister cell formation, since in its absence much more persister cells form that are tolerant to β-lactams antibiotics. We reveal the mechanism to be decreased levels of reactive oxygen species, specifically hydroxyl radicals, and SOS-dependent DNA repair. Our findings suggest that the oxidative stress response and DNA repair are relevant pathways to target in the design of persister-specific antibiotic compounds.

Published

2018

134. Defense Mechanisms Against Oxidative Stress in Coxiella burnetii: Adaptation to a Unique Intracellular Niche

Author

Mertens, Katja, Samuel, James E., Toman, Rudolf, editor, Heinzen, Robert A., editor, Samuel, James E., editor, and Mege, Jean-Louis, editor

Published

2012

135. Molecular Basis of Lysis–Lysogeny Decisions in Gram-Positive Phages

Author

José R. Penadés, Alberto Marina, Nuria Quiles-Puchalt, Francisca Gallego del Sol, Aisling Brady, Alonso Felipe-Ruiz, Medical Research Council (UK), Biotechnology and Biological Sciences Research Council (UK), European Research Council, Generalitat Valenciana, Ministerio de Ciencia, Innovación y Universidades (España), and Ministerio de Economía y Competitividad (España)

Subjects

SOS response, Genetic switch, Arbitrium, Life cycle, viruses, Biology, Microbiology, 03 medical and health sciences, Lysogenic cycle, Bacteriophages, Lysogeny, Ecosystem, Prophage, 030304 developmental biology, Genetics, 0303 health sciences, Bacteria, 030306 microbiology, Host (biology), biology.organism_classification, humanities, 3. Good health, Temperateness, Lytic cycle, Susceptible individual, Repressor

Abstract

versión pre-print: 30 páginas, 5 figuras, Temperate bacteriophages (phages) are viruses of bacteria. Upon infection of a susceptible host, a temperate phage can establish either a lytic cycle that kills the host or a lysogenic cycle as a stable prophage. The life cycle pursued by an infecting temperate phage can have a significant impact not only on the individual host bacterium at the cellular level but also on bacterial communities and evolution in the ecosystem. Thus, understanding the decision processes of temperate phages is crucial. This review delves into the molecular mechanisms behind lysis-lysogeny decision-making in Gram-positive phages. We discuss a variety of molecular mechanisms and the genetic organization of these well-understood systems. By elucidating the strategies used by phages to make lysis-lysogeny decisions, we can improve our understanding of phage-host interactions, which is crucial for a variety of studies including bacterial evolution, community and ecosystem diversification, and phage therapeutics., The writing of this review was supported by grants MR/M003876/1 and MR/S00940X/1 from the UK Medical Research Council, grants BB/N002873/1 and BB/S003835/1 from the UK Biotechnology and Biological Sciences Research Council, grant 201531/Z/16/Z from the Wellcome Trust, and ERC-ADG-2014 proposal 670932 “DUT-signal” from the European Research Council to J.R.P., as well as by grants BIO2016-78571-P and PID2019-108541GB-I00 from the Spanish government and PROMETEO/2020/012 from the Valencian Government to A.M. A.F-R. is a recipient of a PhD fellowship from the FPU program of the Spanish Government (reference FPU19/00433). Figures were created with BioRender.com.

Published

2021

136. Non-canonical LexA proteins regulate the SOS response in the Bacteroidetes

Author

Ivan Erill, Jordi Barbé, Pilar Cortés, Mark A Lee, Miquel Sánchez-Osuna, and Aaron T. Smith

Subjects

DNA, Bacterial, Models, Molecular, Protein Conformation, alpha-Helical, DNA Repair, DNA repair, DNA damage, AcademicSubjects/SCI00010, Repressor, Biology, Genome Integrity, Repair and Replication, SOS Response (Genetics), Bacterial Proteins, Genetics, Escherichia coli, Bacteriophages, Gene Regulatory Networks, Protein Interaction Domains and Motifs, SOS response, SOS Response, Genetics, Gene, Binding Sites, Bacteroidetes, Mutagenesis, Serine Endopeptidases, Gene Expression Regulation, Bacterial, biochemical phenomena, metabolism, and nutrition, Repressor Proteins, enzymes and coenzymes (carbohydrates), bacteria, Protein Conformation, beta-Strand, Repressor lexA, Genome, Bacterial, DNA Damage, Peptide Hydrolases, Protein Binding

Abstract

Lesions to DNA compromise chromosome integrity, posing a direct threat to cell survival. The bacterial SOS response is a widespread transcriptional regulatory mechanism to address DNA damage. This response is coordinated by the LexA transcriptional repressor, which controls genes involved in DNA repair, mutagenesis and cell-cycle control. To date, the SOS response has been characterized in most major bacterial groups, with the notable exception of the Bacteroidetes. No LexA homologs had been identified in this large, diverse and ecologically important phylum, suggesting that it lacked an inducible mechanism to address DNA damage. Here, we report the identification of a novel family of transcriptional repressors in the Bacteroidetes that orchestrate a canonical response to DNA damage in this phylum. These proteins belong to the S24 peptidase family, but are structurally different from LexA. Their N-terminal domain is most closely related to CI-type bacteriophage repressors, suggesting that they may have originated from phage lytic phase repressors. Given their role as SOS regulators, however, we propose to designate them as non-canonical LexA proteins. The identification of a new class of repressors orchestrating the SOS response illuminates long-standing questions regarding the origin and plasticity of this transcriptional network.

Published

2021

137. Escherichia coli K‐12 has two distinguishable PriA‐PriB replication restart pathways

Author

Tricia A. Windgassen, Steven J. Sandler, James L. Keck, and Maxime Leroux

Subjects

DNA Replication, DNA, Bacterial, Escherichia coli K12, DNA repair, Escherichia coli Proteins, Mutant, DNA Helicases, DNA replication, Helicase, Biology, Microbiology, Article, Cell biology, DNA-Binding Proteins, chemistry.chemical_compound, chemistry, Mutation, biology.protein, Nucleoid, SOS response, Homologous recombination, Molecular Biology, DNA

Abstract

In Escherichia coli, PriA, PriB, PriC, and DnaT proteins mediate three pathways for Replication Restart called PriA-PriB, PriA-PriC and PriC. PriA is crucial for two of the three pathways. Its absence leads to slow growth, high basal levels of SOS expression, poorly partitioning nucleoids, UV sensitivity, and recombination deficiency. PriA has ATPase and helicase activities and interacts with PriB, DnaT, and single-stranded DNA-binding protein (SSB). priA300 (K230R) and priA301 (C479Y) have no phenotype as single mutants, but each phenocopies a priA-null mutant when combined with ΔpriB. This suggested that the two priA mutations affected helicase activity that is required for the PriA-PriC pathway. To further test this, the biochemical activities of purified PriA300 and PriA301 were examined. As expected, PriA300 lacks ATPase and helicase activities, but retains the ability to interact with PriB. PriA301, however, retains significant PriB-stimulated helicase activity even though PriA301 interactions with PriB and DNA are weakened. A PriA300,301 variant retains only the ability to interact with DNA in vitro and phenocopies the priA-null phenotype in vivo. This suggests that there are two biochemically and genetically distinct PriA-PriB pathways. One uses PriB-stimulated helicase activity to free a region of ssDNA and the other uses helicase-independent re-modelling activity.

Published

2021

138. Comparative Study of the DNA-Damaging Activity of Epichlorohydrin Using Escherichia coli Biosensors and the Comet Assay Method in Mice

Author

B. S. Zhoshibekova, K. G. Ordzhonikidze, E. V. Igonina, and S. K. Abilev

Subjects

DNA damage, organic chemicals, fungi, Biology, medicine.disease_cause, Molecular biology, Comet assay, chemistry.chemical_compound, chemistry, In vivo, Genetics, medicine, Epichlorohydrin, SOS response, Escherichia coli, Gene, DNA

Abstract

A comparative study of the genotoxic effects of methylmethanesulfonate (MMS) and epichlorohydrin (ECH) was performed using bacterial E. coli biosensors and the comet assay method in mice. ECH was shown to induce weaker SOS response and expression of the alkA gene in bacterial cells compared to MMS. In vivo experiments on mice using the comet assay method showed DNA-damaging activity of ECH in cells of the liver, kidneys, and lungs after 3 h of exposure, same as of MMS. The levels of DNA damage caused by ECH in these organs after exposure for 3 h were lower than for MMS. The genotoxic effect of ECH after 18 h of exposure was statistically significant only in a dose of 20 mg/kg in kidney cells.

Published

2021

139. New Molecular Resistance Mechanisms against Antibiotics in Bacteria

Author

Dariush Shokri and Mohammad Rabbani-Khorasgani

Subjects

Antibiotic, Antibiotic resistance, Riboswitch, SOS response, Quorum sensing, Persister cells, Medicine, Medicine (General), R5-920

Abstract

Only a short time after the discovery of antibiotics by Alexander Fleming, antibiotic-resistant bacteria were reported. Besides the traditional mechanisms of resistance in bacteria, new mechanisms have been described by different researchers. For example, recently a new gene operon of D-alanine-D-serine called VanL that cuased resistant to the antibiotic vancomycin was reported. Other researchers have shown that Klebsiella pneumoniae strains lost purine Ompk36 that have a major role in the antibiotic diffusion into cells, are resistant to carbapenem. In 2011, the first full resistance to tigecycline was reported that the enzyme-linked monooxygenase flavin hydroxyl TetX cause deactivation of antibiotics. In 2012, high resistance to mupricin antibiotic was described that intermediated by a new locus named mupB. In addition, in 2013, it was showed that some strains of Enterococcus faecalis can move daptomycin antibiotic from its target to other places and so inhibit its activity. Removal of whole target gene (PBP3) of ceftazidime in Burkholderia pseudomallei was reported in 2012. In other hand, new role of riboswitch for resistance to aminoglycoside antibiotics reported in 2013. In addition, recent studies have indicated a relationship between SOS response and quorum sensing with antibiotic resistance and new antibiotic resistance mechanisms in bacterial biofilm and persister cells are known. In this review, recent studies have been conducted to identify these new mechanisms.

Published

2015

140. The mef (A)/ msr (D)-carrying streptococcal prophage Φ1207.3 encodes an SOS-like system, induced by UV-C light, responsible for increased survival and increased mutation rate.

Author

Fox V, Santoro F, Apicella C, Diaz-Diaz S, Rodriguez-Martínez JM, Iannelli F, and Pozzi G

Subjects

Streptococcus pneumoniae, Streptococcus pyogenes genetics, Biological Assay, Prophages genetics, Mutation Rate

Abstract

Bacterial SOS response is an inducible system of DNA repair and mutagenesis. Streptococci lack a canonical SOS response, but an SOS-like response was reported in some species. The mef (A)- msr (D)-carrying prophage Ф1207.3 of Streptococcus pyogenes contains a region, spanning orf6 to orf11 , showing homology to characterized streptococcal SOS-like cassettes. Genome-wide homology search showed the presence of the whole Φ1207.3 SOS-like cassette in three S . pyogenes prophages, while parts of it were found in other bacterial species. To investigate whether this cassette confers an SOS-mutagenesis phenotype, we constructed Streptococcus pneumoniae R6 isogenic derivative strains: (i) FR172, streptomycin resistant, (ii) FR173, carrying Φ1207.3, and (iii) FR174, carrying a recombinant Φ1207.3, where the SOS-like cassette was deleted. These strains were used in survival and mutation rate assays using a UV-C LED instrument, for which we designed and 3D-printed a customized equipment, constituted of an instrument support and swappable-autoclavable mini-plates and lids. Upon exposure to UV fluences ranging from 0 to 6,400 J/m 2 at four different wavelengths, 255, 265, 275, and 285 nm, we found that the presence of Φ1207.3 SOS-like cassette increases bacterial survival up to 34-fold. Mutation rate was determined by measuring rifampicin resistance acquisition upon exposure to UV fluence of 50 J/m 2 at the four wavelengths by fluctuation test. The presence of Φ1207.3 SOS-like cassette resulted in a significant increase in the mutation rate (up to 18-fold) at every wavelength. In conclusion, we demonstrated that Φ1207.3 carries a functional SOS-like cassette responsible for an increased survival and increased mutation rate in S. pneumoniae . IMPORTANCE Bacterial mutation rate is generally low, but stress conditions and DNA damage can induce stress response systems, which allow for improved survival and continuous replication. The SOS response is a DNA repair mechanism activated by some bacteria in response to stressful conditions, which leads to a temporary hypermutable phenotype and is usually absent in streptococcal genomes. Here, using a reproducible and controlled UV irradiation system, we demonstrated that the SOS-like gene cassette of prophage Φ1207.3 is functional, responsible for a temporary hypermutable phenotype, and enhances bacterial survival to UV irradiation. Prophage Φ1207.3 also carries erythromycin resistance genes and can lysogenize different pathogenic bacteria, constituting an example of a mobile genetic element which can confer multiple phenotypes to its host., Competing Interests: The authors declare no conflict of interest.

Published

2023

141. بیان ژن recA درموتانdinI- مقاوم به سیپروفلوکسازین اشریشیا کلی

Author

محمدی, ساره, پوراحمد, راضیه, and محزونیه, محمد رضا

Abstract

Introduction: Microorganisms in response to drug development, acquire resistance through a variety of mechanisms. The prevalence of resistance to fluoroquinolones (FQ), such as ciprofluxacin in Escherichia coli has increased markedly in recent years. Mutagenesis induced by SOS catalyzes the evolution of resistance to fluoroquinolones. A member of the SOS regulon is the dinI gene. Protein encoded by the gene DinI acts as positive and negative modulator of RecA performance. Previous studies showedrecA gene expression in ciprofloxacin resistant Escherichia coli dinI+ in which mutants increased. The aim of this study was to investigate recA gene expression in dinI-mutant resistant to ciprofloxacin Materials and Methods: For this purpose, dinI- mutant became ciprofloxacin resistant by encountering to increase amount of ciprofloxacin via stepwise method and be evaluated for MIC. Then, the expression of recA gene was determined in wild type, dinI- and a dinI+ mutants by real time PCR. Results: The results showed that a dinI- mutant acquired low level of resistance to ciprofloxacin and its MIC was 0.3 µg/ml. recA gene expression in the dinI- mutant was increased in comparison with wild type strain. However, the amount of increase was about one fourth of increase in dinI+ mutant. Discussion and conclusion: In conclusion, inactivation of dinI gene does not inhibit increase in recA gene expression and regulation of RecA activity is possibly complex and could be conducted in the absence of dinI by other regulatory proteins. [ABSTRACT FROM AUTHOR]

Published

2018

142. Timing of DNA damage responses impacts persistence to fluoroquinolones.

Author

Mok, Wendy W. K. and Brynildsen, Mark P.

Subjects

*DNA damage, *FLUOROQUINOLONES, *PHENOTYPES, *BACTERIAL population, *BACTERIAL cultures

Abstract

Bacterial persisters are subpopulations of phenotypic variants in isogenic cultures that can survive lethal doses of antibiotics. Their tolerances are often attributed to reduced activities of antibiotic targets, which limit corruption and damage in persisters compared with bacteria that die from treatment. However, that model does not hold for nongrowing populations treated with ofloxacin, a fluoroquinolone, where antibiotic-induced damage is comparable between cells that live and those that die. To understand how those persisters achieve this feat, we employed a genetic system that uses orthogonal control of MazF and MazE, a toxin and its cognate antitoxin, to generate model persisters that are uniformly tolerant to ofloxacin. Despite this complete tolerance, MazF model persisters required the same DNA repair machinery (RecA, RecB, and SOS induction) to survive ofloxacin treatment as their nongrowing, WT counterparts and exhibited similar indicators of DNA damage from treatment. Further investigation revealed that, following treatment, the timing of DNA repair was critical to MazF persister survival because, when repair was delayed until after growth and DNA synthesis resumed, survival was compromised. In addition, we found that, with nongrowing, WT planktonic and biofilm populations, stalling the resumption of growth and DNA synthesis after the conclusion of fluoroquinolone treatment with a prevalent type of stress at infection sites (nutrient limitation) led to near complete survival. These findings illustrate that the timing of events, such as DNA repair, following fluoroquinolone treatment is important to persister survival and provide further evidence that knowledge of the postantibiotic recovery period is critical to understanding persistence phenotypes. [ABSTRACT FROM AUTHOR]

Published

2018

143. Influence of uvrA, recJ and recN gene mutations on nucleoid reorganization in UV-treated Escherichia coli cells.

Author

Estévez Castro, Carlos Felipe, Serment-Guerrero, Jorge Humberto, and Fuentes, Jorge Luis

Subjects

*ESCHERICHIA coli, *NUCLEOIDS, *CHROMOSOMES

Abstract

Exposure to ultraviolet (UV) radiation blocks DNA replication and arrests cellular division in Escherichia coli. Restoration of chromosome replication involves nucleoid reorganization, which involves the participation of the recombination-catalyzing proteins RecA, RecO, RecR and RecN. In this work, we evaluated the influence of recN, uvrA and recJ gene mutations on post-irradiation nucleoid reorganization. We used isogenic E. coli strains that are defective for these genes to study post-irradiation kinetics of the nucleoid shape fractions using fluorescence microscopy. The results showed that in the wild-type strain, post-irradiation nucleoid reorganization occurs, which restores the nucleoid shape fractions in the cells to those observed prior to irradiation. First, the nucleoid condenses into the central area of the irradiated cell. Second, the nucleoid disperses along the cell. Third, the cell enters the chromosome replicative phase and cytokinesis. Escherichia coli cells with a recN mutation did not exhibit increased nucleoid condensation, but chromosome replication and cytokinesis occurred. In the uvrA and recJ strains, the condensation step was delayed compared to the wild-type strain, and chromosome replication and cytokinesis did not occur. The results are discussed with an emphasis on the functions of RecN, UvrA and RecJ in nucleoid reorganization in UV-irradiated E. coli cells. [ABSTRACT FROM AUTHOR]

Published

2018

144. Sub-inhibitory concentrations of heavy metals facilitate the horizontal transfer of plasmid-mediated antibiotic resistance genes in water environment.

Author

Zhang, Ye, Gu, April Z., Cen, Tianyu, Li, Xiangyang, He, Miao, Li, Dan, and Chen, Jianmin

Subjects

HEAVY metal content of water, WATER chemistry, ANTIBIOTICS, REACTIVE oxygen species, PERMEABILITY

Abstract

Although widespread antibiotic resistance has been mostly attributed to the selective pressure generated by overuse and misuse of antibiotics, recent growing evidence suggests that chemicals other than antibiotics, such as certain metals, can also select and stimulate antibiotic resistance via both co-resistance and cross-resistance mechanisms. For instance, tetL , merE , and oprD genes are resistant to both antibiotics and metals. However, the potential de novo resistance induced by heavy metals at environmentally-relevant low concentrations (much below theminimum inhibitory concentrations [MICs], also referred as sub-inhibitory) has hardly been explored. This study investigated and revealed that heavy metals, namely Cu(II), Ag(I), Cr(VI), and Zn(II), at environmentally-relevant and sub-inhibitory concentrations, promoted conjugative transfer of antibiotic resistance genes (ARGs) between E. coli strains. The mechanisms of this phenomenon were further explored, which involved intracellular reactive oxygen species (ROS) formation, SOS response, increased cell membrane permeability, and altered expression of conjugation-relevant genes. These findings suggest that sub-inhibitory levels of heavy metals that widely present in various environments contribute to the resistance phenomena via facilitating horizontal transfer of ARGs. This study provides evidence from multiple aspects implicating the ecological effect of low levels of heavy metals on antibiotic resistance dissemination and highlights the urgency of strengthening efficacious policy and technology to control metal pollutants in the environments. [ABSTRACT FROM AUTHOR]

Published

2018

145. Expansion of the SOS regulon of <italic>Vibrio cholerae</italic> through extensive transcriptome analysis and experimental validation.

Author

Krin, Evelyne, Pierlé, Sebastian Aguilar, Sismeiro, Odile, Jagla, Bernd, Dillies, Marie-Agnès, Varet, Hugo, Irazoki, Oihane, Campoy, Susana, Rouy, Zoé, Cruveiller, Stéphane, Médigue, Claudine, Coppée, Jean-Yves, and Mazel, Didier

Subjects

*GENES, *NON-coding RNA, *CELLS, *MITOMYCINS, *NUCLEOTIDES

Abstract

Background: The SOS response is an almost ubiquitous response of cells to genotoxic stresses. The full complement of genes in the SOS regulon for Vibrio species has only been addressed through bioinformatic analyses predicting LexA binding box consensus and in vitro validation. Here, we perform whole transcriptome sequencing from Vibrio cholerae treated with mitomycin C as an SOS inducer to characterize the SOS regulon and other pathways affected by this treatment. Results: Comprehensive transcriptional profiling allowed us to define the full landscape of promoters and transcripts active in V. cholerae. We performed extensive transcription start site (TSS) mapping as well as detection/quantification of the coding and non-coding RNA (ncRNA) repertoire in strain N16961. To improve TSS detection, we developed a new technique to treat RNA extracted from cells grown in various conditions. This allowed for identification of 3078 TSSs with an average 5'UTR of 116 nucleotides, and peak distribution between 16 and 64 nucleotides; as well as 629 ncRNAs. Mitomycin C treatment induced transcription of 737 genes and 28 ncRNAs at least 2 fold, while it repressed 231 genes and 17 ncRNAs. Data analysis revealed that in addition to the core genes known to integrate the SOS regulon, several metabolic pathways were induced. This study allowed for expansion of the Vibrio SOS regulon, as twelve genes (ubiEJB, tatABC, smpA, cep, VC0091, VC1190, VC1369–1370) were found to be co-induced with their adjacent canonical SOS regulon gene(s), through transcriptional read-through. Characterization of UV and mitomycin C susceptibility for mutants of these newly identified SOS regulon genes and other highly induced genes and ncRNAs confirmed their role in DNA damage rescue and protection. Conclusions: We show that genotoxic stress induces a pervasive transcriptional response, affecting almost 20% of the V. cholerae genes. We also demonstrate that the SOS regulon is larger than previously known, and its syntenic organization is conserved among Vibrio species. Furthermore, this specific co-localization is found in other γ-proteobacteria for genes recN-smpA and rmuC-tatABC, suggesting SOS regulon conservation in this phylum. Finally, we comment on the limitations of widespread NGS approaches for identification of all RNA species in bacteria. [ABSTRACT FROM AUTHOR]

Published

2018

146. Exposure of Escherichia coli to human hepcidin results in differential expression of genes associated with iron homeostasis and oxidative stress.

Author

Pascoe, Michael J., Jiraporn Lueangsakulthai, Ripley, Delia, Morris, Roger H., and Maddocks, Sarah E.

Subjects

*ESCHERICHIA coli, *HEPCIDIN, *PATHOGENIC microorganisms

Abstract

Hepcidin belongs to the antimicrobial peptide family but has weak activity with regards to bacterial killing. The regulatory function of hepcidin in humans serves to maintain an iron-restricted environment that limits the growth of pathogens; this study explored whether hepcidin affected bacterial iron homeostasis and oxidative stress using the model organism Escherichia coli. Using the Miller assay it was determined that under low iron availability exposure to sub-inhibitory doses of hepcidin (4-12µM) led to 2-fold and 4-fold increases in the expression of ftnA and bfd, respectively (P < 0.05), in both a wild type (WT) and Δfur (ferric uptake regulator) background. Quantitative real-time PCR analysis of oxyR and sodA, treated with 4 or 8 µM of hepcidin showed that expression of these genes was significantly (P < 0.05) increased, whereas expression of lexA was unchanged, indicating that hepcidin likely mediated oxidative stress but did not induce DNA damage. [ABSTRACT FROM AUTHOR]

Published

2018

147. Increase in Bacterial Resistance to Antibiotics after Cancer Therapy with Platinum-Based Drugs.

Author

Chistyakov, V. A., Prazdnova, E. V., Mazanko, M. S., Churilov, M. N., and Chmyhalo, V. K.

Subjects

*ANTINEOPLASTIC agents, *DRUG resistance in bacteria, *CANCER treatment, *CANCER chemotherapy, *HYDROGEN peroxide

Abstract

The use of platinum-based anticancer drugs is limited by both their side effects and their effect on normal microflora’s metagenome. Drugs that possess mutagenic and genotoxic properties may cause mutations in microbial genomes that contribute to the emergence of resistance to antimicrobial preparations and the development of complications after chemotherapy. The effects of cisplatin and oxaliplatin on microorganisms were studied using bacterial biosensors—E. coli strains MG1655 pKatG-lux, which reacts to the generation of hydrogen peroxide; MG1655 pSoxS-lux, which reacts to the superoxide anion radical; and the MG1655 pColD-lux strain, which detects DNA damage. The biosensor tests demonstrated high levels of genotoxicity for both drugs and some differences in the spectrum of reactive oxygen species generated. Ascorbate reduced genotoxicity of cisplatin by 41%. Nonlethal doses of cisplatin induced a three- to sevenfold increase in the frequency of the mutations that confer the resistance of E. coli to rifampicin and ciprofloxacin. Ascorbate also reduced frequency of the mutations by 65%. Thus, the effect of these drugs was probably associated with the generation of reactive oxygen species and induction of SOS response. The risk of secondary antibiotic-resistant infections may be decreased by applying antioxidants and antimutagens. At the same time, these increases may also decrease the anti-tumoral action of these compounds. [ABSTRACT FROM AUTHOR]

Published

2018

148. Exposure to Sub-lethal 2,4-Dichlorophenoxyacetic Acid Arrests Cell Division and Alters Cell Surface Properties in Escherichia coli.

Author

Bhat, Supriya V., Kamencic, Belma, Körnig, André, Shahina, Zinnat, and Dahms, Tanya E. S.

Subjects

DICHLOROPHENOXYACETIC acid, CELL division, ESCHERICHIA coli

Abstract

Escherichia coli is a robust, easily adaptable and culturable bacterium in vitro, and a model bacterium for studying the impact of xenobiotics in the environment. We have used correlative atomic force - laser scanning confocal microscopy (AFM-LSCM) to characterize the mechanisms of cellular response to the herbicide 2,4-dichlorophenoxyacetic acid (2,4-D). One of the most extensively used herbicides world-wide, 2,4-D is known to cause hazardous effects in diverse non-target organisms. Sub-lethal concentrations of 2,4-D caused DNA damage in E. coli WM1074 during short exposure periods which increased significantly over time. In response to 2,4-D, FtsZ and FtsA relocalized within seconds, coinciding with the complete inhibition of cell septation and cell elongation. Exposure to 2,4-D also resulted in increased activation of the SOS response. Changes to cell division were accompanied by concomitant changes to surface roughness, elasticity and adhesion in a time-dependent manner. This is the first study describing the mechanistic details of 2,4-D at sub-lethal levels in bacteria. Our study suggests that 2,4-D arrests E. coli cell division within seconds after exposure by disrupting the divisome complex, facilitated by dissipation of membrane potential. Over longer exposures, 2,4-D causes filamentation as a result of an SOS response to oxidative stress induced DNA damage. [ABSTRACT FROM AUTHOR]

Published

2018

149. Endogenous Retrovirus 3 - History, Physiology, and Pathology.

Author

Bustamante Rivera, Yomara Y., Brütting, Christine, Schmidt, Caroline, Volkmer, Ines, and Staege, Martin S.

Subjects

ENDOGENOUS retroviruses, EUKARYOTIC genomes, CARCINOGENESIS

Abstract

Endogenous viral elements (EVE) seem to be present in all eukaryotic genomes. The composition of EVE varies between different species. The endogenous retrovirus 3 (ERV3) is one of these elements that is present only in humans and other Catarrhini. Conservation of ERV3 in most of the investigated Catarrhini and the expression pattern in normal tissues suggest a putative physiological role of ERV3. On the other hand, ERV3 has been implicated in the pathogenesis of auto-immunity and cancer. In the present review we summarize knowledge about this interesting EVE. We propose the model that expression of ERV3 (and probably other EVE loci) under pathological conditions might be part of a metazoan SOS response. [ABSTRACT FROM AUTHOR]

Published

2018

150. Lux Biosensors: Screening Biologically Active Compounds for Genotoxicity.

Author

Igonina, E. V., Marsova, M. V., and Abilev, S. K.

Abstract

The ability of metal salts and pharmacological agents to induce oxidative stress and the SOS response in bacteria is tested with a set of lux biosensors. The sensors are based on three E. coli strains carrying recombinant plasmids with the lux operon fused to the promoters of the SoxS (superoxide dismutase), KatG (catalase-peroxidase), and ColD (colicin D) genes. A total of 47 substances are tested. Of them, 16 induce the SOS response; and 6, oxidative stress. The results observed are compared with the previously published data on the mutagenic activity of the same 47 substances evaluated in the Ames test. The comparison shows full coincidence for 42 of the 47 substances analyzed. The potential of lux-based biosensors for screening chemicals for genetic activity is discussed. [ABSTRACT FROM AUTHOR]

Published

2018