Project description:SOS mutator activity

Project description:Oxidative stress caused by exposure to reactive oxygen species (ROS), is a major challenge for aerobic and especially anaerobic organisms. Bacteria coordinate the response to oxidative stress through the LysR-type transcriptional regulator (LTTR) OxyR. Extensive studies have focused on the classical Escherichia coli system to shed light on the mode of action of defensive weapons against oxidative stress. The underlying mechanism is mediated via the formation of redox-dependent disulfide bond between two conserved cysteines of OxyR, thus activating transcription of members of the OxyR regulon. However, only fragmentary information on the regulation and function of OxyR has been gleaned through genetic and biochemical analyses in the important opportunistic pathogen P. aeruginosa. In this report, we used a comprehensive transcriptional profiling analysis to delineate the OxyR regulon under three conditions (KingM-bM-^@M-^Ys A medium [Pseudomonas medium or PM], Luria Broth (LB), and LB when oxyR is overexpressed), to investigate its roles in different cellular aspects that are independent of the classical oxidative stress response. Interestingly, when grown in LB, OxyR was found to regulating many genes involved in the process of inter-cellular communication known as quorum sensing (QS). In contrast, when grown in PM, OxyR regulate the expression of a newly identified CSS (cell-surface signaling) system in an OxyR-dependent fashion. In addition, the results from oxyR overexpression further confirmed that OxyR was linked to regulation of QS and Type 3 Secretion (T3SS) in addition to the regulation of antioxidative genes. Taken together, our results show that, apart from its dominant role in defense against oxidative stress in P. aeruginosa, OxyR acts as a global regulator that provides a link between the regulation of oxidative stress response, QS and virulence. 15 samples, representing 5 different biological conditions, including 3 biological replicates for each condition

Project description:We studied SOS mutator effect mediated by recA730 and changes in the dNTP pool. We found that established dNTP pool changes resulting from deficiencies in the ndk or dcd genes, had a strongly suppressive effect on the recA730 mutator effect. To investigate whether the observed reduction in SOS mutator effect is due to lowered expression of the entire SOS regulon, we performed microarray analysis of gene expression profiles in each of the single ndk, dcd, and recA730 strains, as well as the double recA730 ndk and recA730 dcd strains.

Project description:Oxidative stress caused by exposure to reactive oxygen species (ROS), is a major challenge for aerobic and especially anaerobic organisms. Bacteria coordinate the response to oxidative stress through the LysR-type transcriptional regulator (LTTR) OxyR. Extensive studies have focused on the classical Escherichia coli system to shed light on the mode of action of defensive weapons against oxidative stress. The underlying mechanism is mediated via the formation of redox-dependent disulfide bond between two conserved cysteines of OxyR, thus activating transcription of members of the OxyR regulon. However, only fragmentary information on the regulation and function of OxyR has been gleaned through genetic and biochemical analyses in the important opportunistic pathogen P. aeruginosa. In this report, we used a comprehensive transcriptional profiling analysis to delineate the OxyR regulon under three conditions (King’s A medium [Pseudomonas medium or PM], Luria Broth (LB), and LB when oxyR is overexpressed), to investigate its roles in different cellular aspects that are independent of the classical oxidative stress response. Interestingly, when grown in LB, OxyR was found to regulating many genes involved in the process of inter-cellular communication known as quorum sensing (QS). In contrast, when grown in PM, OxyR regulate the expression of a newly identified CSS (cell-surface signaling) system in an OxyR-dependent fashion. In addition, the results from oxyR overexpression further confirmed that OxyR was linked to regulation of QS and Type 3 Secretion (T3SS) in addition to the regulation of antioxidative genes. Taken together, our results show that, apart from its dominant role in defense against oxidative stress in P. aeruginosa, OxyR acts as a global regulator that provides a link between the regulation of oxidative stress response, QS and virulence.

Project description:The SOS response is a conserved pathway that is activated under certain stress conditions and is regulated by the repressor LexA and the activator RecA. The food-borne pathogen Listeria monocytogenes contains RecA and LexA homologs, but their roles in Listeria have not been established. In this study, we identified the SOS regulon in L. monocytogenes by comparing the transcription profiles of the wild-type strain and the ΔrecA mutant strain after exposure to the DNA damaging agent mitomycinC (MMC). The SOS response is an inducible pathway involved in DNA repair, restart of stalled replication forks, and in induction of genetic variation in stressed and stationary phase cells. It is regulated by LexA and RecA. LexA is an autoregulatory repressor which binds to a consensus sequence in the promoter region of the SOS response genes, thereby repressing transcription. A consensus LexA binding motif for L. monocytogenes has not been identified thus far. Generally, the SOS response is induced under circumstances in which single stranded DNA accumulates in the cell. This results in activation of RecA, which in turn stimulates cleavage of LexA, and ultimately in the induction of the SOS response. Keywords: stress response, loop design, SOS response, mitomycin c, listeria monocytogenes, RecA, LexA

Project description:Phages have emerged as prime suspects in the adaptation of pathogens to new hosts and the emergence of new pathogens or epidemic clones. Here we describe the genomic features of “swarms” of three related prophages (Ab105-1ϕ, Ab105-2ϕ and Ab105-3ϕ) present in the ST-2 epidemic clone of Acinetobacter baumannii clinical strain Ab105 GEIH-2010 and not present in genetically related Ab155 GEIH-2000 strain isolated 10 years before. The “Quasicore genome” of Ab105-1ϕ, Ab105-2ϕ and Ab105-3ϕ prophages revealed genes that promote bacterial-host fitness. The results of microarray analysis under stress conditions, SOS response and Quorum Sensing (QS) activation revealed 42% and 21% of genes expressed by Ab105-2ϕ and Ab105-3ϕ prophages (which produce bacterial lysis) in the first case and underexpression of these genes from prophages in the second case. Hence, the QS system plays a major role in the evolution of phages in their natural hosts and environments. Interestingly, in host-virus interactions, RT-PCR showed several mechanisms of overexpression of the SOS response in relation to phage defence mechanisms: i) SAM or AdoMet-MTase (methyltransferases) and MazG protein (pyrophosphohydrolase) associated with phage defence in response to bacterial attack; ii) eukaryotic-like protein kinase (glutamate 5-kinase) associated with prevention of secondary infection by the same or a closely related virus. Overexpression of secretory virulence factors such as oxidoreductase (DsbA-like), anfo-nitrogenase and chromosome segregation proteins were also observed. Moreover, under iron-deficient growth, there was an overexpression by RT-PCR of the a new interesting cluster of genes located following a “Moron” organization in the Ab105-3ϕ prophage being associated with iron uptake systems (Xanthine dehydrogenase gene cluster, Anthranilate operon, ABC transporter and TonB dependent receptor). In conclusion, study of the co-evolution of phages (virus) and bacteria may be essential in the search for means of combatting multi-resistant epidemic clones. Two parental clinical strains of A. baumannii (90% identity, indicated by PFGE, and ST2, indicated by Multilocus Sequence Typing, MLST) isolated in the same Intensive Care Unit (ICU) of a Spanish hospital, in 2000 and 2010, during the “I Multicenter Study GEIH-REIPI-Ab-2000” (Ab155 GEIH-2000) and “II Multicenter Study GEIH-REIPI-Ab-2010” (Ab105 GEIH-2010), respectively. Three replicates from RNA of the AB105 GEIH-2010 strain x 2 conditions (SOS response by Mitomycin C) and (Quorum Sensing activation by AHLs mixture).

Project description:We studied SOS mutator effect mediated by recA730 and changes in the dNTP pool. We found that established dNTP pool changes resulting from deficiencies in the ndk or dcd genes, had a strongly suppressive effect on the recA730 mutator effect. To investigate whether the observed reduction in SOS mutator effect is due to lowered expression of the entire SOS regulon, we performed microarray analysis of gene expression profiles in each of the single ndk, dcd, and recA730 strains, as well as the double recA730 ndk and recA730 dcd strains. Comparison of transcriptomes of the bacterium Escherichia coli six strains: wt, dcd, ndk, recA730, recA730 dcd and recA730 ndk. All strains were derivatives of the MC4100 strain, carrying a sulA366 allele (?(argF-lac)169 sulA366). dcd and ndk alleles used were dcd::kan and ndk::cam, respectively. Strains were compared in pairs: wt vs dcd, wt vs ndk, wt vs recA730, recA730 vs recA730 dcd and recA730 vs recA730 ndk. Two or three biological replicates for each strain were used. Each biological replicate had two technical replicates with dye swapping.

Project description:Studies of expression of mechanims of defense of the Acinetobacter sp.5-2Ac.02 from airborne hospital environment under stress conditions, such as SOS response (ROS response, heavy metals resistant mechanisms, peptides), as well as Quorum network (acetoin cluster and aromatics biodegradation cluster). Characterization functional of AcoN-like as negative regulator protein from acetoin cluster in Acinetobacter spp. Strains

Project description:LexA is a transcriptional repressor for genes requiring expression primarily during SOS response in response to stress such as that caused by DNA alkylating agent Mitomycin C (MMC). LexA undergoes self-cleavage under stress conditions thereby lifting the repression on genes whose expression is required for stress response. In our experiment LexA binding sites in the genome were determined in untreated and MMC treated (overnight, 14h) cultures using a LexA-3xFLAG strain and anti-FLAG monoclonal antibodies. Wild type Streptomyces venezuelae (unFLAGged LexA) cultures, with and without MMC treatment were used as negative controls.

Project description:The SOS response is a conserved pathway that is activated under certain stress conditions and is regulated by the repressor LexA and the activator RecA. The food-borne pathogen Listeria monocytogenes contains RecA and LexA homologs, but their roles in Listeria have not been established. In this study, we identified the SOS regulon in L. monocytogenes by comparing the transcription profiles of the wild-type strain and the ΔrecA mutant strain after exposure to the DNA damaging agent mitomycinC (MMC). The SOS response is an inducible pathway involved in DNA repair, restart of stalled replication forks, and in induction of genetic variation in stressed and stationary phase cells. It is regulated by LexA and RecA. LexA is an autoregulatory repressor which binds to a consensus sequence in the promoter region of the SOS response genes, thereby repressing transcription. A consensus LexA binding motif for L. monocytogenes has not been identified thus far. Generally, the SOS response is induced under circumstances in which single stranded DNA accumulates in the cell. This results in activation of RecA, which in turn stimulates cleavage of LexA, and ultimately in the induction of the SOS response. Keywords: stress response, loop design, SOS response, mitomycin c, listeria monocytogenes, RecA, LexA Triple loop design of 3 independent experiments (series A, B, and C) using Wt strain and recA mutant (activator of the SOS response). Sampling was done before (t=0) and 1 hour after (t=60) exposure to mitomycin C (MMC) for both the wild-type strain and the recA mutant strain. One series therefore contains 4 samples and the complete experiments consists of 12 samples. Each of the 3 series was designed in a loop (wt, t=0 =>wt, t=60 => recA, t=60 => recA, t=0 => wt, t=0). These 3 loops were connected using series B as the central loop. Series B was connected to series A as follows: wt, t=0 (B) => recA, t=0 (A) and wt, t=60 (B) => recA, t=60 (A). Series B was connected to series C as follows: recA, t=0 (B) => wt, t=0 (C) and recA, t=60 (B) => wt, t=60 (C).