Project description:The human pathogenic bacterium Listeria monocytogenes was exposed to antibiotics both during clinical treatment and as a saprophyte. As one of the keys to successful treatment is continued antibiotic sensitivity, the purpose of this study was to determine if exposure to sublethal antibiotic concentrations would affect the bacterial physiology and potentially induce tolerance to antibiotics. Transcriptomic analyses demonstrated that each of four antibiotics caused a compound-specific gene expression pattern related to (the) mode-of-action of the particular antibiotic. All four antibiotics caused the same changes in expression of several metabolic genes indicating a shift from aerobic to anaerobic metabolism driven by the induction of lmo1634 and the repression of alsA and lmo1992. This shift in metabolism could be a survival strategy in response to antibiotics and is further supported by the observation that a Δlmo1634 mutant was more sensitive to bactericidal antibiotics. The monocin locus encoding a cryptic prophage was induced by co-trimoxazole and repressed by ampicillin and gentamicin. This expression pattern correlated with the observed antibiotic-dependent biofilm formation, indicating a role of monocin in antibiotic-induced biofilm formation and a ΔlmaDCBA mutant confirmed this correlation. Thus, sublethal concentrations of antibiotics caused metabolic and physiological changes indicating that the organism is preparing to withstand lethal concentrations of antibiotics.

Project description:RNA-seq based transcriptome profiling allows a detailed molecular analysis of the E.coli transcriptome (~4200 genes) after perturbation with different antibiotics. Transcriptome fingerprints enable the identification of gene and pathway level responses to treatment to derive a mechanistic understanding of antibiotics mode of action and to differentiate antibiotics. For this goal, treatment has to be performed in a short time period and with sublethal concentrations of the antibiotics. Sublethal concentrations were chosen based on the EC90 concentration of the antibiotic necessary to change the cellular morphology compared to control conditions. Conclusions: Our study represents the first detailed analysis of E.coli transcriptomes after treatment with different antibiotics, with biologic replicates, generated by RNA-seq technology. The experimental design and data analysis reported here should provide a framework for comparative investigations of expression profiles of known and novel antibiotics. We conclude that RNA-seq based transcriptome characterization would expedite genetic network analyses and permit the dissection of complex biologic functions.

Project description:We studied the effects of three classes of antibiotics (amoxicillin, chlortetracycline and enrofloxacin ) on P. multocida transcriptome using custom oligonucleotide microarrays from Nimblegen systems. All the 2015 genes of Pm70 were spotted on the array and hybridizations were carried out with RNA isolated from three independent cultures of Pm70 grown in the presence or absence of sub-minimum inhibitory (sub-MIC) doses of antibiotics. Differentially expressed genes were identified by ANOVA and Dunnett’s test. Biological modeling of the differentially expressed genes (DE) was carried out based on Clusters of Orthologous (COG) groups and network analysis in Pathway Studio. Keywords: Response to sub-MIC antibiotics The experimental design included three biological replicate cultures of P. multocida grown in the absence or presence of sub-MIC antibiotics. Effects of antibiotics on the transcriptome with each antibiotic were determined by comparing the growth in the presence of antibiotic (treatment) to growth in the absence of antibiotic (control).

Project description:We report the application of a high-throughput technique, RNA-seq, to study the transcriptomic response of P. putida DOT-T1E in the presence of antibiotics with different mechanisms of action with the aim to study in more detail the defense mechanisms that bacteria use to resist against toxic compounds. We find that P. putida DOT-T1E responde in a different way against each antimicrobial compound, what clearly shows that bacteria defense in different ways depending on the targets that compounds uses to attack. Our work is the first global transcriptomic analysis done in P. putida DOT-T1E in the presence of a considerable range of antibiotics. P. putida DOT-T1E mRNA profiles in the presence of control condition (LB) and 8 different antibiotics (ampicillin, chloramphenicol, kanamycin, ciprofloxacin, tetracycline, spectinomycin, gentamicin and rifampicin)

Project description:The rise of antibiotic resistance and decline of antibiotic discovery urgently calls for novel mechanistic understanding of pharmacological and evolutionary interactions between antibiotics and multidrug resistant bacteria to revitalize existing antibiotics. The evolutionary cross-resistance to antibiotics has received intensive attention previously. Nevertheless, whether and how bacteria develop negative responses, under the selective pressure of antibiotics by inverting the evolutionary trajectory remains unclear. Here we found an instance of collateral sensitivity, in which clinical vancomycin-resistant Enterococcus faecium (VREfm) pathogens exhibit dramatic and specific susceptibility to pleuromutilin antibiotics, decreased minimal inhibitory concentrations (MICs) from 128 µg/mL to 0.03 µg/mL. The unique trade-off between vancomycin and pleuromutilins is mediated by the epistasis between the van gene cluster and msrC encoding an ABC-F protein protecting bacterial ribosomes. We validated the efficacy of pleuromutilins in vivo through reducing colonization and promoting microbiota restoration. Our findings provide an alternative approach to inverting the selective advantage and reversing the route of vancomycin resistance evolution, and to treat VREfm associated infections.

Project description:Treatment of bacteria with antibiotics at or close to the inhibitory concentration leads to specific transcriptional responses often affecting target genes and targets pathways. A dataset of transcriptional profiles (compendium) induced by antibiotics with known mode-of-action (MoA) can be used to gain information on the putative MoA of novel substances with unknown MoAs. We used a Pasteurella multocida microarray to generate a compendium of transcriptional profiles and to obtain information on the putative MoA of a novel antibiotic compound. We also show a strong impact of the bacteriostatic antibiotics on P. multocida virulence gene transcription. Keywords: antibiotica treatment, time course Midlog-grown cultures of P. multocida were treated for 10 or 30 min with 8 different antibiotics and one novel compound (thiazin) at minimal inhibitory concentrations (MICs) and were harvested. Control bacteria were not-treated and harvested at approximately the same optical density an OD578 of ~ 0.5. Total RNA was extracted from these samples and labelled with biotin. P. multocida whole genome transcriptional profiling was performed by hybridization on the custom-made Affymetrix microarray according to the manufacturer’s instructions. The experiments were done in triplicates.

Project description:Clostridioides difficile is the leading cause of antibiotics-associated diarrhea but can also result in more serious, life-threatening conditions. As incidence of C. difficile infections in hospitals is increasing, both in frequency and severity, and antibiotic-resistant C. difficile strains are advancing, antimicrobial peptides (AMPs) are an interesting alternative to classic antibiotics. Knowledge on the effects of AMPs on C. difficile will therefore not only enhance the knowledge for possible biomedical application but may also provide insights in mechanisms of C. difficile to adapt or counteract AMPs. This study applies state-of-the-art mass spectrometry methods to quantitatively investigate the proteomic response of C. difficile 630∆erm to sublethal concentrations of the AMP nisin allowing to follow the cellular stress adaptation in a time-resolved manner. The results do not only point at a heavy reorganization of the cellular envelop but also determined pronounced changes in central cellular processes such as carbohydrate metabolism. Moreover, the number of flagella per cell was changed during the process of adaptation to nisin suggesting a role of these cellular structures in combating this particular AMP, which is independent from pure cell motility

Project description:To investigate the transcriptome and global methylation patterns of cytosines and adenines in cells selected for adaptive resistance to ampicillin, gentamicin, and ciprofloxacin

Project description:Non-typeable Haemophilus influenzae (NTHi) is a common acute otitis media pathogen, with an incidence that is increased by previous antibiotic treatment. NTHi is also an emerging causative agent of other chronic infections in humans, some linked to morbidity, and all of which impose substantial treatment costs. In this study we explore the possibility that antibiotic exposure may stimulate biofilm formation by NTHi bacteria. We discovered that sub-inhibitory concentrations of beta-lactam antibiotic (i.e., amounts that partially inhibit bacterial growth) stimulated the biofilm-forming ability of NTHi strains, an effect that was strain and antibiotic dependent. When exposed to sub-inhibitory concentrations of beta-lactam antibiotics NTHi strains produced tightly packed biofilms with decreased numbers of culturable bacteria but increased biomass. The ratio of protein per unit weight of biofilm decreased as a result of antibiotic exposure. Antibiotic-stimulated biofilms had altered ultrastructure, and genes involved in glycogen production and transporter function were up regulated in response to antibiotic exposure. Down-regulated genes were linked to multiple metabolic processes but not those involved in stress response. Antibiotic-stimulated biofilm bacteria were more resistant to a lethal dose (10M-BM-5g/mL) of cefuroxime. Our results suggest that beta-lactam antibiotic exposure may act as a signaling molecule that promotes transformation into the biofilm phenotype. Loss of viable bacteria, increase in biofilm biomass and decreased protein production coupled with a concomitant up-regulation of genes involved with glycogen production might result in a biofilm of sessile, metabolically inactive bacteria sustained by stored glycogen. These biofilms may protect surviving bacteria from subsequent antibiotic challenges, and act as a reservoir of viable bacteria once antibiotic exposure has ended. 12 samples

Project description:This study reports on the co-administration of a zinc ionophore (PBT-2) and ampicillin to break antibiotic resistance of Streptococcus pneumoniae in a murine pneumonia model. The molecular mechanism for this heightened antimicrobial activity was identified through transcriptomic and metabolomic analyses of a wild type strain and a zinc efflux mutant to identify cellular targets of zinc intoxication. This revealed that zinc intoxication induces numerous cellular disruptions, which when combined with frontline antibiotics, can break antibiotic resistance and potentially preclude further resistance from emerging.