Project description:This DNA methylation dataset describes epigenomic changes in in vitro serially passaged primary and immortalized astrocytes, in the context of studies examining cellular aging patterns that are conserved in vivo and in vitro. Primary and fetal hTERT-immortalized astrocytes were grown under normoxic conditions and serially passaged. Longitudinal DNA samples were collected throughout passaging and DNA methylation was measured using the Infinium HumanMethylation850 BeadChip.

Project description:Silver-resistant Saccharomyces cerevisiae mutant was obtained by evolutionary engineering method. Briefly, genetic diversity in reference strain, CEN.PK.113-7D, was increased by ethyl methane sulfonate (EMS)-mutagenesis. The mutant population was passaged several times in gradually increasing silver stress. Several mutant individuals were selected from the final population. Among selected mutant individuals, one of them was much more resistant to silver stress than the reference strain, called as 2E. Whole-genome transcriptomic analysis was performed to identify the silver resistance mechanisms in the silver-resistant mutant strain.

Project description:Applications for silver nanomaterials in consumer products are rapidly expanding, creating an urgent need for toxicological examination of the exposure potential and ecological effects of silver nanoparticles (AgNPs). The integration of genomic techniques into environmental toxicology has presented new avenues to develop exposure biomarkers and investigate the mode of toxicity of novel chemicals. In the present study we used a 15k oligonucleotide microarray for Daphnia magna, a freshwater crustacean and common indicator species for toxicity, to differentiate between particle specific and ionic silver toxicity and to develop exposure biomarkers for citrate-coated and PVP-coated AgNPs. Gene expression profiles revealed that AgNO3 and AgNPs have distinct expression profiles suggesting different modes of toxicity. However, the gene expression profiles of the different coated AgNPs were similar revealing similarities in the cellular effects of these two particles. Major biological processes disrupted by the AgNPs include protein metabolism and signal transduction. In contrast, AgNO3 caused a downregulation of developmental processes, particularly in sensory development. Metal responsive and DNA damage repair genes were induced by the PVP AgNPs, but not the other treatments. In addition, two specific biomarkers were developed for the environmental detection of PVP AgNPs; although further verification under different environmental conditions is needed.

Project description:Purpose: Analyze changes in the transcriptome of Arabidopsis thaliana in response to chronic exposure to silver nitrate at 4 μg/mL concentration. Methods: mRNA was extracted from non-treated and silver nitrate-treated 14-day old Arabidopsis thaliana seedlings using the RNAeasy extraction kit (Qiagen). RNA-seq libraries (3 rep/treatment and 3 reps/control) constructed with the TruSeq Stranded mRNA Sample Preparation kit (Illumina) were paired-end sequenced (100-nt read length) on an Illumina Nova Seq6000 system. Reads were mapped to the A. thaliana TAIR10 reference genome sequence and transcript levels were analyzed using the softare CLC Genomics Workbench (version 20.0.4, Qiagen). Results: Chronic exposure of A. thaliana plants to silver nitrate caused a change in the abundance of transcripts: AT2G01520 and AT4G12550, but no measureable impact on the rest of the transcriptome. Conclusions: Exposure of A. thaliana to silver nitrate at 4 μg/mL has minor impact on the transcriptome.

Project description:Applications for silver nanomaterials in consumer products are rapidly expanding, creating an urgent need for toxicological examination of the exposure potential and ecological effects of silver nanoparticles (AgNPs). The integration of genomic techniques into environmental toxicology has presented new avenues to develop exposure biomarkers and investigate the mode of toxicity of novel chemicals. In the present study we used a 15k oligonucleotide microarray for Daphnia magna, a freshwater crustacean and common indicator species for toxicity, to differentiate between particle specific and ionic silver toxicity and to develop exposure biomarkers for citrate-coated and PVP-coated AgNPs. Gene expression profiles revealed that AgNO3 and AgNPs have distinct expression profiles suggesting different modes of toxicity. However, the gene expression profiles of the different coated AgNPs were similar revealing similarities in the cellular effects of these two particles. Major biological processes disrupted by the AgNPs include protein metabolism and signal transduction. In contrast, AgNO3 caused a downregulation of developmental processes, particularly in sensory development. Metal responsive and DNA damage repair genes were induced by the PVP AgNPs, but not the other treatments. In addition, two specific biomarkers were developed for the environmental detection of PVP AgNPs; although further verification under different environmental conditions is needed. We exposed Daphnia magna to the 1/10 LC50 and LC25 of citrate coated and PVP-coated Ag nanoparticles and Ag+ as AgNO3 for 24-h. For each exposure condition, we performed 6 replicate exposures with 5 individuals in each. All exposures were compared to a unexposed laboratory control.

Project description:Silver exposure is toxic to fish due to disturbances of normal gill function. A proposed toxicity mechanism of silver nanoparticles (AgNP) is derived from the release of silver ions, similar to silver nitrate (AgNO3). However, some datasets support the fact that AgNP can have unique toxic effects that are mediated at the gill. To determine if differences between AgNO3 and AgNP toxicities exist, fathead minnows were exposed to 20 nm PVP- or citrate-coated silver nanoparticles (PVP-AgNP; citrate-AgNP) at the nominal concentration of 200 μg/L or AgNO3 at nominal 6 μg/L for 96 hr. This nominal concentration was applied to approximate the dissolved fraction of Ag in the AgNP suspensions. Mucus production in the water was measured. While mucus production was initially significantly increased in the first 4 h of exposure in all silver treatments compared to control, a decrease in mucus production was observed following 24-96 h of exposure. To determine which genes/pathways are driving this shift in mucus production, gills were dissected and microarray analysis was performed. Hierarchal clustering of differentially expressed genes revealed that all samples distinctly clustered by treatment. There were 109 differentially expressed genes shared among all Ag treatments compared to controls. However, there were 185, 423, and 615 differentially expressed genes unique to AgNO3, PVP-AgNP, and citrate-AgNP, relative to control. While functional analysis indicated several common enriched pathways, such as aryl hydrocarbon receptor signaling, this analysis also indicated some unique pathways between nanosilver and AgNO3. Our results show that AgNO3, PVP-AgNP, and citrate-AgNP exposure affected mucus production in fish gills and also lead to common and unique transcriptional changes.

Project description:Emerging antibiotic resistance among clinically relevant bacteria, paired with their ability to form biofilms on medical and technical devices, represents a serious problem in terms of effective and long-term decontamination in health care environments and gives rise to an urgent need for new antimicrobial materials. Here we present the first study of the impact of AGXX®, a novel broad-spectrum antimicrobial surface coating consisting of micro galvanic elements formed by silver and ruthenium, on the transcriptome of the nosocomial pathogen Enterococcus faecalis. E. faecalis was subjected to metal stress by growing it for different periods of time in the presence of AGXX® or silver-coated steel meshes. Subsequently, total RNA was isolated and next-generation RNA sequencing was performed to analyze variations in gene expression levels in the presence of the antimicrobial materials with focus on known stress genes. Exposure to AGXX® had a large impact on the transcriptome of E. faecalis. After 24 minutes almost 1/5 of the E. faecalis genome displayed differential expression. At each time-point the cop operon was strongly up-regulated, providing indirect evidence for the presence of free Ag+-ions. Moreover, exposure to AGXX® induced a broad general stress response in E. faecalis. Genes coding for the chaperones GroEL and GroES as well as the Clp proteases ClpE and ClpB were among the top up-regulated heat shock genes. Furthermore, differential expression of genes coding for thioredoxin, superoxide dismutase and glutathione synthetase indicates a high level of oxidative stress. We postulate a mechanism of action where the combination of Ag+-ions and reactive oxygen species generated by AGXX® results in a synergistic antimicrobial effect, which is superior to that of conventional silver coatings. Gene expression analysis of Enterococcus faecalis 12030 either subjected to metal stress by exposure to an antimicrobial AGXX®- or Ag-coated V2A steel mesh or exposed to an uncoated V2A steel mesh or left untreated performing RNA Sequencing with an Ion ProtonTM Sequencer and subsequent data analysis with a T-REx RNA-Sequencing expression analysis pipeline.

Project description:Emerging antibiotic resistance among clinically relevant bacteria, paired with their ability to form biofilms on medical and technical devices, represents a serious problem in terms of effective and long-term decontamination in health care environments and gives rise to an urgent need for new antimicrobial materials. Here we present the first study of the impact of AGXX®, a novel broad-spectrum antimicrobial surface coating consisting of micro galvanic elements formed by silver and ruthenium, on the transcriptome of the nosocomial pathogen Enterococcus faecalis. E. faecalis was subjected to metal stress by growing it for different periods of time in the presence of AGXX® or silver-coated steel meshes. Subsequently, total RNA was isolated and next-generation RNA sequencing was performed to analyze variations in gene expression levels in the presence of the antimicrobial materials with focus on known stress genes. Exposure to AGXX® had a large impact on the transcriptome of E. faecalis. After 24 minutes almost 1/5 of the E. faecalis genome displayed differential expression. At each time-point the cop operon was strongly up-regulated, providing indirect evidence for the presence of free Ag+-ions. Moreover, exposure to AGXX® induced a broad general stress response in E. faecalis. Genes coding for the chaperones GroEL and GroES as well as the Clp proteases ClpE and ClpB were among the top up-regulated heat shock genes. Furthermore, differential expression of genes coding for thioredoxin, superoxide dismutase and glutathione synthetase indicates a high level of oxidative stress. We postulate a mechanism of action where the combination of Ag+-ions and reactive oxygen species generated by AGXX® results in a synergistic antimicrobial effect, which is superior to that of conventional silver coatings.

Project description:To investigate the individual and synergistic antibacterial mechanisms of silver nitrate and potassium tellurite, Pseudomonas aeruginosa cultures were exposed to a shock treatment of these metal salts (individually and in combination) at inhibitory concentrations. Differential gene expression was identified by contrasting each metal salt challenge against a PBS-treated control.

Project description:In this study, a label-free quantitative proteomic approach was employed to analyze the serial passaged human skin fibroblast （CCD-1079Sk） cells, within 3305 proteins quantified. Of which, 372 proteins were significantly changed in early passage(P6), middle passage (P12) and later passage (P21), with a time-dependent decrease or increase tendency. Then, of which, SMC4 was selected for further biological validation. The results confirmed that the expression of SMC4 was significantly down-regulated in a time-dependent manner in the subculture of human skin fibroblasts (HSFb) with Western Blot experiment.