Project description:<p>The increasing application of biodegradable mulch films in agriculture has raised concerns regarding the potential persistence of biodegradable microplastics (BMPs) in soil and their subsequent ecological impacts. Although these materials are designed to mineralize, their actual rates of breakdown under field conditions vary widely, and the role of plant roots in modulating BMP transformation through the rhizosphere effect remains poorly understood. In particular, how the complex biochemical environment of the rhizosphere influences BMP degradation and byproduct accumulation represents a critical knowledge gap. Here we show that the soybean rhizosphere significantly enhances the degradation of 1% (w/w) large (998.7 ± 74.6 μm) poly(butylene adipate-co-terephthalate) microplastics (PBAT-MPs), whereas small (145.6 ± 3.1 μm) particles remain largely protected within soil aggregates over a 70-day growth cycle. This size-dependent effect is accompanied by preferential hydrolysis of aliphatic adipate units, leading to greater accumulation of degradation monomers in the rhizosphere than in bulk soil. We further demonstrate that PBAT degradation is associated with increased microbial biomass, altered soil carbon pools, and the enrichment of Proteobacteria, particularly Bradyrhizobium and Ramlibacter, which are linked to PBAT hydrolysis and metabolite utilization. These findings redefine the role of plant roots in regulating the fate of biodegradable microplastics in soil and highlight that biodegradable mulches cannot be assumed to degrade benignly under realistic agricultural conditions. Our work underscores the need for rhizosphere relevant criteria when assessing the environmental safety of biodegradable plastics.</p>

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:Quercetin is a flavonol modifying numerous cell processes with potent antiproliferative effects on cancer cell-lines. The aim of this study was to explore by gene-array analysis the effect of quercetin on cancer-related gene expression in HepG2 cells, followed by verification with RT-PCR and analysis of the expected phenotypic changes (migration, cell cycle, cell proliferation). Quercetin induces significant changes on cell-adhesion related genes, leading to reduced migratory capacity and disorganization of the actin cytoskeleton. Several genes related to DNA functions, cellular metabolism and signal-transducer activities were also modified, while an early effect on G–protein related cascades possibly via protease-activated receptor 2 and phospholipase C-?1 was identified. Cyclin-D associated events in G1 and ubiquitin-dependent degradation of cyclin-D1 were also affected, resulting in cell-cycle arrest without activation of apoptosis pathways. In conclusion quercetin (3?M) exerts its cellular effects by modifying numerous genes related to mechanisms involved in cancer initiation and promotion. HepG2 cells were serum starved for 24 hours and were then treated with serum free medium with or without quercetin (3?M). Total RNA was collected at 2, 4, 12 and 24 hours and was used for gene-array experiments.

Project description:Sonodynamic therapy is an important approach in the treatment of hepatocellular carcinoma. A novel targeted nanobubbles loaded with HMME and LND was structured as sensibilizer, characterized the properties, and studied therapeutic effect on hepatocellular carcinoma. Next-generation high throughput RNA sequencing (RNA-Seq) was performed to accurately analyze the differential expression of mRNAs and lncRNA targets in hepatocellular carcinoma after sonodynamic therapy.

Project description:Effect of two different antimicrobial materials, functionalized graphene oxide (GOX), and AGXX® coated on cellulose fibers, on the growth and transcriptome of the clinical MRSA strain S. aureus 04-02981. In addition, we investigated the effect of a third material as a combination of GOX and AGXX® fibers on S. aureus 04-02981

Project description:Quercetin is a flavonol modifying numerous cell processes with potent antiproliferative effects on cancer cell-lines. The aim of this study was to explore by gene-array analysis the effect of quercetin on cancer-related gene expression in HepG2 cells, followed by verification with RT-PCR and analysis of the expected phenotypic changes (migration, cell cycle, cell proliferation). Quercetin induces significant changes on cell-adhesion related genes, leading to reduced migratory capacity and disorganization of the actin cytoskeleton. Several genes related to DNA functions, cellular metabolism and signal-transducer activities were also modified, while an early effect on G–protein related cascades possibly via protease-activated receptor 2 and phospholipase C-γ1 was identified. Cyclin-D associated events in G1 and ubiquitin-dependent degradation of cyclin-D1 were also affected, resulting in cell-cycle arrest without activation of apoptosis pathways. In conclusion quercetin (3μM) exerts its cellular effects by modifying numerous genes related to mechanisms involved in cancer initiation and promotion.

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:Quercetin has been shown to act as an anti-carcinogen in experimental colorectal cancer (CRC). The aim of the present study was to characterise transcriptome and proteome changes occurring in the distal colon mucosa of rats supplemented with 10 g quercetin/kg diet for 11 weeks. Transcriptome data analysed with Gene Set Enrichment Analysis showed that quercetin significantly downregulated the potentially oncogenic mitogen-activated protein kinase (Mapk) pathway. In addition, quercetin enhanced expression of tumor suppressor genes, including Pten, Tp53 and Msh2, and of cell cycle inhibitors, including Mutyh. Furthermore, dietary quercetin enhanced genes involved in phase I and II metabolism, including Fmo5, Ephx1, Ephx2 and Gpx2. Quercetin increased PPARα target genes, and concomitantly enhanced expression genes in volved in of mitochondrial fatty acid degradation. Proteomics performed in the same samples revealed 33 affected proteins, of which 4 glycolysis enzymes and 3 heatshock proteins were decreased. A proteome-transcriptome comparison showed a low correlation, but both pointed out towards altered energy metabolism. In conclusion, transcriptomics combined with proteomics showed that dietary quercetin evoked changes contrary to those found in colorectal carcinogenesis. These tumor-protective mechanisms were associated with a shift in energy production pathways, pointing at decreased glycolysis in the cytoplasm towards increased fatty acid degradation in the mitochondria. Experiment Overall Design: After an 11-week diet, rats fed quercetin or the control diet were sacrificed and fold changes in gene expression were detemined as quercetin (n=4) vs. control (n=4)

Project description:Quercetin has been shown to act as an anti-carcinogen in experimental colorectal cancer (CRC). The aim of the present study was to characterise transcriptome and proteome changes occurring in the distal colon mucosa of rats supplemented with 10 g quercetin/kg diet for 11 weeks. Transcriptome data analysed with Gene Set Enrichment Analysis showed that quercetin significantly downregulated the potentially oncogenic mitogen-activated protein kinase (Mapk) pathway. In addition, quercetin enhanced expression of tumor suppressor genes, including Pten, Tp53 and Msh2, and of cell cycle inhibitors, including Mutyh. Furthermore, dietary quercetin enhanced genes involved in phase I and II metabolism, including Fmo5, Ephx1, Ephx2 and Gpx2. Quercetin increased PPARα target genes, and concomitantly enhanced expression genes in volved in of mitochondrial fatty acid degradation. Proteomics performed in the same samples revealed 33 affected proteins, of which 4 glycolysis enzymes and 3 heatshock proteins were decreased. A proteome-transcriptome comparison showed a low correlation, but both pointed out towards altered energy metabolism. In conclusion, transcriptomics combined with proteomics showed that dietary quercetin evoked changes contrary to those found in colorectal carcinogenesis. These tumor-protective mechanisms were associated with a shift in energy production pathways, pointing at decreased glycolysis in the cytoplasm towards increased fatty acid degradation in the mitochondria. Keywords: Transscriptomics, proteomics, quercetin-exposed and control rats

Project description:We showed that diets containing 0.1% or 0.5% quercetin lowered the STZ-induced increase in blood glucose levels and improved plasma insulin levels. A cluster analysis of the hepatic gene expressions showed that 0.5% quercetin diet suppressed STZ-induced alteration of gene expression. Gene set enrichment analysis (GSEA) and quantitative RT-PCR analysis showed that the quercetin diets had their greatest suppressive effect on the STZ-induced elevation of expression of cyclin dependent kinase inhibitor p21(WAF1/Cip1) (Cdkn1a). In this experiment, we determined the effect of quercetin on healthy control BALB/c mice that were fed the AIN93G diet containing 0, 0.1, 0.5 or 1% quercetin for 2 weeks. GSEA and one-way ANOVA did not detect any significant changes in hepatic gene expression in normal mice as a result of a quercetin diet. Using a linear modeling approach and the empirical Bayes statistics, we found that Ubc were significantly reduced by both the 0.5% and 1% quercetin.