Project description:Here, we established a successive Fe0-enhanced microbe system to remove azo dye (a typical organic pollutant) by Shewanella decolorationis S12 (S. decolorationis S12, an effective azo dye degradation bacterium) and examined the gene expression time course (10, 30, 60, and 120 min) in whole genome transcriptional level. Comparing with the treatment without ZVI, approximately 8% genes affiliated with 10 different gene expression profiles in S. decolorationis S12 were significantly changed in 120 min during the ZVI-enhanced microbial azo reduction. Intriguingly, MarR transcriptional factor might play a vital role in regulating ZVI-enhanced azo reduction in the aspect of energy production, iron homeostasis, and detoxification. Further investigation showed that induced [Ni-Fe] H2ase genes (hyaABCDEF) and azoreductase genes (mtrABC-omcA) contributed to ZVI-enhanced energy production, while reduced iron uptake (hmuVCB and feoAB), induced sulfate assimilation (cysPTWA) and cysteine biosynthesis (cysM) related genes were essential to iron homeostasis and detoxification. This study disentangles underlying mechanisms of ZVI-enhanced azo reduction in S. decolorationis S12 and lays a foundation for further optimization of integrated ZVI-microbial system for efficient organic pollution treatment.

Project description:The contribution of the different CNS cell types to Aicardi-Goutiéres Syndrome pathogenesis is still unclear. With the aim to elucidate how oligodendrocytes, neurons and astrocytes impact AGS human phenotype we interrogate transcriptomes of the different cell populations performing single-cell RNA-Seq (scRNASeq). We compared cells deriving from AGS patient-derived iPSC harboring mutations in TREX1 (AGS1) or RNASEH2B (AGS2) to healthy donor control (WT) cells differentiated into mixed neuronal/glial cell populations.

Project description:ZVI-Anammox 20191029

Project description:Core-shell ZVI@carbon Composites Reduce Phosphate Inhibition of ZVI Dissolution

Project description:Genome-wide cDNA array from HT29,HT29-shROR,HT29-Mock, AGS, AGS-shROR, AGS-Mock cells We used microarrays to detail the global programme of gene expression and identified significantly changed genes after ROR depletion. HT29,HT29-shROR, HT29-Mock, AGS, AGS-shROR, AGS-Mock cells were selected for RNA extraction and hybridization on Affymetrix microarrays.

Project description:Aicardi-Goutières syndrome (AGS) is a severe childhood inflammatory disorder that shows clinical and genetic overlap with systemic lupus erythematosus (SLE). AGS is thought to arise from the accumulation of incompletely metabolized endogenous nucleic acid species owing to mutations in nucleic acid degrading enzymes TREX1 (AGS1), RNase H2 (AGS2, 3 and 4) and SAMHD1 (AGS5). However, the identity and source of such immunogenic nucleic acid species remain undefined. Using genome-wide approaches, we show that fibroblasts from AGS patients with AGS1-5 mutations are burdened by excessive loads of RNA:DNA hybrids. Using MethylC-seq, we show that AGS fibroblasts display pronounced and global loss of DNA methylation and demonstrate that AGS-specific RNA:DNA hybrids often occur within DNA hypomethylated regions. Altogether, our data suggest that RNA:DNA hybrids may represent a common immunogenic form of nucleic acids in AGS and provide the first evidence of epigenetic perturbations in AGS, furthering the links between AGS and SLE.

Project description:Genome-wide cDNA array from HT29,HT29-shROR,HT29-Mock, AGS, AGS-shROR, AGS-Mock cells We used microarrays to detail the global programme of gene expression and identified significantly changed genes after ROR depletion.

Project description:ZVI influence on constructed wetland

Project description:ZVI Metagenomic shotgun sequencing analysis

Project description:ncRNA-seq and miRNA-seq of AGS cellline and AGS cellline with neutrophil extracellular traps