Project description:Genomic mutations allow bacteria to adapt rapidly to adverse stress environments. The three-dimensional conformation of the genome also may play an important role in transcriptional regulation and environmental adaptation. Here, using chromosome conformation capture, we investigate the high-order architecture of the Zymomonas mobilis chromosome in response to genomic mutant and ambient stimuli (acetic acid and furfural, derived from lignocellulosic hydrolysate). We find that genomic mutation only influences the local chromosome contacts, whereas stress of acetic acid and furfural restrict the long-range contacts and change the chromosome organization at domain scales significantly. Further deciphering the domain feature unveils the important transcription factors, Ferric uptake regulation (Fur) proteins, which act as nucleoid-associated proteins to promote long-range (> 200 kb) chromosomal communications and regulate the expression of genes involved in stress response. Our work suggests that ubiquitous transcription factors in prokaryotes mediate chromosome organization and regulate stress-resistance genes in bacterial adaptation. ChIP-seq analysis of Fur proteins binding in the genome of ZM532.

Project description:Genomic mutations allow bacteria to adapt rapidly to adverse stress environments. The three-dimensional conformation of the genome also may plays an important role in transcriptional regulation and environmental adaptation. Here, using chromosome conformation capture, we investigate the high-order architecture of the Zymomonas mobilis chromosome in response to genomic mutant and ambient stimuli (acetic acid and furfural, derived from lignocellulosic hydrolysate). We find that genomic mutation only influences the local chromosome contacts, whereas stress of acetic acid and furfural restrict the long-range contacts and change the chromosome organization at domain scales significantly. Further deciphering the domain feature unveils the important transcription factors, Ferric uptake regulation (Fur) proteins, which act as nucleoid-associated proteins to promote long-range (> 200 kb) chromosomal communications and regulate the expression of genes involved in stress response. Our work suggests that ubiquitous transcription factors in prokaryotes mediate chromosome organization and regulate stress-resistance genes in bacterial adaptation. Hi-C analysis revealed the three-dimensional conformation of Zymomonas mobilis.

Project description:This study investigated the responses of ZM532 and wild-type ZM4 to acetic acid and furfural using genomics, transcriptomics and label free quantitative proteome. By Sanger sequencing technology we re-verified of previously identified 19 mutations in ZM532, but we found a total of 23 single nucleotide polymorphisms (SNPs) in the coding sequence (CDS; 4) and intergenic region (19) in ZM532. Six SNPs were however novel in this study. We also identified a total of 1865 and 14 novel differentially expressed genes (DEGs) in ZM532 and wild-type ZM4. Further we identified 1,532 proteins by label free proteome. These proteins and genes are involved in amino acid biosynthesis, macromolecules repair, glycolysis, flagella assembly, ABC transporter, fermentation, and ATP synthesis pathways and stress response. The exclusively found genes and proteins in ZM532 confirmed and help to unravel the acetic acid and furfural tolerance mechanism between ZM532 and wild-type ZM4. May be these proteins and genes play key roles in ZM532 regulation with strong expressions under acids stress conditions. Furthermore, we knocked-out and overexpressed two differentially expressed genes (DEGs), ZMO_RS02740 up-regulated and ZMO_RS06525 down-regulated to investigate their roles in acetic acid and furfural tolerance. Our knockout and complementary experiments revealed that up-regulated expression gene ZMO RS02740 and the down-regulated expression gene ZMO-RS06525 play important roles in dealing with Furfural and acetic acid stress. ZM532 can be used to substitute ZM4 as a biocatalyst for bioethanol under acetic acid and furfural condition, with a shorter fermentation time and higher productivity.

Project description:Development of molecular approaches based on chromosome conformation capture (3C) technology such as Hi-C, combined with methods for modeling and interpreting chromatin interaction data, have revolutionized the analysis of chromosome folding. Even if the impact of chromatin structure on gene expression seems likely, little is known about the dynamics of DNA compaction and the factors involved in this process still have to be determined. Using the yeast Saccharomyces cerevisiae as a model, we used Hi-C technology to evaluate how 3D chromatin structure changes during different cellular processes such as adaptation in response to stress or DNA repair. We optimized the protocol from Belton, J.M et al (1) to produce our Hi-C libraries, one from control cells, one from cells after oxidative stress and one from cells after UV irradiation. Preliminary analysis suggests that in response to oxidative stress, chromosomes tend to make more contacts in trans and less contacts in cis compared to normal condition.

Project description:Lignocellulosic biomass is an abundant renewable resource with tremendous potential to alleviate climate crisis. Yarrowia lipolytica is an attractive biochemical production host, while the presence of inhibitors furfural and acetic acid in lignocellulosic hydrolysate restricts the efficient utilization of this resource. Given a deficient understanding of the inherent interactions between these inhibitors and cellular metabolism, sufficiently mining relevant genes is necessary. Herein, 14 novel gene targets were discovered using CRISPR interference library in Y. lipolytica, achieving tolerance to 0.35% (v/v) acetic acid (the highest concentration reported in Y. lipolytica), 4.8 mM furfural, or a combination of 2.4 mM furfural and 0.15% (v/v) acetic acid. The tolerance mechanism might involve improvements of signal transduction, PP pathway, and TCA cycle. Transcriptional repression of effective gene targets still enabled tolerance when xylose was a carbon source. This work forms a robust foundation for significantly improving microbial tolerance to inhibitors in lignocellulosic hydrolysate and profoundly revealing underlying mechanism.

Project description:Lignocellulosic biomass is an abundant renewable resource with tremendous potential to alleviate climate crisis. Yarrowia lipolytica is an attractive biochemical production host, while the presence of inhibitors furfural and acetic acid in lignocellulosic hydrolysate restricts the efficient utilization of this resource. Given a deficient understanding of the inherent interactions between these inhibitors and cellular metabolism, sufficiently mining relevant genes is necessary. Herein, 14 novel gene targets were discovered using CRISPR interference library in Y. lipolytica, achieving tolerance to 0.35% (v/v) acetic acid (the highest concentration reported in Y. lipolytica), 4.8 mM furfural, or a combination of 2.4 mM furfural and 0.15% (v/v) acetic acid. The tolerance mechanism might involve improvements of signal transduction, PP pathway, and TCA cycle. Transcriptional repression of effective gene targets still enabled tolerance when xylose was a carbon source. This work forms a robust foundation for significantly improving microbial tolerance to inhibitors in lignocellulosic hydrolysate and profoundly revealing underlying mechanism.

Project description:Here, we developed a novel chromosome conformation capture (3C) method for capturing the 3D spatial contacts of endogenous genomic loci without a need for crosslinking. This method, i3C, was applied to multiple loci in two different human primary (ENCODE) cell lines, HUVEC and IMR90, and in the absence or presence of a proinflammatory stimulus (TNFalpha). Coupled to high throughput sequencing on an Illumina HiSeq200 platform, i3C generated aprrox. 8 million single-end reads per experiment.

Project description:Furfural, phenol and acetic acid, generated during cellulosic material pretreatment, are the representative inhibitors to yeast used for ethanol production. The responses to these inhibitors in industrial yeast and the corresponding adapted strains were analyzed. Experiment Overall Design: We analyzed the transient response to inhibitors and the different transcriptions in industrial yeast and furfural-, phenol-, and acetic acid-adapted strains. Industrial yeast and the adapted strains were collected at 20 minutes after inhibitor addition. The reference samples for industrial yeast and adapted strains were collected at the same time without inhibitor addition. 2 replicates for each strain/treatment were analyzed.

Project description:Genome-wide chromosome conformation capture (Hi-C) and promoter-capture Hi-C (CHi-C) were performed during epidermal differentiation. These data indicate that dynamic and constitutive enhancer-promoter contacts combine to control gene induction during differentiation and that chromosome conformation enables discovery of new TFs with distinct roles in this process.

Project description:Genome-wide chromosome conformation capture (Hi-C) and promoter-capture Hi-C (CHi-C) were performed during epidermal differentiation. These data indicate that dynamic and constitutive enhancer-promoter contacts combine to control gene induction during differentiation and that chromosome conformation enables discovery of new TFs with distinct roles in this process.