Project description:Ubiquinone (UQ) is a polyprenylated lipid that is conserved from bacteria to humans and is crucial to cellular respiration. How the cell orchestrates the efficient synthesis of UQ, which involves the modification of extremely hydrophobic substrates by multiple sequential enzymes, remains an unresolved issue. Here, we demonstrate that seven Ubi proteins form the Ubi complex, a stable metabolon that catalyzes the last six reactions of the UQ biosynthetic pathway in Escherichia coli. In addition to five Ubi enzymes, the 1 MDa Ubi complex contains the newly identified UbiJ and UbiK proteins that we show to be involved in the binding of UQ intermediates and the structuration of the multiprotein complex. We also develop an in vitro assay and show that UQ biosynthesis occurs in the cytoplasmic fraction of E. coli, from which we purify the Ubi complex. Collectively, our work documents a rare case of stable metabolon and revisits the current thinking that the hydrophobic intermediates of the UQ pathway are metabolized in association with the membrane.

Project description:To ensure equal separation of DNA, sister chromatids are held together from S phase to metaphase–anaphase transition by a multiprotein complex called cohesin. This makes it possible to establish chromosome biorientation, counteracts the pulling force of mitotic spindle microtubules, preventing premature sister chromatid separation, and ensures precise segregation of sister DNAs into daughter cells In order to better understand how the sister chromatid cohesion process is regulated we looked for new cohesin interacors. We constructed a yeast strain endogenously expressing TAP-tagged Scc1 (Scc1-TAP). Next, we performed a single-step TAP purification using an untagged strain (mock sample) or a strain expressing Scc1-TAP, followed by identification of co-purifying proteins by MS.

Project description:Mapping the occupancy of ArcA throughout the genome of Escherchia coli MG1655 K-12 using an affinity purified antibody under anaerobic and aerobic growth conditions. As a control, we also performed ChIP-chip onArcA in a M-bM-^HM-^FarcA mutant strain of Escherchia coli MG1655 K-12. Described in the manuscript The response regulator ArcA uses a diverse binding site architechture to globally regulate carbon oxidation in E. coli Mapping of occupancy of ArcA in the genome of Escherchia coli MG1655 K-12 during anaerobic fermentation and aerobic respiration. Immunoprecipitated DNA compared to INPUT for each sample.

Project description:Inflammation is associated with many cardiovascular pathologies, but the underlying mechanisms remain unclear. To explore this in more detail, we characterized the transcriptome of an immortalized adult human ventricular cardiomyocyte cell line (AC16) in response to tumor necrosis factor (TNFa). Using a combination of genomic approaches, including global nuclear run-on sequencing (GRO-seq) and chromatin immunoprecipitation coupled with sequencing (ChIP-seq), we identified ~30,000 transcribed regions in AC16 cells, which includes a set of RNA polymerases I and III (Pol I and Pol III) transcribed regions revealed in the presence of M-NM-1-amanitin. The set of transcribed regions produces both protein-coding and non-coding RNAs, many of which have not been annotated previously, including enhancer RNAs originating from NF-M-NM-:B binding sites. In addition, we observed that AC16 cells rapidly and dynamically reorganize their transcriptomes in response to TNFa stimulation in an NF-M-NM-:B-dependent manner, switching from a basal state to a proinflammatory state affecting a spectrum of cardiac-associated protein-coding and non-coding genes. Moreover, we observed distinct Pol II dynamics for up- and downregulated genes, with a rapid release of Pol II into productive elongation for TNFa-stimulated genes. Our studies shed new light on the regulation of the cardiomyocyte transcriptome in response to a proinflammatory signal and help to clarify the link between inflammation and cardiomyocyte function at the transcriptional level. Using GRO-seq and ChIP-seq (p65 and RNA Pol II) over a time course of TNFM-NM-1 signaling in AC16 human cardiomyocytes.

Project description:Chromosomes are composed of enormously long DNA molecules which must be distributed correctly as the cells grow and divide. In Escherichia coli the new DNA behind the replication forks is specifically bound by the SeqA protein. SeqA binds to GATC sequences which are methylated on the A of the old strand but not on the new strand. Binding lasts for a period of time until Dam methyltransferase methylates the new strand. It is therefore believed that a region of hemi-methylated DNA covered by SeqA follows the replication fork. We show that this is indeed the case by using global ChIP on Chip analysis and a newly developed method for methylation analysis. A comparison of rapid and slow growth conditions showed that in cells with multiple replication forks per chromosome, the old forks bind little SeqA. Analysis of strains with strong SeqA binding sites at different chromosomal loci supported this finding. The results indicate that a re-organization of the chromosome occurs at a timepoint when new forks have travelled about 20% and old forks about 75% of the way to the terminus. This timepoint coincides with the end of origin sequestration. It is so far not known what brings about the end of origin sequestration. Here we suggest that a reorganization event occurs resulting in both origin desequestration and loss of old replication forks from the SeqA structures. SeqA ChIP-Chip analysis of unsynchronized E. coli MG1655 and in cells synchronized regarding initiation of DNA replication; SeqA ChIP-Chip of Dam overproducing strain and SeqA4 mutant; SeqA ChIP-Chip of strains with chromosomal insertions of strong SeqA binding site. Methylation analysis of synchronized E. coli MG1655dnaC2 cells 0 and 15 min after initiation.

Project description:Mapping the occupancy of FNR, HNS, and IHF throughout the genome of Escherchia coli MG1655 K-12 using an affinity purified antibody under anerobic growth conditions. We also mapped the binding of the M-CM-^_ subunit of RNA Polymerase under both aerobic and anaerobic growth conditions. As a control, we also performed ChIP-chip on FNR in a M-bM-^HM-^Ffnr mutant strain of Escherchia coli MG1655 K-12. We also examined FNR immunoprecipitation at various FNR concentrations using IPTG and Ptac::fnr (PK8263). The M-bM-^HM-^Fhns/M-bM-^HM-^FstpA strains were also used. Descirbed in the manuscript Genome-scale Analysis of E. coli FNR Reveals the Complexity of Bacterial Regulon Structure Mapping of occupancy of FNR, NNS, IHF and M-CM-^_ of RNAP in the genome of Escherchia coli MG1655 K-12 under aerobic or anaerobic growth conditions. Immunoprecipitated DNA compared to INPUT for each sample.

Project description:DNA sequence and local chromatin landscape act jointly to determine transcription factor (TF) binding intensity profiles. To disentangle these influences, we developed an experimental approach, called protein/DNA binding and high-throughput sequencing (PB-seq), that allows the binding energy landscape to be characterized genome-wide in the absence of chromatin. We applied our methods to the Drosophila Heat Shock Factor (HSF), which inducibly binds a target DNA sequence element (HSE) following heat shock stress. PB-seq involves incubating sheared naked genomic DNA with recombinant HSF, partitioning the HSF-bound and HSF-free DNA, and then detecting HSF-bound DNA by high throughput sequencing. We compared PB-seq binding profiles with ones observed in vivo by ChIP-seq, and developed statistical models to predict the observed departures from idealized binding patterns based on covariates describing the local chromatin environment. We found that DNase I hypersensitivity and tetra-acetylation of H4 were the most influential covariates in predicting changes in HSF binding affinity. We also investigated the extent to which DNA accessibility, as measured by digital DNase I footprinting data, could be predicted from MNase-seq data and the ChIP-chip profiles for many histone modifications and TFs, and found GAGA element associated factor (GAF), tetra-acetylation of H4, and H4K16 acetylation to be the most predictive covariates. Lastly, we generated an unbiased model of HSF binding sequences, which revealed distinct biophysical properties of the HSF/HSE interaction and a previously unrecognized substructure within the HSE. These findings provide new insights into the interplay between the genomic sequence and the chromatin landscape in determining transcription factor binding intensity. We performed an in vitro binding experiment with purified HSF and naked, sheared genomic Drosophila S2 DNA (PB-seq), to derive an accurate set of potential HSF binding sites in the Drosophila genome. HSF-bound DNA was specifically eluted and detected by high throughput sequencing. Drosophila HSF was N-terminally tagged with glutathione s-transferase and a tobacco etch virus (TEV) protease cleavage site. The C-terminus of the recombinant HSF was fused to the 3xFLAG epitope. Recombinant HSF was purified from E. coli with glutathione resin as previously described (PMID: 20078429) , with the following modifications: HSF-3xFLAG elution was achieved by addition of 6xHistidine tagged TEV protease and TEV protease was cleared from the HSF preparation using a Nickel-NTA column. We incubated 600pM HSF and 2500ng genomic DNA (sonicated to 100-600bp fragment size as previously described in PMID: 20844575) in 1500μl final volume of 1xHSF binding buffer and let it come to equilibrium for an hour at room temperature. We added 20μl ANTI-FLAG M2 affinity gel for 10 minutes, washed 8 times with 1xHSF binding buffer to remove unbound DNA; 3xFLAG peptide was added to a final concentration of 200ng/μl to specifically elute HSF and HSF-bound DNA. The mock IP was done in the absence of recombinant HSF.

Project description:A systems understanding of nuclear organization and events is critical for determining how cells divide, differentiate and respond to stimuli and for identifying the causes of diseases. Chromatin remodeling complexes such as SWI/SNF have been implicated in a wide variety of cellular processes including gene expression, nuclear organization, centromere function and chromosomal stability, and mutations in SWI/SNF components have been linked to several types of cancer. To better understand the biological processes in which chromatin remodeling proteins participate we globally mapped binding regions for several components of the SWI/SNF complex throughout the human genome using ChIP-Seq. SWI/SNF components were found to lie near regulatory elements integral to transcription (e.g. 5M-bM-^@M-^Y ends, RNA Polymerases II and III and enhancers) as well as regions critical for chromosome organization (e.g. CTCF, lamins and DNA replication origins). To further elucidate the association of SWI/SNF subunits with each other as well as with other nuclear proteins we also analyzed SWI/SNF immunoprecipitated complexes by mass spectrometry. Individual SWI/SNF factors are associated with their own family members as well as with cellular constituents such as nuclear matrix proteins, key transcription factors and centromere components implying a ubiquitous role in gene regulation and nuclear function. We find an overrepresentation of both SWI/SNF-associated regions and proteins in cell cycle and chromosome organization. Taken together the results from our ChIP and immunoprecipitation experiments suggest that SWI/SNF facilitates gene regulation and genome function more broadly and through a greater diversity of interactions than previously appreciated. ChIP-Seq analysis of the SWI/SNF subunits Ini1, Brg1, BAF155 and BAF170 in HeLa S3 cells

Project description:This SuperSeries is composed of the following subset Series: GSE41936: Rho and NusG suppress pervasive antisense transcription in Escherichia coli [ChIP-chip]. GSE41938: Rho and NusG suppress pervasive antisense transcription in Escherichia coli [tiling array]. GSE41939: Rho and NusG suppress pervasive antisense transcription in Escherichia coli [RNA-seq]. Refer to individual Series

Project description:Tumor suppressor p53 and its related proteins, p63 and p73, can be synthesized as multiple isoforms lacking part of the N- or C-terminal regions. Specifically, high expression of the Np73 isoform is notoriously associated with poor prognosis in cancer. Here, we have performed proteomics analysis of Np73 using as a cellular model human papillomavirus type 38-transformed keratinocytes (38HK) that express high levels of this isoform. We find that Np73 associates with the E2F4/p130 repressor complex through a direct interaction with E2F4. Remarkably, this interaction is favored by the N-terminal truncation of p73 characteristic of Np73 isoforms and is independent of the C-terminal splicing status. We show that the Np73-E2F4/p130 complex is recruited to the promoters of specific genes, thereby enforcing inhibition of their expression both in 38HK and in cancer-derived cell lines. Consistently, silencing of E2F4 in 38HK and in cancer cells resulted in induction of senescence. In conclusion, we have identified and characterized a novel transcriptional regulatory complex that exerts pro-proliferative functions in transformed cells