Project description:We analyzed Hi-C, HiChIP, Ocean-C, RNA-seq, ATAC-seq, ChIP-seq and 4C-seq data to provide the most comprehensive evidence to date to demonstrate that transcription plays a marginal role in organizing the 3D genome in mammalian cells: 1) degraded Pol I, Pol II and Pol III proteins in mESCs, and showed their loss results in little or no changes of global 3D chromatin structures for the first time; 2) selected RNA polymerases high abundance binding sites-associated interactions and found they still persist after the degradation; 3) generated higher resolution chromatin interaction maps and revealed that transcription inhibition mildly alters small loop domains; 4) identified Pol II bound but CTCF and Cohesin unbound loops and disclosed that they are largely resistant to transcription inhibition Interestingly, we found that Pol II depletion for a longer time significantly affects the chromatin accessibility and Cohesin occupancy, suggesting RNA polymerases are capable of affecting the 3D genome indirectly. So, the direct and indirect effects of transcription inhibition explain the previous confusing effects on the 3D genome. We conclude that Pol I, Pol II, and Pol III loss only mildly alter chromatin interactions in mammalian cells, suggesting the 3D chromatin structures are preestablished and relatively stable.

Project description:Genome binding/occupancy profiling by high throughput sequencing ｜ Expression profiling by high throughput sequencing | Other We analyzed Hi-C, HiChIP, Ocean-C, RNA-seq, ATAC-seq, ChIP-seq and 4C-seq data to provide the most comprehensive evidence to date to demonstrate that transcription plays a marginal role in organizing the 3D genome in mammalian cells: 1) degraded Pol I, Pol II and Pol III proteins in mESCs, and showed their loss results in little or no changes of global 3D chromatin structures for the first time; 2) selected RNA polymerases high abundance binding sites-associated interactions and found they still persist after the degradation; 3) generated higher resolution chromatin interaction maps and revealed that transcription inhibition mildly alters small loop domains; 4) identified Pol II bound but CTCF and Cohesin unbound loops and disclosed that they are largely resistant to transcription inhibition Interestingly, we found that Pol II depletion for a longer time significantly affects the chromatin accessibility and Cohesin occupancy, suggesting RNA polymerases are capable of affecting the 3D genome indirectly. So, the direct and indirect effects of transcription inhibition explain the previous confusing effects on the 3D genome. We conclude that Pol I, Pol II, and Pol III loss only mildly alter chromatin interactions in mammalian cells, suggesting the 3D chromatin structures are preestablished and relatively stable.

Project description:Genome binding/occupancy profiling by high throughput sequencing ｜ Expression profiling by high throughput sequencing | Other We analyzed Hi-C, HiChIP, Ocean-C, RNA-seq, ATAC-seq, ChIP-seq and 4C-seq data to provide the most comprehensive evidence to date to demonstrate that transcription plays a marginal role in organizing the 3D genome in mammalian cells: 1) degraded Pol I, Pol II and Pol III proteins in mESCs, and showed their loss results in little or no changes of global 3D chromatin structures for the first time; 2) selected RNA polymerases high abundance binding sites-associated interactions and found they still persist after the degradation; 3) generated higher resolution chromatin interaction maps and revealed that transcription inhibition mildly alters small loop domains; 4) identified Pol II bound but CTCF and Cohesin unbound loops and disclosed that they are largely resistant to transcription inhibition Interestingly, we found that Pol II depletion for a longer time significantly affects the chromatin accessibility and Cohesin occupancy, suggesting RNA polymerases are capable of affecting the 3D genome indirectly. So, the direct and indirect effects of transcription inhibition explain the previous confusing effects on the 3D genome. We conclude that Pol I, Pol II, and Pol III loss only mildly alter chromatin interactions in mammalian cells, suggesting the 3D chromatin structures are preestablished and relatively stable.

Project description:Genome binding/occupancy profiling by high throughput sequencing ｜ Expression profiling by high throughput sequencing | Other We analyzed Hi-C, HiChIP, Ocean-C, RNA-seq, ATAC-seq, ChIP-seq and 4C-seq data to provide the most comprehensive evidence to date to demonstrate that transcription plays a marginal role in organizing the 3D genome in mammalian cells: 1) degraded Pol I, Pol II and Pol III proteins in mESCs, and showed their loss results in little or no changes of global 3D chromatin structures for the first time; 2) selected RNA polymerases high abundance binding sites-associated interactions and found they still persist after the degradation; 3) generated higher resolution chromatin interaction maps and revealed that transcription inhibition mildly alters small loop domains; 4) identified Pol II bound but CTCF and Cohesin unbound loops and disclosed that they are largely resistant to transcription inhibition Interestingly, we found that Pol II depletion for a longer time significantly affects the chromatin accessibility and Cohesin occupancy, suggesting RNA polymerases are capable of affecting the 3D genome indirectly. So, the direct and indirect effects of transcription inhibition explain the previous confusing effects on the 3D genome. We conclude that Pol I, Pol II, and Pol III loss only mildly alter chromatin interactions in mammalian cells, suggesting the 3D chromatin structures are preestablished and relatively stable.

Project description:Genome binding/occupancy profiling by high throughput sequencing ｜ Expression profiling by high throughput sequencing | Other We analyzed Hi-C, HiChIP, Ocean-C, RNA-seq, ATAC-seq, ChIP-seq and 4C-seq data to provide the most comprehensive evidence to date to demonstrate that transcription plays a marginal role in organizing the 3D genome in mammalian cells: 1) degraded Pol I, Pol II and Pol III proteins in mESCs, and showed their loss results in little or no changes of global 3D chromatin structures for the first time; 2) selected RNA polymerases high abundance binding sites-associated interactions and found they still persist after the degradation; 3) generated higher resolution chromatin interaction maps and revealed that transcription inhibition mildly alters small loop domains; 4) identified Pol II bound but CTCF and Cohesin unbound loops and disclosed that they are largely resistant to transcription inhibition Interestingly, we found that Pol II depletion for a longer time significantly affects the chromatin accessibility and Cohesin occupancy, suggesting RNA polymerases are capable of affecting the 3D genome indirectly. So, the direct and indirect effects of transcription inhibition explain the previous confusing effects on the 3D genome. We conclude that Pol I, Pol II, and Pol III loss only mildly alter chromatin interactions in mammalian cells, suggesting the 3D chromatin structures are preestablished and relatively stable.

Project description:Genome binding/occupancy profiling by high throughput sequencing ｜ Expression profiling by high throughput sequencing | Other We analyzed Hi-C, HiChIP, Ocean-C, RNA-seq, ATAC-seq, ChIP-seq and 4C-seq data to provide the most comprehensive evidence to date to demonstrate that transcription plays a marginal role in organizing the 3D genome in mammalian cells: 1) degraded Pol I, Pol II and Pol III proteins in mESCs, and showed their loss results in little or no changes of global 3D chromatin structures for the first time; 2) selected RNA polymerases high abundance binding sites-associated interactions and found they still persist after the degradation; 3) generated higher resolution chromatin interaction maps and revealed that transcription inhibition mildly alters small loop domains; 4) identified Pol II bound but CTCF and Cohesin unbound loops and disclosed that they are largely resistant to transcription inhibition Interestingly, we found that Pol II depletion for a longer time significantly affects the chromatin accessibility and Cohesin occupancy, suggesting RNA polymerases are capable of affecting the 3D genome indirectly. So, the direct and indirect effects of transcription inhibition explain the previous confusing effects on the 3D genome. We conclude that Pol I, Pol II, and Pol III loss only mildly alter chromatin interactions in mammalian cells, suggesting the 3D chromatin structures are preestablished and relatively stable.

Project description:Genome binding/occupancy profiling by high throughput sequencing ｜ Expression profiling by high throughput sequencing | Other We analyzed Hi-C, HiChIP, Ocean-C, RNA-seq, ATAC-seq, ChIP-seq and 4C-seq data to provide the most comprehensive evidence to date to demonstrate that transcription plays a marginal role in organizing the 3D genome in mammalian cells: 1) degraded Pol I, Pol II and Pol III proteins in mESCs, and showed their loss results in little or no changes of global 3D chromatin structures for the first time; 2) selected RNA polymerases high abundance binding sites-associated interactions and found they still persist after the degradation; 3) generated higher resolution chromatin interaction maps and revealed that transcription inhibition mildly alters small loop domains; 4) identified Pol II bound but CTCF and Cohesin unbound loops and disclosed that they are largely resistant to transcription inhibition Interestingly, we found that Pol II depletion for a longer time significantly affects the chromatin accessibility and Cohesin occupancy, suggesting RNA polymerases are capable of affecting the 3D genome indirectly. So, the direct and indirect effects of transcription inhibition explain the previous confusing effects on the 3D genome. We conclude that Pol I, Pol II, and Pol III loss only mildly alter chromatin interactions in mammalian cells, suggesting the 3D chromatin structures are preestablished and relatively stable.

Project description:Transcription of the eukaryotic genomes is carried out by three distinct RNA polymerases I, II and III whereby each polymerase is thought to independently transcribe a distinct set of genes. To investigate a possible relationship of RNA polymerases II and III we mapped their in vivo binding sites throughout the human genome using ChIP Seq in two different cell lines, GM12878 and K562 cells. Pol III was found to bind near many known genes as well as several novel genes. RNA-Seq studies indicate that majority of the genes are expressed although a subset are not suggestive of stalling by RNA polymerase III. Pol II was found to bind near many known Pol III genes, including tRNA, U6, HVG, hY and 7SK and novel Pol III genes. Similarly, in vivo binding studies also reveal that a number of transcription factors normally associated with Pol II transcription, including c-Fos, c-Jun and c-Myc, also tightly associate with most Pol III transcribed genes. Inhibition of Pol II activity using ?-amanitin reduced expression of a number of Pol III genes (e.g. U6, hY, HVG), suggesting that Pol II plays an important role in regulating their transcription. These results indicate that, contrary to previous expectations, polymerases can often work with one another to globally coordinate gene expression. For data usage terms and conditions, please refer to http://www.genome.gov/27528022 and http://www.genome.gov/Pages/Research/ENCODE/ENCODEDataReleasePolicyFinal2008.pdf This SuperSeries is composed of the SubSeries listed below.

Project description:Polymerases IV and V affect Pol II transcription termination

Project description:Vegetative cells of B. subtilis can recover from injury caused by high hydrostatic pressure (HHP) treatment at 250 MPa. DNA microarray analysis revealed that many ribosomal genes and translation relating factors (e.g. translation initiation factors) were induced during a growth-arrested phase after the HHP treatment. Expression of cold shock-responsive genes, whose products play key roles for efficient translation, and heat shock-responsive genes, whose product mediates the correct protein folding or degrades misfolded proteins, were also induced. In contrast, the expression of hpf, whose product (Hpf) is involved in ribosome inactivation through dimerization of 70S ribosomes, was repressed. Sucrose density gradient sedimentation analysis showed that ribosomes were dissociated in a pressure-dependent manner and then reconstructed during the growth-arrested phase. These results suggested that the translational machinery can be preferentially reconstructed in the HHP-injured cells. We also found that cell growth after HHP-induced injury was apparently inhibited by Mn2+ or Zn2+ supplemented to the recovery medium. Ribosome reconstruction in HHP-injured cells was significantly delayed in the presence of Mn2+ or Zn2+. Moreover, Zn2+ but not Mn2+ stimulated dimer formation of ribosomes in HHP-injured cells. This Zn2+-dependent accumulation of ribosome dimer was no longer observed in a Δhpf mutant lacking the functional Hpf. Furthermore, the growth recovery of the Δhpf mutant in the Zn2+-supplemented medium was faster than that of the parent strain. Thus, our results indicate that Zn2+ can prevent ribosome reconstruction by stimulating the Hpf-dependent ribosome dimerization, thereby inhibiting the growth recovery of the HHP-injured B. subtilis cells.