Project description:The Structural Maintenance of Chromosomes (SMC) complexes regulate the chromosome structures essential for proper genome regulation and cell viability. In mammals, the coordinated actions of the SMC complexes condensin I, condensin II and cohesin regulate dynamic chromosome structures throughout the cell cycle, but it is not clear how these complexes are positioned across the genome. We report here that condensin I, condensin II and cohesin occupy active euchromatic regions of the embryonic stem cell genome, but not heterochromatic regions. Like cohesin, we find that condensin II is deposited at active genes by the SMC loading factor Nipbl. The recruitment of Condensin II to active genes is dependent on their transcriptional activation. Subsequent transcriptional elongation by RNA polymerase II distributes condensin II across gene bodies. During mitosis, condensin I occupies the same set of active genes occupied by condensin II during interphase. Thus, SMC complexes are positioned in the genome by transcription-dependent processes, indicating that condensin-dependent condensation mechanisms are preferentially utilized in euchromatic regions. RNA-seq in mES cells after known-down of Smc1, CapH2 or Smc2.

Project description:Condensin molecules are loaded onto the genome to mediate essential changes in chromosome condensation during mitosis, but it is not clear why there are two forms of vertebrate condensin that become differentially distributed on chromosomes. We report here that condensin II, the form of condensin present in the nucleus throughout the cell cycle, functions specifically at active genes. Condensin II is loaded at transcriptionally active promoters in embryonic stem cells (ESCs), migrates through these genes in a transcription-dependent fashion and accumulates in transcription termination regions. Unlike cohesin, which is also loaded at active promoters, condensin II has little influence on transcription. We conclude that condensin II is loaded and distributed across actively transcribed chromatin and thus serves to specifically condense this euchromatic portion of chromosomes during the cell division cycle. ChIP-Seq data for Condensin II and Cohesin in v6.5 ESCs treated or not with the RNA polymerase II elongation inhibitor flavopiridol.

Project description:The Structural Maintenance of Chromosomes (SMC) complexes regulate the chromosome structures essential for proper genome regulation and cell viability. In mammals, the coordinated actions of the SMC complexes condensin I, condensin II and cohesin regulate dynamic chromosome structures throughout the cell cycle, but it is not clear how these complexes are positioned across the genome. We report here that condensin I, condensin II and cohesin occupy active euchromatic regions of the embryonic stem cell genome, but not heterochromatic regions. Like cohesin, we find that condensin II is deposited at active genes by the SMC loading factor Nipbl. The recruitment of Condensin II to active genes is dependent on their transcriptional activation. Subsequent transcriptional elongation by RNA polymerase II distributes condensin II across gene bodies. During mitosis, condensin I occupies the same set of active genes occupied by condensin II during interphase. Thus, SMC complexes are positioned in the genome by transcription-dependent processes, indicating that condensin-dependent condensation mechanisms are preferentially utilized in euchromatic regions.

Project description:The precise control of gene expression programs is critical for maintenance of cell state in emryonic stem cells. Cohesin has been shown to play an important role in maintaining gene expression programs by contributing to DNA loops between enhancers and promoters of active genes. The influence of condensin on gene expression is not well understood. We used microarrays to detail the changes to the global gene expression program of mouse embryonic stem cells upon depletion of cohesin or condensin II.

Project description:The precise control of gene expression programs is critical for maintenance of cell state in emryonic stem cells. Cohesin has been shown to play an important role in maintaining gene expression programs by contributing to DNA loops between enhancers and promoters of active genes. The influence of condensin on gene expression is not well understood. We used microarrays to detail the changes to the global gene expression program of mouse embryonic stem cells upon depletion of cohesin or condensin II. Mouse embryonic stem cells were treated with shRNA constructs targeting CapH2 (2 hairpins), Smc2 (2 hairpins), Smc1 (1 hairpin, 2 biological replicates) and GFP control (1 hairpin, 2 biological replicates) for a total of 8 samples. After 5 days RNA was extracted from the depleted cells and hybridized to Affymetrix microarrays.

Project description:Cohesin is a well-known mediator of sister chromatid cohesion, but it also influences gene expression and development. These non-canonical roles of cohesin are not well understood, but are vital: gene expression and development are altered by modest changes in cohesin function that do not disrupt chromatid cohesion. To clarify cohesinM-bM-^@M-^Ys roles in transcription, we measured how cohesin controls RNA polymerase II (Pol II) activity by genome-wide chromatin immunoprecipitation and precision global run-on sequencing. On average, cohesin-binding genes have more transcriptionally active Pol II and promoter-proximal Pol II pausing than non-binding genes, and are more efficient, producing higher steady state levels of mRNA per transcribing Pol II complex. Cohesin depletion frequently increases pausing at cohesin-binding genes, indicating that cohesin often facilitates transition of paused Pol II to elongation. In many cases this likely reflects a role for cohesin in transcriptional enhancer function. Strikingly, more than 95% of predicted extragenic enhancers bind cohesin, and cohesin depletion can reduce their association with Pol II, indicating that cohesin facilitates enhancer-promoter contact. Cohesin directly promotes transcription of the myc gene, and cohesin depletion reduces Pol II activity at most Myc target genes. The multiple transcriptional roles of cohesin revealed by these studies likely underlie the growth and developmental deficits caused by minor changes in cohesin activity. We performed ChIP-chip of Rpb3 (representing total Pol II), Ser2P-Pol II (representing elongating Pol II), and Cdk12 and CycT Pol II kinase components in Mock RNAi-treated and cohesin subunit Rad21 RNAi-treated ML-DmBG3-c2 cells, which revealed that cohesin depletion has a variety of effects on Pol II occupancy and modification, as well as on occupancy of Pol II kinases.

Project description:Cohesin is a well-known mediator of sister chromatid cohesion, but it also influences gene expression and development. These non-canonical roles of cohesin are not well understood, but are vital: gene expression and development are altered by modest changes in cohesin function that do not disrupt chromatid cohesion. To clarify cohesin’s roles in transcription, we measured how cohesin controls RNA polymerase II (Pol II) activity by genome-wide chromatin immunoprecipitation and precision global run-on sequencing. On average, cohesin-binding genes have more transcriptionally active Pol II and promoter-proximal Pol II pausing than non-binding genes, and are more efficient, producing higher steady state levels of mRNA per transcribing Pol II complex. Cohesin depletion frequently increases pausing at cohesin-binding genes, indicating that cohesin often facilitates transition of paused Pol II to elongation. In many cases this likely reflects a role for cohesin in transcriptional enhancer function. Strikingly, more than 95% of predicted extragenic enhancers bind cohesin, and cohesin depletion can reduce their association with Pol II, indicating that cohesin facilitates enhancer-promoter contact. Cohesin directly promotes transcription of the myc gene, and cohesin depletion reduces Pol II activity at most Myc target genes. The multiple transcriptional roles of cohesin revealed by these studies likely underlie the growth and developmental deficits caused by minor changes in cohesin activity. The PRO-seq method was used to measure transcriptionally engaged Pol II genome-wide in two replicates each of mock RNAi-treated, Nipped-B RNAi-treated, and Rad21 RNAi-treated ML-DmBG3-c2 cells.

Project description:Condensin molecules are loaded onto the genome to mediate essential changes in chromosome condensation during mitosis, but it is not clear why there are two forms of vertebrate condensin that become differentially distributed on chromosomes. We report here that condensin II, the form of condensin present in the nucleus throughout the cell cycle, functions specifically at active genes. Condensin II is loaded at transcriptionally active promoters in embryonic stem cells (ESCs), migrates through these genes in a transcription-dependent fashion and accumulates in transcription termination regions. Unlike cohesin, which is also loaded at active promoters, condensin II has little influence on transcription. We conclude that condensin II is loaded and distributed across actively transcribed chromatin and thus serves to specifically condense this euchromatic portion of chromosomes during the cell division cycle.

Project description:Condensin II plays a crucial role in shaping chromosome structure throughout the cell cycle, but its specific functions during interphase have remained unclear. In this study, we utilized Oligopaints and Hi-C techniques to investigate how changes in condensin II levels affect chromosome organization across various length scales. Our findings reveal that condensin II has a significant impact on long-range interactions within chromosomes, which are essential for the organization of intrachromosomal compartments. Importantly, these effects occur independently of the chromatin state. Furthermore, overexpression of condensin II during interphase leads to the formation of "peri-centric super stripes" observed through Hi-C analysis, indicating a disruption of the boundary between heterochromatin and euchromatin on Drosophila chromosomes. Collectively, our results challenge the existing belief that compartments form without the involvement of a loop extruder and suggest that condensin II activity is a prerequisite for driving proximity between distal compartmental domains within chromosomes.

Project description:Condensin II plays a crucial role in shaping chromosome structure throughout the cell cycle, but its specific functions during interphase have remained unclear. In this study, we utilized Oligopaints and Hi-C techniques to investigate how changes in condensin II levels affect chromosome organization across various length scales. Our findings reveal that condensin II has a significant impact on long-range interactions within chromosomes, which are essential for the organization of intrachromosomal compartments. Importantly, these effects occur independently of the chromatin state. Furthermore, overexpression of condensin II during interphase leads to the formation of "peri-centric super stripes" observed through Hi-C analysis, indicating a disruption of the boundary between heterochromatin and euchromatin on Drosophila chromosomes. Collectively, our results challenge the existing belief that compartments form without the involvement of a loop extruder and suggest that condensin II activity is a prerequisite for driving proximity between distal compartmental domains within chromosomes.