Project description:Poly(A)-tail length and mRNA deadenylation play important roles in post-transcriptional gene regulation. Here, we report the regulation of mRNA expression, half-life, and polysome association in mouse embryonic stem cells by the Cnot3 subunit in the Ccr4-Not mRNA deadenylase complex. To determine the consequence of Cnot3 deletion, Cnot3 conditional knockout ESCs were first treated with DMSO (WT) or 0.1μM 4-hydroxytamoxifen (4OHT, KO). 1. In one experiment, cells were collected 3 days after the 4OHT treatment and total RNAs were extracted and sequenced to determine changes in mRNA expression. 2. In the second experiment, cells were collected 3 days after the 4OHT treatment and polysome-associated RNAs were fractionated using a published protocol, purified, and sequenced to determine changes in polysome-association. 3. In the third experiment, cells were further treated with actinomycin D (10ug/ml) 2 days after the initial 4OHT treatment. Cells were collected at 0, 4, 8 hrs after actinomycin D treatment and total RNAs were extracted and sequenced to determine changes in mRNA half-life. Two biological replicates were carried out for each experiment. RNAs were extracted using RNA purification kits from Life Technologies, and RNA-seq libraries were prepared using Illumina TruSeq RNA library preparation kit.

Project description:Poly(A)-tail length and mRNA deadenylation play important roles in post-transcriptional gene regulation. Here, we report the regulation of mRNA expression, half-life, and polysome association in mouse embryonic stem cells by the Cnot3 subunit in the Ccr4-Not mRNA deadenylase complex.

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Project description:Chromosomes have an intrinsic tendency to segregate into compartments, forming long-distance contacts between loci of similar chromatin states. How genome compartmentalization is regulated remains elusive. Here, comparison of mouse ground-state embryonic stem cells (ESCs) characterized by open and active chromatin, and advanced serum ESCs with a more closed and repressed genome, reveals distinct regulation of their genome organization due to differential dependency on BAZ2A/TIP5, a component of the chromatin remodeling complex NoRC. On ESC chromatin, BAZ2A interacts with SNF2H, DNA topoisomerase 2A (TOP2A) and cohesin. BAZ2A associates with chromatin subdomains within the active A compartment, which intersect through long-range contacts. We found that ground-state chromatin selectively requires BAZ2A to limit the invasion of active domains into repressive compartments. BAZ2A depletion increases chromatin accessibility at B compartments. Furthermore, BAZ2A regulates H3K27me3 genome occupancy in a TOP2A-dependent manner. Finally, ground-state ESCs require BAZ2A for growth, differentiation, and correct expression of developmental genes. Our results uncover the propensity of open chromatin domains to invade repressive domains, which is counteracted by chromatin remodeling to establish genome partitioning and preserve cell identity.