Project description:N-terminal coding sequences (NCS) are key regulatory elements for fine-tuning gene expression during translation initiation, the rate-limiting step of translation. However, due to complex combinatory effects of NCS biophysical factors and endogenous regulation, designing NCS remains challenging. Herein, we implemented multi-view learning strategy for model-driven generation of synthetic NCS for Saccharomyces cerevisiae and Bacillus subtilis, which are model microorganisms widely used in the laboratory and industry.

Project description:Dramatic change in DNA methylation patterns and levels both globally and/or locus-specifically is associated with the process of cell lineage specification and somatic reprogramming. We found the expression of DNA methyltransferase 1 (Dnmt1), the enzyme that maintains 5-methylcytosine (5mC) after DNA replication, is tightly regulated by the progression of cell cycle. Upregulation of Dnmt1 was observed in cells with shortened G1 and G2 phase. We hypothesize that 5mC level is not completely recovered by Dnmt1 immediately after DNA replication. In the attempt to clarify DNA methylation status before and after DNA replication, we performed Whole Genome Bisulfite Sequencing (WGBS) to map genome-wide DNA methylation separately in G1 and G2 phase of mouse embryonic fibroblasts (MEFs). Cells of different cell cycle phases were sorted by flow cytometry after Propidium iodide (PI) staining. We find an average of 2% decrease of global DNA methylation in G2 phase compared with G1, with the trend more magnificent in high CpG density regions. Generally, the results indicate that the G1 phase of cell cycle is an important time window for the stability of DNA methylation inheritance.

Project description:Primary outcome(s): The regional/distant metastasis rate and the risk factors of the colorectal neuroendocrine tumor G1 / G2 based on the 2010 WHO classification.

Project description:The retinoblastoma tumour suppressor, Rb, has two major functions. First, it represses genes whose products are required for S-phase entry and progression, thus stabilizing cells in G1. Second, Rb synergizes with factors that induce cell cycle exit and terminal differentiation. Dictyostelium lacks a G1 phase in its cell cycle but it has a retinoblastoma orthologue, rblA. Using mRNA-Seq transcriptional profiling, we show that rblA strongly represses hundreds of genes whose products are involved in S-phase and mitosis. Both S-phase and mitotic genes are expressed at a single point in late G2 and again in mid-development, near the time when cell cycling is reactivated. RblA also activates a set of genes unique to slime moulds that function in terminal differentiation. Like its mammalian counterpart, Dictyostelium RblA plays a dual role, regulating cell cycle progression and transcriptional events leading to terminal differentiation. In the absence of a G1 phase, however, RblA functions in late G2 controlling the expression of both S-phase and mitotic genes.

Project description:The retinoblastoma tumour suppressor, Rb, has two major functions. First, it represses genes whose products are required for S-phase entry and progression, thus stabilizing cells in G1. Second, Rb synergizes with factors that induce cell cycle exit and terminal differentiation. Dictyostelium lacks a G1 phase in its cell cycle but it has a retinoblastoma orthologue, rblA. Using mRNA-Seq transcriptional profiling, we show that rblA strongly represses hundreds of genes whose products are involved in S-phase and mitosis. Both S-phase and mitotic genes are expressed at a single point in late G2 and again in mid-development, near the time when cell cycling is reactivated. RblA also activates a set of genes unique to slime moulds that function in terminal differentiation. Like its mammalian counterpart, Dictyostelium RblA plays a dual role, regulating cell cycle progression and transcriptional events leading to terminal differentiation. In the absence of a G1 phase, however, RblA functions in late G2 controlling the expression of both S-phase and mitotic genes. RNA was isolated from an rblA-disruptant and the parental strain when the cells were vegetatively growing or while the cells were developing (at the early culminant stage). Total RNA was also isolated from wild type cells synchronized using the cold-shock protocol (Maeda, J Gen Microbiol 132:1189-1196 (1986)). T0 to T13 represent the hours after the shift up from 9.5C to 22C, a regime that synchronizes the cells in the cell cycle.

Project description:This is a multicentre long-term non-interventional study of adult subjects diagnosed with unresectable or metastatic, progressive, well differentiated (G1 and G2), somatostatin receptor positive GEP-NETs who have been prescribed Lutathera in standard clinical practice.

Project description:We generated EPB41L5 WT and KO podocytes to model human glomerular kidney disease in vitro. Immortalized human podocytes were genome edited applying the CRISPR/Cas9 technique. Two monoclonal cell lines were generated for WT and KO genotypes (WT-1, WT-2, KO-1 & KO-2). Transcriptome profiling (RNA-Sequencing) and differential gene expression analysis was performed in duplicate for each cell line. EPB41L5 KO podocytes exhibit transcriptional changes compared to WT cells. Analyzed cell were previously described: Schell C, Rogg M, Suhm M, et al. The FERM protein EPB41L5 regulates actomyosin contractility and focal adhesion formation to maintain the kidney filtration barrier. Proc Natl Acad Sci U S A. 2017;114(23):E4621-E4630. doi:10.1073/pnas.1617004114

Project description:ChIP-on-chip of Cdc45 in synchronized cells operating with the analog-sensitive CDK fusion protein (Cdc13-Cdc2). Cells were released from a G2 block or from a G2 block followed by an extended G1 (G1+ 15 min extension). For the G2 block, samples were collected 30 minutes after release. For the G1+15 extension, samples were collected 3 minutes after release. Timepoint of collection was based on qPCR experiments showing Cdc45 binding at origins of replication.

Project description:Proteomic data from three populations of sorted murine podocytes using the FUCCI (fluorescence ubiquitination cell cycle indicator) Cell Cycle Sensor: Wild-Type podocytes at G0 (WT_G0), Alport Syndrome podocytes at G0 (AS_G0), and Alport Syndrome podocytes at G1 (AS_G1). Cell populations were sorted from murine kidney; ~10K cells were prepared using the MicroPOTS protocol (PMID: 30460388), digested with trypsin, then analyzed by LC-MS/MS. Data was searched with MaxQuant.

Project description:Endothelial cells derived from hESCs were separated into 4 different cell cycle phases via FACS and sequenced (i.e., early G1, late G1, G1/S, S/G2/M)