Project description:We performed streptavidin pulldown sequencing of endogenously and exogenously Avi-tagged FOXD3 to determine genome-wide binding pattern of this transcription factor in asynchronous or cell cycle synchronized naive mouse ESCs.

Project description:DNA replication checkpiont kinase rad3 (human ATM/ATR-like kinase) and cds1 (human CHK2-like kinase) are known to restore stalled replication forks and prevent subsequent cell cycle progression during a replication block imposed by HU-treatment in fission yeast. In order to identify cell cycle-specific exression which are modulated by replication checkpoint kinase rad3 and cds1, microarray approach was used to profile asynchronous and synchronous cells of wildtype and mutants treated and untreated with HU Keywords: HU treated cells vs wildtype untreated cells

Project description:DNA replication checkpiont kinase rad3 (human ATM/ATR-like kinase) and cds1 (human CHK2-like kinase) are known to restore stalled replication forks and prevent subsequent cell cycle progression during a replication block imposed by HU-treatment in fission yeast. In order to identify cell cycle-specific exression which are modulated by replication checkpoint kinase rad3 and cds1, microarray approach was used to profile asynchronous and synchronous cells of wildtype and mutants treated and untreated with HU Keywords: HU treated cells vs wildtype untreated cells

Project description:For rapid characterisation of replication dynamics in wild-type cells from an unperturbed cell cycle we have obtained replicating (S phase) and non-replicating (G2 phase) cells by fluorescence activated cell sorting (FACS) and subjected the DNA to copy number analysis. Measurement of genome replication time for various S. cerevisiae strains. For each strain two samples were analysed: a replicating sample (from S phase) and a non-replicating sample (from G2 phase).

Project description:For rapid characterisation of replication dynamics in wild-type cells from an unperturbed cell cycle we have obtained replicating (S phase) and non-replicating (G2 phase) cells by fluorescence activated cell sorting (FACS) and subjected the DNA to copy number analysis.

Project description:Genome replication follows a defined temporal programme that can change during cellular differentiation and disease onset. DNA replication results in an increase in DNA copy number that can be measured by high-throughput sequencing (HTS). Here we present a protocol to determine genome replication dynamics using DNA copy number measurements. Cell populations can be obtained in three variants of the method. First, sort-seq uses fluorescence activated cell sorting (FACS) to isolate replicating and non-replicating subpopulations from asynchronous cells. Second, sync-seq uses cell synchronisation to obtain samples before and during DNA replication. Third, marker frequency analysis (MFA-seq) assesses copy number differences in rapidly replicating asynchronous cells. These approaches have been used to reveal genome replication dynamics in prokaryotes, archaea, and a wide range of eukaryotes, including mammalian cells. The whole protocol can be performed in 7-10 days.

Project description:E. coli and many other bacterial species can alternate their cell cycle according to nutrient availability. As a result, they grow and divide very fast under optimal conditions or slow down the cell cycle when conditions deteriorate. This adaptability is underlined by mechanisms coordinating cell growth with duplication of genetic material and cell division. Several mechanisms regulating DNA replication process in E. coli have been described so far with biochemical details, nevertheless we still don’t fully understand the source of remarkable precision that bacterial cells coordinate their growth and chromosome replication with. To shed light on regulation of E. coli DNA replication at systemic level, we used affinity purification coupled with mass spectrometry (AP-MS) to characterize protein-protein interactions (PPIs) formed by key E. coli replication proteins, under disparate bacterial growth conditions and phases. We present the resulting dynamic replication protein interaction network (PIN) and highlight links between DNA replication and several cellular processes, like outer membrane synthesis, RNA degradation and modification or starvation response.

Project description:The past twenty years have seen tremendous advances in our understanding of the mechanisms underlying bacterial cytokinesis, particularly the composition of the division machinery and the factors controlling its assembly. At the same time, however, we understand very little about the relationship between cell division and other cell cycle events in bacteria. Here we report that inhibiting division in Bacillus subtilis and Staphylococcus aureus quickly leads to an arrest in the initiation of new rounds of DNA replication followed by a complete arrest in cell growth. Arrested cells are metabolically active but unable to initiate new rounds of either DNA replication or division when shifted to permissive conditions. Inhibiting DNA replication results in entry into a similar quiescent state, in which cells are unable to resume growth or division when returned to permissive conditions. Our findings suggest the presence of two cell cycle control points: one linking division to the initiation of DNA replication and another linking the initiation of DNA replication to division. Significantly, this evidence contradicts the prevailing view of the bacterial cell cycle as a series of coordinated but uncoupled events. Importantly, the terminal nature of the cell cycle arrest validates the bacterial cell cycle machinery as an effective target for antimicrobial development.

Project description:au13-11_gravity - gravity - Cell cycle and cell proliferation are decoupled under altered gravity conditions. We have previously shown that semisolid cell cultures of Arabidopsis suffer overall genome changes in response to altered gravity and also that cell cycle stages duration is altered. By using synchronized cell cultures we will demonstrate the precise alterations in cell cycle duration and also the transcriptional signature in any of them. - Experiments consists on exposures of Arabidopsis cell cultures to 1g control/simulated microgravity (RPM) conditions. Asynchronous cells exposed for 14 h + Syncronous populations choosen to have an enrichment of cell cycle phases were used (being T7/T10 samples on G2 phase, T14/T16 samples on G1 phase). 6 dye-swap - time course,treated vs untreated comparison

Project description:The cellular and nuclear states are constantly changing and closely linked to DNA replication and cell division, defining cell cycle phases. Pharmacological inhibition is a widely used strategy to enrich for specific phases to study them in isolation. However, it is important to understand how synchronization influences chromatin openness and gene expression compared to unperturbed cell cycle states. Here, we use an integrated approach to obtain G1, S and G2/M phases from mouse embryonic stem cells (mESC) and to profile their chromatin accessibility and marks as well as steady and nascent transcripts levels. We demonstrate that synchronization with thymidine and nocodazole leads to dramatic changes in chromatin compaction and gene expression, which only partially resemble bona fide cell cycle-dependent differences. Blocking with CDK1 inhibitor results in efficient synchronization and evokes moderate changes in chromatin accessibility, resembling G2/M phase. Correlative analysis suggests that cell cycle-specific variations in chromatin openness in unperturbed mESCs are mediated by CDK1 substrates and CTCF. This integrated strategy can be applied to most cultured cell lines under any conditions and holds the potential to further our understanding of cell cycle-dependent susceptibility to external cues and chromatin regulation.