Project description:Two mitotic Cyclins, A and B, exist in higher eukaryotes, but their specialised functions in mitosis are poorly understood. Using degron tags we analyse how acute depletion of these proteins affects mitosis. Loss of Cyclin A in G2-phase prevents the initial activation of Cdk1. Cells lacking Cyclin B can enter mitosis and phosphorylate most mitotic proteins, because of parallel PP2A:B55 phosphatase inactivation by Greatwall kinase. The final barrier to mitotic establishment corresponds to nuclear envelope breakdown that requires a decisive shift in the balance of Cdk1 and PP2A:B55 activity. Beyond this point Cyclin B/Cdk1 is essential to phosphorylate a distinct subset mitotic Cdk1 substrates that are essential to complete cell division. Our results identify how Cyclin A, B and Greatwall coordinate mitotic progression by increasing levels of Cdk1-dependent substrate phosphorylation. The phosphoproteomics dataset aims to identify substrates that are affected specifically by acute depletion of Cyclin Bprotein.

Project description:Chromatin organization must be maintained during cell proliferation to preserve cellular identity and genome integrity. However, DNA replication results in transient displacement of DNA bound proteins, and it is unclear how they regain access to newly replicated DNA. Using quantitative MS-based proteomics coupled to Nascent Chromatin Capture, we provide time resolved binding kinetics for thousands of proteins behind replisomes of mid-S replicated regions. This shows that most proteins regain access within the first 15 minutes after the passage of the fork. In contrast, 25% of the identified proteins do not, and this delay cannot be inferred from their known function, physicochemical properties, or nuclear abundance. A sample treated with nocodazole to block the cell cycle progression. The comparison between a normal cell cycle progression and a nocodazole treated sample shows that the reassociation onto chromatin of proteins with a delayed restoration can be regulated by the cell cycle progression and/or the post-replication time. In addition, we provide evidence that DNA replication not only disrupts but also promotes recruitment of transcription factors and chromatin remodellers, providing a significant advance in understanding how DNA replication could contribute to programmed changes of cell memory. Data available in this entry are related with the supplementary table 5 from our manuscript.

Project description:Chromatin organization must be maintained during cell proliferation to preserve cellular identity and genome integrity. However, DNA replication results in transient displacement of DNA bound proteins, and it is unclear how they regain access to newly replicated DNA. Using quantitative MS-based proteomics coupled to Nascent Chromatin Capture, we provide time resolved binding kinetics for thousands of proteins behind replisomes within euchromatin and heterochromatin in human cells. This shows that most proteins regain access within the first 15 minutes after the passage of the fork. In contrast, 30% of the identified proteins do not, and this delay cannot be inferred from their known function, physicochemical properties, or nuclear abundance. Instead, differential chromatin organization affect their reassociation. We provide evidence that DNA replication not only disrupts but also promotes recruitment of transcription factors and chromatin remodellers, providing a significant advance in understanding how DNA replication could contribute to programmed changes of cell memory.We include here a reference to link the data with our manuscript:Tables SUPP1 and SUPP2:NCC data: PT7988 (Bio-rep1), PT8242 (Bio-rep2), PT8243 (Bio-rep3). 1-24 (24 high-pH RPLC fractions from TMT labeled peptides)Nuclear fraction data: PT7988 (Bio-rep1), PT8242 (Bio-rep2), PT8243 (Bio-rep3). 25-48 (24 high-pH RPLC fractions from TMT labeled peptides)Tables SUPP3-5:NCC data: PT9825 (Bio-rep1), PT9825 (Bio-rep2), PT9825 (Bio-rep3). (11-34, 35-58, 59-82) (24 high-pH RPLC fractions from TMT labeled peptides)Nuclear fraction data: PT9825 (Bio-rep1), PT9825 (Bio-rep2), PT9825 (Bio-rep3). (83-106, 107-130, 131-154). (24 high-pH RPLC fractions from TMT labeled peptides)

Project description:Chromatin organization must be maintained during cell proliferation to preserve cellular identity and genome integrity. However, DNA replication results in transient displacement of DNA bound proteins, and it is unclear how they regain access to newly replicated DNA. Using quantitative MS-based proteomics coupled to isolation of proteins on nascent DNA (iPOND), we provide time resolved binding kinetics for thousands of proteins behind replisomes in the lung fibroblast cell line TIG-3 (JCRB0506, JCRB Cell Bank). Performing hierarchical clustering, we identified four groups of protein behaviour: Transient enriched on nascent, restored within 11min, peaking in G2/M, and delayed restored. Overall, our data show that most proteins (85%) regain access within the first 2h after the passage of the fork. Only a small percentage of proteins is restored after 2h post-replication, with 5.3 % of factors peaking in G2/M and 9.1% factors not restored before the next G1 phase. We provide evidence that DNA replication not only disrupts but also promotes recruitment of transcription factors and chromatin remodelers, providing a significant advance in understanding how DNA replication could contribute to programmed changes of cell memory.

Project description:Flag-G6PD was expressed in HeLa cells. Then the HeLa cells were synchronized with a double thymidine block procedure. Briefly, the exponentially growing HeLa cells were maintained with 2 mM thymidine for 18 h, followed by a release of 9 h in fresh medium, and then cells were re-cultured in 2 mM thymidine for additional 15 h. These interphase cells were harvested. After a release of 8.5 h in fresh medium, the cells entered into M phase. Mitotic cells were harvested by mitotic shake-off. Then, cell lysate was incubated with anti-Flag M2-agarose. Elutes were separated with 10% SDS-PAGE. The gel was stained with Coomassie Brilliant Blue. Visualized bands were excised and subjected to LC-MS/MS analysis.

Project description:Total S phase was measured for wild-type cells undergoing meiS and mitS. Early replication origins were mapped in mitS in wild-type cells, and in meiS for wild-type, sml1 delete, rec8 delete and spo11 delete cells. Comparative genome hybridization was used to measure the kinetics and final extent of DNA replication in wild-type and mutant cells. First, S phase profiles were produced from wild-type cells undergoing pre-mitotic S phase (mitS) and pre-meiotic S phase (meiS) to measure the kinetics of DNA replication in the two S phases. For these experiments, a pool of samples collected throught out all of S phase were labeled and hybridized to a microarray together with a control G1 DNA sample. Second, early replication origins were mapped by exposing cells to levels of HU that strongly reduced DNA replication. Early replication was compared for wild-type cells in mitS to wild-type, sml1, rec8 and spo11 delete strain undergoing meiS. In these experiment, samples were collected after 4 hours exposure to HU. Total genomic DNA was isolated, labeled and hybridized to a microarray together with a control G1 DNA sample. A control G1 vs. G1 sample was prepared to measure the level of noise inherent in the CGH technique.

Project description:The aim of the project was to quantify protein aggregation and disaggregation in human cells after transient non-lethal heat shock and during recovery. In addition, the non-aggregating proteins were analyzed by two-dimensional proteome profiling to detect changes in thermal stability upon heat shock. For aggregation/disaggregation study, K562 cells were grown in light SILAC medium which was changed to heavy medium 90 minutes before heat treatment (10 minutes at 44C). After heat shock, cells were let to recover at 37C. Samples were collected before and after the heat shock as well as on multiple time points during recovery (one, two, three and five hours). Protein intensities from soluble fraction (extracted with mild detergent - NP40) was compared to a control samples that on parallel were treated with mock shock (10 minutes at +37C). Samples were labelled with TMT labels and pooled. The medium switch prior to heat shock also allowed to monitor changes in protein synthesis caused by the heat shock. For control, an analysis of total protein amount (extracted with strong detergent - SDS) was conducted. For two-dimensional proteome profiling, aliquots of heat shocked and mock shocked samples were exposed to a temperature gradient (from 37.0C to 66.3C). Samples from two adjacent temperatures were labelled with TMT and pooled. Proteins from soluble fractions were quantified and heat shock-induced changes in thermal stability were analyzed.

Project description:Stringent post-transcriptional regulation of mRNA fate is critical for proper cell division. To detect proteins involved in such regulation, we analyzed the composition of intact polysomal complexes from mitotic and interphase cells by quantitative mass-spectrometry. Using this approach, we detected increased association of several mRNA-binding proteins, including heterogeneous nuclear ribonucleoprotein C (hnRNP C), with mitotic polysomes. Immunofluorescence analysis, puromycin-sensitivity assays and nascent-chain pulldowns confirmed that hnRNP C interacts with polysome-bound mRNA during mitosis. Using a combination of pulsed SILAC and metabolic labeling, we found that knockdown of hnRNP C has a pervasive effect on both global and transcript-specific translation rates. Furthermore, ribosome profiling revealed that hnRNP C is involved in translation of mRNAs encoding components of the translation machinery and other mRNAs harboring a 5' terminal oligopyrimidine tract (5’ TOP). Taken together, these results suggest that hnRNP C is crucial for ribogenesis during mitosis; in its absence, production of ribosomal proteins and translation factors is impaired and translation rates are reduced during subsequent phases of the cell cycle.

Project description:Multiplexed quantitative proteomics enables the development of complex workflows for studying the mechanisms by which small molecule drugs interact with the proteome such as thermal proteome profiling (TPP) or multiplexed proteome dynamics profiling (mPDP). TPP measures changes in protein thermal stability in response to drug treatment and thus informs on direct targets and downstream regulation events, while the mPDP approach enables the discovery of regulated protein synthesis and degradation events caused by small molecules and other perturbations. The mass tags available for multiplexed proteomics have thus far limited the efficiency and sensitivity with which such experiments could be performed. Here we evaluate a new generation of 16-plex isobaric mass tags and demonstrate similar sensitivity and accuracy of quantification as the previously described TMT reagents. The TMT16 tags enabled the sensitive and time efficient identification of staurosporine targets in HepG2 cell extracts by recording full thermal denaturation/aggregation profiles of vehicle and compound treated samples in a single mass spectrometry experiment. In 2D-TPP experiments, isothermal titration over 7 concentrations per temperature enabled comprehensive selectivity profiling of staurosporine with EC50 values for kinase targets tightly matching to the kinobeads gold standard assay. Finally, we demonstrate time and condition-based multiplexing of dynamic SILAC labeling experiments to delineate proteome-wide effects of the molecular glue Indisulam on synthesis and degradation rates.

Project description:Multiplexed quantitative proteomics enables the development of complex workflows for studying the mechanisms by which small molecule drugs interact with the proteome such as thermal proteome profiling (TPP) or multiplexed proteome dynamics profiling (mPDP). TPP measures changes in protein thermal stability in response to drug treatment and thus informs on direct targets and downstream regulation events, while the mPDP approach enables the discovery of regulated protein synthesis and degradation events caused by small molecules and other perturbations. The mass tags available for multiplexed proteomics have thus far limited the efficiency and sensitivity with which such experiments could be performed. Here we evaluate a new generation of 16-plex isobaric mass tags and demonstrate similar sensitivity and accuracy of quantification as the previously described TMT reagents. The TMT16 tags enabled the sensitive and time efficient identification of staurosporine targets in HepG2 cell extracts by recording full thermal denaturation/aggregation profiles of vehicle and compound treated samples in a single mass spectrometry experiment. In 2D-TPP experiments, isothermal titration over 7 concentrations per temperature enabled comprehensive selectivity profiling of staurosporine with EC50 values for kinase targets tightly matching to the kinobeads gold standard assay. Finally, we demonstrate time and condition-based multiplexing of dynamic SILAC labeling experiments to delineate proteome-wide effects of the molecular glue Indisulam on synthesis and degradation rates.