Project description:mathematical approach to model the protein interactions regulating the transition from the G1 phase to the phase of DNA synthesis. Model is encoded by matthieu Maire and submitted to BioModels by krishna kumar tiwari.

Project description:Mathematical description of the interactions of CycE/Cdk2, Cdc25A, and P27Kip1 in a core cancer subnetwork. Model is encoded by Matthieu Maire/partially by Krishna Kumar Tiwari and submitted to BioModels by Krishna Kumar Tiwari.

Project description:A quantitative model of the initiation of DNA replication in Saccharomyces cerevisiae predicts the effects of system perturbations. Model is encoded by Matthew Maire and submitted in BioModels by Krishna Kumar Tiwari.

Project description:model allows us to infer proliferation rates and cell cycle phase durations from complex experimental 5-ethynyl-2'-deoxyuridine (EdU) data, revealing T cell proliferation heterogeneity and specific signatures. Model is encoded by Matthew Maire and submitted in BioModels by Krishna Kumar Tiwari.

Project description:mathematical model, with accompanying quantitative experimental data, for binding and trafficking properties of the epidermal growth factor (EGF) receptor on B82 fibroblasts, and propose a theoretical dependence of cell proliferation rate on these properties. Model encoded by Matthieu Maire adn submitted to BioModels by Krishna Kumar Tiwari.

Project description:ABSTRACT: Condensin is a central regulator of mitotic genome structure, with mutants showing poorly condensed chromosomes and profound segregation defects. Here we identify the fission yeast NCT complex, comprising the Nrc1 BET-family tandem bromodomain protein (SPAC631.02), Casein Kinase II (CKII) and several TAFs, as a novel regulator of condensin function (where NCT mutants restore the formation of segregation-competent chromosomes in cells containing defective condensin). Synchronous ChIP-seq shows that NCT and condensin bind similar genomic regions, but only briefly co-localize during the periods of chromosome condensation and decondensation. These results are consistent with a model where NCT targets CKII to chromatin in a cell cycle-directed manner to modulate the activity of condensin during chromosome condensation and decondensation. DATA: Study includes ChIP-seq of fission yeast H3-K4Me3, H3-K36Me3, TBP, Taf7, Nrc1, Cka1 from aynchronous cells; Nrc1 and Cut3 (representing condensin) from four synchronized cell-cycle stages estimated as G2/M, Metaphase, Anaphase and G1/S.

Project description:Immunoprecipitated UBE2S from HeLa K cells synchronized in pro metaphase, anaphase and G1-phase, were analyzed by tryptic digest and LC-MS/MS.

Project description:Defects in DNA damage responses may underlie genetic instability and malignant progression in melanoma. Cultures of normal human melanocytes (NHMs) and melanoma lines were analyzed to determine whether global patterns of gene expression could predict the efficacy of DNA damage cell cycle checkpoints that arrest growth and suppress genetic instability. NHMs displayed effective G1 and G2 checkpoint responses to ionizing radiation-induced DNA damage. A majority of melanoma cell lines (11/16) displayed significant quantitative defects in one or both checkpoints. Melanomas with B-RAF mutations as a class displayed a significant defect in DNA damage G2 checkpoint function. In contrast the epithelial-like subtype of melanomas with wildtype N-RAS and B-RAF alleles displayed an effective G2 checkpoint but a significant defect in G1 checkpoint function. RNA expression profiling revealed that melanoma lines with defects in the DNA damage G1 checkpoint displayed reduced expression of p53 transcriptional targets, such as CDKN1A and DDB2, and enhanced expression of proliferation-associated genes, such as CDC7 and GEMININ. A Bayesian analysis tool was more accurate than significance analysis of microarrays for predicting checkpoint function using a leave-one-out method. The results suggest that defects in DNA damage checkpoints may be recognized in melanomas through analysis of gene expression. Experiment Overall Design: Normal human melanocyte and melanoma cell lines w/wo mutations in B-raf or N-ras were treated with 1.5 Gy IR irridiartion for G1 and G2 checkpoint determination. RNA was isolated from exponentially growing cultures and applied for microarray hybridizaton with Agilent 44 K (G4112A) array.

Project description:This 133-node Boolean regulatory network model reproduces mitochondrial dynamics during cell cycle progression (hyper-fusion at the G1/S boundary, fission in mitosis), apoptosis (fission and dysfunction) and glucose starvation (reversible hyper-fusion), as well as MiDAS in response to SIRT3 knockdown or oxidative stress and the protective role of NAD+ or external pyruvate. These features are in addition to the cell cycle-related phenotypes reproduced by the Sizek et al model that served as our starting point. Testable predictions (new): a) In cell lines with low basal p21 expression known to pre-commit to the next division in early mitosis of their current cycle, a subset of cells respond to glucose withdrawal by arresting with 4N DNA content but losing their internal G2 state (i.e. Cyclin A/B expression), and undergo endo-reduplication upon glucose re-exposure. b) In a subset of glucose-starved cells that pass the G2/M checkpoint with hyperfused mitochondria, mitotic fragmentation can be sufficiently delayed to cause spindle assembly defects and mitotic catastrophe. c) Quiescent cells are less susceptible to ROS-induced MiDAS due to FoxO-mediated PINK1 expression, which blocks MFN1/2 from inducing hyperfusion. d) Boosting NAD+ levels in MiDAS cells that have not yet established deep senescence (2-3 days post induction) can reverse their fate.

Project description:We establish that subtelomeric regions together with some other functional elements like transposons are consistently under-replicated in metaphase and with lower extent in late anaphase, suggesting and ongoing DNA replication between metaphase and telophase.