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Tutorials in Mathematical Biosciences III : Cell Cycle, Proliferation, and Cancer. (2005)

Friedman, Avner.

Berlin, Heidelberg :Springer Berlin / Heidelberg,

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Keywords: Mathematics. ; Electronic books.

Type of Medium: Online Resource

Pages: 1 online resource (254 pages)

Edition: 1st ed.

ISBN: 9783540324157

Series Statement: Lecture Notes in Mathematics Series ; v.1872

URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=5579176

DDC: 510

Language: English

Note: Intro -- Modeling the Cell Division Cycle -- Baltazar D. Aguda -- 1 Introduction -- 2 Basic Biology of the Cell Division Cycle: Chromosome Cycle and Growth Cycle -- 3 The Molecular Regulators of the Cell Cycle: CDKs and APC -- 4 The Key Molecular Pathways -- 5 From Qualitative Network and Mechanisms to Dynamical Equations -- 6 Mammalian Cell Cycle and Checkpoints -- 7 Coupling Between the Cell Cycle and Apoptosis -- 8 Conclusions and Future Directions -- References -- Angiogenesis-A Biochemical/Mathematical Perspective -- Howard A. Levine and Marit Nilsen-Hamilton -- 1 Introduction -- 2 What is Angiogenesis? -- 3 What are the Key Events in Angiogenesis? -- 4 What are the Chemical and Cellular Contributions to Capillary Structure? -- 5 Interaction of Endothelial Cells with Their Environment -- 6 What are the Extracellular Events Leading to Vascularization? -- 7 Soluble Proteins that Modify the ECM and Influence EC Function: Proteases and Protease Inhibitors -- 8 Growth and Angiogenesis Factors: Factors that Stimulate Angiogenesis -- 9 Inhibitors of Angiogenesis -- 10 Cellular Events that Characterize Angiogenesis -- 11 Intracellular Signals (Signal Transduction) that Regulate Cellular Events -- 12 How does one Model These Events Mathematically? -- 13 Vocabulary -- References -- Mathematical Modelling of Proteolysisand Cancer Cell Invasion of Tissue -- Georgios Lolas -- 1 Introduction -- 2 Mathematical Modelling of Solid Tumour Growth and Invasion -- 3 Biological Background -- 4 The Mathematical Model of Proteolysisand Cancer Cell Invasion of Tissue -- 5 Numerical Simulation Results -- 6 Discussion -- References -- Mathematical Modelling of Spatio-temporal Phenomena in Tumour Immunology -- Mark Chaplain and Anastasios Matzavinos -- 1 Introduction -- 2 Tumour Immunology. , 3 Modelling the Spatio-temporal Response of Cytotoxic T-lymphocytes to a Solid Tumour -- 4 Discussion and Conclusions -- References -- Control Theory Approach to Cancer Chemotherapy: Benefiting from Phase Dependence and Overcoming Drug Resistance -- Marek Kimmel and Andrzej Swierniak -- 1 Introduction -- 2 Modeling the Cell Cycle -- 3 Control Problems with Cell-Cycle-Phase Dependence -- 4 Evolution of Resistance by Gene Amplification -- 5 Control Under Evolving Resistance -- 6 Remarks on Estimation of Parameters -- 7 Discussion -- References -- Cancer Models and Their Mathematical Analysis -- Avner Friedman -- 1 Introduction -- 2 Introduction to Tumors -- 3 Three Types of Cells -- 4 Two Types of Cells -- 4 Proliferating Cells -- 5 Tumors with Necrotic Core -- 6 Cancer Therapy -- 7 Concluding Remarks -- References.

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Runx1 deletion or dominant inhibition reduces Cebpa transcription via conserved promoter and distal enhancer sites to favor monopoiesis over granulopoiesis (2012)

Guo, H., Ma, O., Speck, N. A., Friedman, A. D.

American Society of Hematology (ASH)

In: Blood

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Publication Date: 2012-05-11

Description: Deletion of Runx1 in adult mice produces a myeloproliferative phenotype. We now find that Runx1 gene deletion increases marrow monocyte while reducing granulocyte progenitors and that exogenous RUNX1 rescues granulopoiesis. Deletion of Runx1 reduces Cebpa mRNA in lineage-negative marrow cells and in granulocyte-monocyte progenitors or common myeloid progenitors. Pu.1 mRNA is also decreased, but to a lesser extent. We also transduced marrow with dominant-inhibitory RUNX1a. As with Runx1 gene deletion, RUNX1a expands lineage – Sca-1 + c-kit + and myeloid cells, increased monocyte CFUs relative to granulocyte CFUs, and reduced Cebpa mRNA. Runx1 binds a conserved site in the Cebpa promoter and binds 4 sites in a conserved 450-bp region located at +37 kb; mutation of the enhancer sites reduces activity 6-fold in 32Dcl3 myeloid cells. Endogenous Runx1 binds the promoter and putative +37 kb enhancer as assessed by ChIP, and RUNX1-ER rapidly induces Cebpa mRNA in these cells, even in cycloheximide, consistent with direct gene regulation. The +37 kb region contains strong H3K4me1 histone modification and p300-binding, as often seen with enhancers. Finally, exogenous C/EBPα increases granulocyte relative to monocyte progenitors in Runx1 -deleted marrow cells. Diminished CEBPA transcription and consequent impairment of myeloid differentiation may contribute to leukemic transformation in acute myeloid leukemia cases associated with decreased RUNX1 activity.

Keywords: Hematopoiesis and Stem Cells, Phagocytes, Granulocytes, and Myelopoiesis

Print ISSN: 0006-4971

Electronic ISSN: 1528-0020

Topics: Biology , Medicine

Published by American Society of Hematology (ASH)

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