Dissect the Dynamic Molecular Circuits of Cell Cycle Control through Network Evolution Model

Dissect the Dynamic Molecular Circuits of Cell Cycle Control through Network Evolution Model

The molecular circuits of cell cycle control serve as a key hub to integrate from endogenous and environmental signals into a robust biological decision driving cell growth and division. Dysfunctional cell cycle control is highlighted in a wide spectrum of human cancers. More importantly the mainsta...

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Main Authors: Yang Peng, Paul Scott, Ruikang Tao, Hua Wang, Yan Wu, Guang Peng
Format: Article
Language:English
Published: Hindawi Limited 2017-01-01
Series:BioMed Research International
Online Access:http://dx.doi.org/10.1155/2017/2954351
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spelling doaj-9e120f37185f4209ac17a7b9d732e3272020-11-24T23:49:55ZengHindawi LimitedBioMed Research International2314-61332314-61412017-01-01201710.1155/2017/29543512954351Dissect the Dynamic Molecular Circuits of Cell Cycle Control through Network Evolution ModelYang Peng0Paul Scott1Ruikang Tao2Hua Wang3Yan Wu4Guang Peng5Department of Clinical Cancer Prevention, The University of Texas MD Anderson Cancer Center, Houston, TX 77030, USAMathematical Sciences, Georgia Southern University, Statesboro, GA 30458, USAUniversity of California, Santa Cruz, CA 65064, USAMathematical Sciences, Georgia Southern University, Statesboro, GA 30458, USAMathematical Sciences, Georgia Southern University, Statesboro, GA 30458, USADepartment of Clinical Cancer Prevention, The University of Texas MD Anderson Cancer Center, Houston, TX 77030, USAThe molecular circuits of cell cycle control serve as a key hub to integrate from endogenous and environmental signals into a robust biological decision driving cell growth and division. Dysfunctional cell cycle control is highlighted in a wide spectrum of human cancers. More importantly the mainstay anticancer treatment such as radiation therapy and chemotherapy targets the hallmark of uncontrolled cell proliferation in cancer cells by causing DNA damage, cell cycle arrest, and cell death. Given the functional importance of cell cycle control, the regulatory mechanisms that drive the cell division have been extensively investigated in a huge number of studies by conventional single-gene approaches. However the complexity of cell cycle control renders a significant barrier to understand its function at a network level. In this study, we used mathematical modeling through modern graph theory and differential equation systems. We believe our network evolution model can help us understand the dynamic cell cycle control in tumor evolution and optimizing dosing schedules for radiation therapy and chemotherapy targeting cell cycle.http://dx.doi.org/10.1155/2017/2954351
collection DOAJ
language English
format Article
sources DOAJ
author Yang Peng
Paul Scott
Ruikang Tao
Hua Wang
Yan Wu
Guang Peng
spellingShingle Yang Peng
Paul Scott
Ruikang Tao
Hua Wang
Yan Wu
Guang Peng
Dissect the Dynamic Molecular Circuits of Cell Cycle Control through Network Evolution Model
BioMed Research International
author_facet Yang Peng
Paul Scott
Ruikang Tao
Hua Wang
Yan Wu
Guang Peng
author_sort Yang Peng
title Dissect the Dynamic Molecular Circuits of Cell Cycle Control through Network Evolution Model
title_short Dissect the Dynamic Molecular Circuits of Cell Cycle Control through Network Evolution Model
title_full Dissect the Dynamic Molecular Circuits of Cell Cycle Control through Network Evolution Model
title_fullStr Dissect the Dynamic Molecular Circuits of Cell Cycle Control through Network Evolution Model
title_full_unstemmed Dissect the Dynamic Molecular Circuits of Cell Cycle Control through Network Evolution Model
title_sort dissect the dynamic molecular circuits of cell cycle control through network evolution model
publisher Hindawi Limited
series BioMed Research International
issn 2314-6133
2314-6141
publishDate 2017-01-01
description The molecular circuits of cell cycle control serve as a key hub to integrate from endogenous and environmental signals into a robust biological decision driving cell growth and division. Dysfunctional cell cycle control is highlighted in a wide spectrum of human cancers. More importantly the mainstay anticancer treatment such as radiation therapy and chemotherapy targets the hallmark of uncontrolled cell proliferation in cancer cells by causing DNA damage, cell cycle arrest, and cell death. Given the functional importance of cell cycle control, the regulatory mechanisms that drive the cell division have been extensively investigated in a huge number of studies by conventional single-gene approaches. However the complexity of cell cycle control renders a significant barrier to understand its function at a network level. In this study, we used mathematical modeling through modern graph theory and differential equation systems. We believe our network evolution model can help us understand the dynamic cell cycle control in tumor evolution and optimizing dosing schedules for radiation therapy and chemotherapy targeting cell cycle.
url http://dx.doi.org/10.1155/2017/2954351
work_keys_str_mv AT yangpeng dissectthedynamicmolecularcircuitsofcellcyclecontrolthroughnetworkevolutionmodel
AT paulscott dissectthedynamicmolecularcircuitsofcellcyclecontrolthroughnetworkevolutionmodel
AT ruikangtao dissectthedynamicmolecularcircuitsofcellcyclecontrolthroughnetworkevolutionmodel
AT huawang dissectthedynamicmolecularcircuitsofcellcyclecontrolthroughnetworkevolutionmodel
AT yanwu dissectthedynamicmolecularcircuitsofcellcyclecontrolthroughnetworkevolutionmodel
AT guangpeng dissectthedynamicmolecularcircuitsofcellcyclecontrolthroughnetworkevolutionmodel
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