A comprehensive complex systems approach to the study and analysis of mammalian cell cycle control system in the presence of DNA damage stress. (21st September 2017)
- Record Type:
- Journal Article
- Title:
- A comprehensive complex systems approach to the study and analysis of mammalian cell cycle control system in the presence of DNA damage stress. (21st September 2017)
- Main Title:
- A comprehensive complex systems approach to the study and analysis of mammalian cell cycle control system in the presence of DNA damage stress
- Authors:
- Abroudi, Ali
Samarasinghe, Sandhya
Kulasiri, Don - Abstract:
- Highlights: Presents a holistic complex system modelling approach involving interacting subsystems. Develops the most comprehensive ODE based mammalian cell cycle model. Abstracts known pathways into subsystems and adds new pathways and elements. Introduces a Global parameter sensitivity approach -Self Organising Maps/Correlation. Identifies the most important subsystems, sub-pathways and parameters in cell cycle. Demonstrates the value and role of the newly added components. Introduces a statistical/simulation based approach to assess efficiency of DNA damage check points. Reveals a relatively higher G2/M checkpoint efficiency compared to G1/S checkpoint. Quantifies the efficiency of checkpoints in arresting damaged cells and not sacrificing healthy cells. Abstract: Not many models of mammalian cell cycle system exist due to its complexity. Some models are too complex and hard to understand, while some others are too simple and not comprehensive enough. Moreover, some essential aspects, such as the response of G1-S and G2-M checkpoints to DNA damage as well as the growth factor signalling, have not been investigated from a systems point of view in current mammalian cell cycle models. To address these issues, we bring a holistic perspective to cell cycle by mathematically modelling it as a complex system consisting of important sub-systems that interact with each other. This retains the functionality of the system and provides a clearer interpretation to the processes withinHighlights: Presents a holistic complex system modelling approach involving interacting subsystems. Develops the most comprehensive ODE based mammalian cell cycle model. Abstracts known pathways into subsystems and adds new pathways and elements. Introduces a Global parameter sensitivity approach -Self Organising Maps/Correlation. Identifies the most important subsystems, sub-pathways and parameters in cell cycle. Demonstrates the value and role of the newly added components. Introduces a statistical/simulation based approach to assess efficiency of DNA damage check points. Reveals a relatively higher G2/M checkpoint efficiency compared to G1/S checkpoint. Quantifies the efficiency of checkpoints in arresting damaged cells and not sacrificing healthy cells. Abstract: Not many models of mammalian cell cycle system exist due to its complexity. Some models are too complex and hard to understand, while some others are too simple and not comprehensive enough. Moreover, some essential aspects, such as the response of G1-S and G2-M checkpoints to DNA damage as well as the growth factor signalling, have not been investigated from a systems point of view in current mammalian cell cycle models. To address these issues, we bring a holistic perspective to cell cycle by mathematically modelling it as a complex system consisting of important sub-systems that interact with each other. This retains the functionality of the system and provides a clearer interpretation to the processes within it while reducing the complexity in comprehending these processes. To achieve this, we first update a published ODE mathematical model of cell cycle with current knowledge. Then the part of the mathematical model relevant to each sub-system is shown separately in conjunction with a diagram of the sub-system as part of this representation. The model sub-systems are Growth Factor, DNA damage, G1-S, and G2-M checkpoint signalling. To further simplify the model and better explore the function of sub-systems, they are further divided into modules. Here we also add important new modules of: chk-related rapid cell cycle arrest, p53 modules expanded to seamlessly integrate with the rapid arrest module, Tyrosine phosphatase modules that activate Cyc_Cdk complexes and play a crucial role in rapid and delay arrest at both G1-S and G2-M, Tyrosine Kinase module that is important for inactivating nuclear transport of CycB_cdk1 through Wee1 to resist M phase entry, Plk1-Related module that is crucial in activating Tyrosine phosphatases and inactivating Tyrosine kinase, and APC-Related module to show steps in CycB degradation. This multi-level systems approach incorporating all known aspects of cell cycle allowed us to (i) study, through dynamic simulation of an ODE model, comprehensive details of cell cycle dynamics under normal and DNA damage conditions revealing the role and value of the added new modules and elements, (ii) assess, through a global sensitivity analysis, the most influential sub-systems, modules and parameters on system response, such as G1-S and G2-M transitions, and (iii) probe deeply into the relationship between DNA damage and cell cycle progression and test the biological evidence that G1-S is relatively inefficient in arresting damaged cells compared to G2-M checkpoint. To perform sensitivity analysis, Self-Organizing Map with Correlation Coefficient Analysis (SOMCCA) is developed which shows that Growth Factor and G1-S Checkpoint sub-systems and 13 parameters in the modules within them are crucial for G1-S and G2-M transitions. To study the relative efficiency of DNA damage checkpoints, a Checkpoint Efficiency Evaluator (CEE) is developed based on perturbation studies and statistical Type II error. Accordingly, cell cycle is about 96% efficient in arresting damaged cells with G2-M checkpoint being more efficient than G1-S. Further, both checkpoint systems are near perfect (98.6%) in passing healthy cells. Thus this study has shown the efficacy of the proposed systems approach to gain a better understanding of different aspects of mammalian cell cycle system separately and as an integrated system that will also be useful in investigating targeted therapy in future cancer treatments. … (more)
- Is Part Of:
- Journal of theoretical biology. Volume 429(2017)
- Journal:
- Journal of theoretical biology
- Issue:
- Volume 429(2017)
- Issue Display:
- Volume 429, Issue 2017 (2017)
- Year:
- 2017
- Volume:
- 429
- Issue:
- 2017
- Issue Sort Value:
- 2017-0429-2017-0000
- Page Start:
- 204
- Page End:
- 228
- Publication Date:
- 2017-09-21
- Subjects:
- Complex systems -- Integrated sub-systems -- Cell cycle -- Global parameter sensitivity -- Self-organising maps -- DNA damage -- Checkpoint efficiency
Biology -- Periodicals
Biological Science Disciplines -- Periodicals
Biology -- Periodicals
Biologie -- Périodiques
Theoretische biologie
Biology
Periodicals
571.05 - Journal URLs:
- http://www.sciencedirect.com/science/journal/00225193/ ↗
http://www.elsevier.com/journals ↗ - DOI:
- 10.1016/j.jtbi.2017.06.018 ↗
- Languages:
- English
- ISSNs:
- 0022-5193
- Deposit Type:
- Legaldeposit
- View Content:
- Available online (eLD content is only available in our Reading Rooms) ↗
- Physical Locations:
- British Library DSC - 5069.075000
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