Computational modelling suggests dynamic interactions between Ca2+, IP3 and G protein-coupled modules are key to robust Dictyostelium aggregation

Valeyev, Najl V.; Kim, Jung-Su; Heslop-Harrison, J. S.; Postlethwaite, Ian; Kotov, Nikolay V.; Bates, Declan G.

doi:10.1039/b822074c

Cited by 7 publications

(7 citation statements)

References 82 publications

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“…The concentration of cAMP is also increased through ERK2, which inhibits the phosphodiesterase (PDE) RegA, in turn hydrolyzing cAMP. This pathway is inhibited by PKA, activated by cAMP [19,45,46]. (c) Photo-transduction.…”

Section: Methodsmentioning

confidence: 99%

Unraveling Adaptation in Eukaryotic Pathways: Lessons from Protocells

Palo

Endres

2013

PLoS Comput Biol

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Eukaryotic adaptation pathways operate within wide-ranging environmental conditions without stimulus saturation. Despite numerous differences in the adaptation mechanisms employed by bacteria and eukaryotes, all require energy consumption. Here, we present two minimal models showing that expenditure of energy by the cell is not essential for adaptation. Both models share important features with large eukaryotic cells: they employ small diffusible molecules and involve receptor subunits resembling highly conserved G-protein cascades. Analyzing the drawbacks of these models helps us understand the benefits of energy consumption, in terms of adjustability of response and adaptation times as well as separation of cell-external sensing and cell-internal signaling. Our work thus sheds new light on the evolution of adaptation mechanisms in complex systems.

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Section: Methodsmentioning

confidence: 99%

Unraveling Adaptation in Eukaryotic Pathways: Lessons from Protocells

Palo

Endres

2013

PLoS Comput Biol

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“…Interestingly, the effect of intrinsic noise was to 'enhance' the robustness of cAMP oscillations to variations between cells, whereas synchronisation of oscillations between cells via a shared pool of external cAMP also significantly improved the robustness of the system. Two further studies suggested a significant role for other subnetworks involving calcium and IP3 in generating robust oscillations [64,65]. Using a combination of structural robustness analysis [64] and biophysical modelling [65], an extended model including these subnetworks ( Fig.…”

Section: Camp Oscillations In Dictyostelium Cellsmentioning

confidence: 99%

“…Two further studies suggested a significant role for other subnetworks involving calcium and IP3 in generating robust oscillations [64,65]. Using a combination of structural robustness analysis [64] and biophysical modelling [65], an extended model including these subnetworks ( Fig. 8) was constructed which exhibited significantly higher robustness than the original model, as shown in Fig.…”

Section: Camp Oscillations In Dictyostelium Cellsmentioning

confidence: 99%

Validation and invalidation of systems biology models using robustness analysis

Bates

Cosentino

2011

IET Systems Biology

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Robustness, the ability of a system to function correctly in the presence of both internal and external uncertainty, has emerged as a key organising principle in many biological systems. Biological robustness has thus become a major focus of research in Systems Biology, particularly on the engineering-biology interface, since the concept of robustness was first rigorously defined in the context of engineering control systems. This review focuses on one particularly important aspect of robustness in Systems Biology, that is, the use of robustness analysis methods for the validation or invalidation of models of biological systems. With the explosive growth in quantitative modelling brought about by Systems Biology, the problem of validating, invalidating and discriminating between competing models of a biological system has become an increasingly important one. In this review, the authors provide a comprehensive overview of the tools and methods that are available for this task, and illustrate the wide range of biological systems to which this approach has been successfully applied.

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“…Note that, due to their almost linear dependence on other states, the variables PKA, RegA, and CAR1 in the original model have not been included as independent states in the extended model, but appear implicitly in the equations, in order to keep the complexity of the extended model within manageable levels. Owing to space limitations, we do not present here a full description of the derivation of the extended model equations given above, or of the meaning of all of the model parameters-the interested reader is referred to [20] for full details of the model and the underlying experimental results. The key point to be noticed about the extended model for our purposes is that, as shown in Figure 6(a), the newly added modules in the extended model are connected at the point of interaction between the states x 1 (ACA) and x 7 (CAR1) in the original model, i.e.…”

Section: Extension Of the Modelmentioning

confidence: 99%

Analysis and extension of a biochemical network model using robust control theory

Kim

Valeyev

Postlethwaite

et al. 2009

Intl J Robust & Nonlinear

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SUMMARYMathematical models of biological processes which have been observed in vivo to be highly robust to intracellular and environmental variations should themselves display appropriate levels of robustness when analysed in silico. This paper uses techniques from robust control theory to analyse and extend a mathematical model of the interacting proteins underlying adenosine 3 , 5 -cyclic monophosphate (cAMP) oscillations in aggregating Dictyostelium cells. Starting with a previously proposed 'minimal' model, we show how robustness analysis using the structured singular value can identify points of structural fragility in the network. By combining these results with insights from recent results from the experimental literature, we show how the original model can be augmented with some important additional modules, comprising networks involving IP 3 and Ca 2+ . By analysing the robustness of our new extended model, we are able to show that dynamic interactions between the different modules play a pivotal role in generating robust cAMP oscillations; thus, significantly improving our understanding of the design principles underlying this complex biological system.

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Computational modelling suggests dynamic interactions between Ca2+, IP3 and G protein-coupled modules are key to robust Dictyostelium aggregation

Cited by 7 publications

References 82 publications

Unraveling Adaptation in Eukaryotic Pathways: Lessons from Protocells

Unraveling Adaptation in Eukaryotic Pathways: Lessons from Protocells

Validation and invalidation of systems biology models using robustness analysis

Analysis and extension of a biochemical network model using robust control theory

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