Discrete event, multi-level simulation of metabolite channeling

Degenring, Daniela; Röhl, Mathias; Uhrmacher, Adelinde M.

doi:10.1016/j.biosystems.2004.03.008

Cited by 35 publications

(13 citation statements)

References 32 publications

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“…Enzyme proteins can form multienzyme protein complexes that serve to microcompartment metabolic pathways and thus allow operation of more efficient metabolic transitions (Saks et al, 2008). The organisation of metabolic pathways by enzyme protein complexes has been discussed as the main molecular-scale organisation units to orchestrate the multiple metabolic processes (Degenring et al, 2004;Durek and Walther, 2008;Graham et al, 2007;Ro and Douglas, 2004;Srere, 2000). Additionally transient complexes offer the possibility of fast exchange of some of the polypeptide components upon reassembly and thus can be a molecular basis for rapid and fine tuning or redirection of metabolism.…”

Section: Introductionmentioning

confidence: 99%

Alteration of mitochondrial protein complexes in relation to metabolic regulation under short-term oxidative stress in Arabidopsis seedlings

et al. 2011

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Section: Introductionmentioning

confidence: 99%

Alteration of mitochondrial protein complexes in relation to metabolic regulation under short-term oxidative stress in Arabidopsis seedlings

et al. 2011

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“…Both approaches employ a microlevel view on the molecules in the system, instead of simply representing species populations by discrete numbers. That is, they allow a detailed, complex description of molecules, which may even contain additional structure for internal processes (eg the indole channel in the Tryptophan synthase (Degenring et al, 2004)). Here, stochasticity can be easily added to describe the behaviour of single model entities, that is, the state transitions of an atomic DEVS model or a STATECHART.…”

Section: Other Approachesmentioning

confidence: 99%

Discrete event modelling and simulation in systems biology

Ewald

Maus

Rolfs

et al. 2007

Journal of Simulation

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With Systems Biology, a promising new application area for modelling and simulation emerges. Today's biologists are facing huge amounts of data delivered at different levels of detail by a multitude of advanced experimentation techniques. The Systems Biology approach copes with this information by cycling through phases of forming hypotheses, constructing models, experimenting with or analysing these models, and validating the findings by wet-lab experiments. A crucial point is therefore the way in which the knowledge about a system is formalized, that is, how a biological system is described, as this constrains the perception of the system as well as the scope of possible answers the model might provide. In this article, we compare different discrete event modelling formalisms (PETRI NETS, Stochastic p-CALCULUS, STATECHARTS, and DEVS) regarding their applicability to a cell biological system of current research interest, the Wnt signalling pathway. We then introduce the popular Gillespie algorithm, which is the foundation of many discrete event simulators for molecular-biological systems, and elaborate on some interesting extensions.

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“…Therefore a discrete-event stochastic multi-level model was generated [100] to allow a more detailed description of the individual enzymes including additional structural (qualitative) information about the enzymes and to allow at the same time the reproduction of the in-vitro experiments. In spite of the additional com- [29] plexity the multi-level model should remain transparent for the experimentalists, see figure 3.…”

Section: Biological Example: Diverse Models For the Tryptophan Synthasementioning

confidence: 99%

“…in our case mainly the different binding-states of the enzymes, have to be modeled; -corresponding simulations can be realized in Stochsim: at each time step of the simulation, which is determined by the fastest reaction step, [29] i.e. in our case the tunneling reaction, two molecules were randomly chosen.…”

Section: Biological Example: Diverse Models For the Tryptophan Synthasementioning

confidence: 99%

“…The importance of these interdependencies has been emphasized for systems in general [19] and biological systems in particular [20,21], and also recently for Systems Biology with increasing urgency [22,23,24,25] motivating the development of concrete models, e.g. [26,27,28,29]. This paper is organized as follows: in chapter two the modeling approaches in the area of Systems Biology are categorized into the three modeling dimensions, which were described above (quantitative-qualitative, continuous-discrete and stochastic-deterministic); chapter three introduces the idea of the different organization levels for the distinction of the modeling approaches (micro, macro and multi-level models) and interrelates the categorization approach to the modeling dimensions studied in chapter two with a focus on multi-level models; after theoretical considerations about the different modeling dimensions and their interdependencies, chapter four illustrates the explorations based on a biological application example; chapter five gives a more in-detail discussion of the composition and interaction of multi-level models; it is followed by a general discussion, summary and outlook.…”

Section: Introductionmentioning

confidence: 99%

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Discrete Event Multi-level Models for Systems Biology

Uhrmacher

Degenring

Zeigler

2005

Lecture Notes in Computer Science

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Abstract. Diverse modeling and simulation methods are being applied in the area of Systems Biology. Most models in Systems Biology can easily be located within the space that is spanned by three dimensions of modeling: continuous and discrete; quantitative and qualitative; stochastic and deterministic. These dimensions are not entirely independent nor are they exclusive. Many modeling approaches are hybrid as they combine continuous and discrete, quantitative and qualitative, stochastic and deterministic aspects. Another important aspect for the distinction of modeling approaches is at which level a model describes a system: is it at the "macro" level, at the "micro" level, or at multiple levels of organization. Although multi-level models can be located anywhere in the space spanned by the three dimensions of modeling and simulation, clustering tendencies can be observed whose implications are discussed and illustrated by moving from a continuous, deterministic quantitative macro model to a stochastic discrete-event semi-quantitative multi-level model.

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Discrete event, multi-level simulation of metabolite channeling

Cited by 35 publications

References 32 publications

Alteration of mitochondrial protein complexes in relation to metabolic regulation under short-term oxidative stress in Arabidopsis seedlings

Alteration of mitochondrial protein complexes in relation to metabolic regulation under short-term oxidative stress in Arabidopsis seedlings

Discrete event modelling and simulation in systems biology

Discrete Event Multi-level Models for Systems Biology

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