Stochastic and deterministic multiscale models for systems biology: an auxin-transport case study

Twycross, Jamie; Band, Leah R.; Bennett, Malcolm J.; King, John R.; Krasnogor, Natalio

doi:10.1186/1752-0509-4-34

Cited by 42 publications

(30 citation statements)

References 39 publications

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“…Thus sibling disciplines systems [2,27] and synthetic [7] biology depend crucially on the availability of sophisticated and expressive modeling methodologies and tools. Infobiotics approaches [40,25], also called Executable biology [14] and Algorithmic Systems Biology [35] are gaining momentum as alternative ways of modeling large biological complex systems. Infobiotics is based on models that are built not by specifying differential equations but rather mechanistically by defining algorithms (under a variety of possible formalisms) whose execution mimics the causal relation behind change and time/space dynamics in biological systems.…”

Section: Infobiotics Model Evolution In Systems and Synthetic Biologymentioning

confidence: 99%

Evolutionary symbolic discovery for bioinformatics, systems and synthetic biology

Widera

Bacardit

Krasnogor

et al. 2010

Proceedings of the 12th Annual Conference Companion on Genetic and Evolutionary Computation

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Symbolic regression and modeling are tightly linked in many Bioinformatics, Systems and Synthetic Biology problems. In this paper we briefly overview two problems, and the approaches we have use to tackle them, that can be deemed to represent this entwining of regression and modeling, namely, the evolutionary discovery of (1) effective energy functions for protein structure prediction and (2) models that capture biological behavior at the gene, signaling and metabolic networks level. These problems are not, strictly speaking, "regression problems" but they do share several characteristics with the latter, namely, a symbolic representation of a solution is sought , this symbolic representation must be human understandable and the results obtained by the symbolic and human interpretable solution must fit the available data without over-learning.

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Section: Infobiotics Model Evolution In Systems and Synthetic Biologymentioning

confidence: 99%

Evolutionary symbolic discovery for bioinformatics, systems and synthetic biology

Widera

Bacardit

Krasnogor

et al. 2010

Proceedings of the 12th Annual Conference Companion on Genetic and Evolutionary Computation

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“…Entre ellos podemos mencionar los continuos-deterministas (Twycross et al, 2010), y aquellos discretos-estocásticos (Mura, 2010). En el contexto de este trabajo de investigación, nos limitamos a considerar el enfoque continuo-determinista, el más utilizado a la hora de construir modelos matemáticos en epidemiología.…”

Section: Modelado Predictivo De Sistemas Biológicosunclassified

Modelado predictivo de la epidemia de Chikungunya

Martínez¹,

Gil²,

Guzman³

et al. 2016

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ResumenEste artículo presenta los resultados preliminares de una investigación multidisciplinaria que se está realizando en un proyecto de semillero en la Universidad EAN, y que tiene como objetivo el desarrollo de un modelo matemático predictivo de la difusión del Chikungunya en Colombia. Para enfrentarse a la epidemia, es necesario disponer de predicciones sobre la difusión de la enfermedad que permiten planear las respuestas sanitarias necesarias, así como evaluar la efectividad de las acciones de contraste, como por ejemplo la lucha química o biológica contra los mosquitos vectores. En el presente trabajo, se muestran los elementos esenciales para la construcción de modelos matemáticos basados en un sistema de ecuaciones diferenciales, cuya solución en el tiempo, proporcione una predicción a las poblaciones de humanos y vectores infectados por el virus del Chikungunya. El trabajo se fundamenta en las técnicas de modelado de sistemas biológicos, y a partir de una revisión de la literatura, propone construir un modelo que incluya los aspectos principales que afectan la difusión de la enfermedad y que se pueda adaptar a las condiciones específicas del área bajo objeto de estudio. El resultado final de la investigación, proporcionará una herramienta valiosa para implementar en la toma de decisiones en cuanto a las respuestas más adecuadas al momento de contrastar y controlar la difusión de esta enfermedad. PalabRas clave

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“…The derived equations provide insight into the underlying dynamics and show how the cell-scale parameters influence the effective velocity and diffusivity of the auxin flux. The benefits of this multiscale analytical approach have recently been highlighted by Twycross et al (2010). Similar modelling approaches have been used to study calcium dynamics (Goel et al 2006), pattern formation (Newell et al 2008) and nutrient distributions (Shipley et al 2009), for example, and the effective tissue-scale auxin transport has also been considered in Chavarría-Krauser and Ptashnyk (2009); Kramer (2002); Martin et al (1990); Mitchison (1980a,b); Mitchison et al (1981) and Newell et al (2008).…”

Section: Introductionmentioning

confidence: 99%

Multiscale modelling of auxin transport in the plant-root elongation zone

Band

King

2011

J. Math. Biol.

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In the root elongation zone of a plant, the hormone auxin moves in a polar manner due to active transport facilitated by spatially distributed influx and efflux carriers present on the cell membranes. To understand how the cell-scale active transport and passive diffusion combine to produce the effective tissue-scale flux, we apply asymptotic methods to a cell-based model of auxin transport to derive systematically a continuum description from the spatially discrete one. Using biologically relevant parameter values, we show how the carriers drive the dominant tissue-scale auxin flux and we predict how the overall auxin dynamics are affected by perturbations to these carriers, for example, in knockout mutants. The analysis shows how the dominant behaviour depends on the cells' lengths, and enables us to assess the relative importance of the diffusive auxin flux through the cell wall. Other distinguished limits are also identified and their potential roles discussed. As well as providing insight into auxin transport, the study illustrates the use of multiscale (cell to tissue) methods in deriving simplified models that retain the essential biology and provide understanding of the underlying dynamics.

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Stochastic and deterministic multiscale models for systems biology: an auxin-transport case study

Cited by 42 publications

References 39 publications

Evolutionary symbolic discovery for bioinformatics, systems and synthetic biology

Evolutionary symbolic discovery for bioinformatics, systems and synthetic biology

Modelado predictivo de la epidemia de Chikungunya

Multiscale modelling of auxin transport in the plant-root elongation zone

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