Luis Mendoza scite author profile

Motivation: In silico modeling of gene regulatory networks has gained some momentum recently due to increased interest in analyzing the dynamics of biological systems. This has been further facilitated by the increasing availability of experimental data on gene–gene, protein–protein and gene–protein interactions. The two dynamical properties that are often experimentally testable are perturbations and stable steady states. Although a lot of work has been done on the identification of steady states, not much work has been reported on in silico modeling of cellular differentiation processes.Results: In this manuscript, we provide algorithms based on reduced ordered binary decision diagrams (ROBDDs) for Boolean modeling of gene regulatory networks. Algorithms for synchronous and asynchronous transition models have been proposed and their corresponding computational properties have been analyzed. These algorithms allow users to compute cyclic attractors of large networks that are currently not feasible using existing software.Hereby we provide a framework to analyze the effect of multiple gene perturbation protocols, and their effect on cell differentiation processes. These algorithms were validated on the T-helper model showing the correct steady state identification and Th1–Th2 cellular differentiation process.Availability: The software binaries for Windows and Linux platforms can be downloaded from http://si2.epfl.ch/~garg/genysis.html.Contact: abhishek.garg@epfl.ch

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Genetic control of flower morphogenesis in Arabidopsis thaliana: a logical analysis.

Mendoza¹,

Thieffry²,

Alvarez-Buylla³

1999

270

188

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The genetic control of flower morphogenesis in Arabidopsis involves a large number of genes, of which 10 are considered here. The network topology has been derived from published genetic and molecular data, mainly relying on mRNA expression patterns under wild-type and mutant backgrounds. Using a 'generalized logical formalism', we provide a qualitative model and derive the parameter constraints accounting for the different patterns of gene expression found in the four floral organs of Arabidopsis (sepals, petals, stamens and carpels), plus a 'non-floral' state. This model also allows the simulation or the prediction of various mutant phenotypes. On the basis of our model analysis, we predict the existence of a sixth stable pattern of gene expression, yet to be characterized experimentally. Moreover, our dynamical analysis leads to the prediction of at least one more regulator of the gene LFY, likely to be involved in the transition from the non-flowering state to the flowering pathways. Finally, this work, together with other theoretical and experimental considerations, leads us to propose some general conclusions about the structure of gene networks controlling development.

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Dynamics of the Genetic Regulatory Network forArabidopsis thalianaFlower Morphogenesis

Mendoza

Álvarez-Buylla

1998

Journal of Theoretical Biology

228

160

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A network model for the control of the differentiation process in Th cells

Mendoza¹

2006

Biosystems

153

160

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Luis Mendoza

Synchronous versus asynchronous modeling of gene regulatory networks

Genetic control of flower morphogenesis in Arabidopsis thaliana: a logical analysis.

Dynamics of the Genetic Regulatory Network forArabidopsis thalianaFlower Morphogenesis

A network model for the control of the differentiation process in Th cells

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