Simulated Evolution of Signal Transduction Networks

Mobashir, Mohammad; Schraven, Burkhart; Beyer, Tilo

doi:10.1371/journal.pone.0050905

Cited by 22 publications

(24 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Currently, much of the theory related to evolution of signal transduction networks focuses on changes at the phenotypic level (e.g. changing protein interactions directly) [25,26]. In this paper we adapt a sequence-based evolutionary model due to Zulfikar et al [27] that allows us to map from sequence space (genotype) to rate constant space (phenotype).…”

Section: Introductionmentioning

confidence: 99%

Modeling evolution of crosstalk in noisy signal transduction networks

Tareen¹,

Wingreen²,

Mukhopadhyay³

2018

Phys. Rev. E

View full text Add to dashboard Cite

Signal transduction networks can form highly interconnected systems within cells due to crosstalk between constituent pathways. To better understand the evolutionary design principles underlying such networks, we study the evolution of crosstalk for two parallel signaling pathways that arise via gene duplication. We use a sequence-based evolutionary algorithm and evolve the network based on two physically motivated fitness functions related to information transmission. We find that one fitness function leads to a high degree of crosstalk while the other leads to pathway specificity. Our results offer insights on the relationship between network architecture and information transmission for noisy biomolecular networks.

show abstract

Section: Introductionmentioning

confidence: 99%

Modeling evolution of crosstalk in noisy signal transduction networks

Tareen¹,

Wingreen²,

Mukhopadhyay³

2018

Phys. Rev. E

View full text Add to dashboard Cite

show abstract

“…Weak PPIs also facilitate transient and strong signaling activation that underlies robust biological responses. [55] Protein partitioning results in the production of multiple responses by activating signaling in the cytosol and at the membrane surface. In other words, unlike TCS, an input signal is “diluted” by protein partitioning to generate multiple biological responses including gene transcription, protein synthesis, and metabolism that allow organisms to make time- and energy-efficient adjustments, depending on external perturbations.…”

Section: A Possible Contribution Of Macromolecular Crowding To Thementioning

confidence: 99%

A Link Between Alzheimer's and Type II Diabetes Mellitus? Ca⁺²‐Mediated Signal Control and Protein Localization

Tsutsui

Hays

2018

BioEssays

View full text Add to dashboard Cite

We propose protein localization dependent signal activation (PLDSA) as a model to describe pre-existing protein partitioning between the cytosol, and membrane surface, as a means to modulate signal activation, specificity, and robustness. We apply PLDSA to explain possible molecular links between type II diabetes mellitus (T2DM) and Alzheimer's disease (AD) by describing Ca -mediated interactions between the Src non-receptor tyrosine kinase and p52Shc adaptor protein. We suggest that these interactions may serve as a contributing factor to disease development and progression. In particular, we propose that signaling response is regulated, in part, by Ca -mediated partitioning of lipid-bound and soluble forms of Src and p52shc. Thus, protein-protein interactions that drive signaling in response to extracellular ligand binding are also mediated by partitioning of signaling proteins between membrane-bound and soluble populations. We propose that PLDSA effects may explain, in part, the evolutionary basis of promiscuous protein interaction domains and their importance in cellular function.

show abstract

“…Known as evolutionary algorithms, these methods can predict state changes in the behavior of signaling pathways over time, through adaptation or random mutation, by modeling this rewiring directly (Hallinan et al, 2010; Chen et al, 2011; Mobashir et al, 2012). In the same vein, these methods allow for the de novo construction and optimization of genetic networks by way of simulation (Bloom and Arnold, 2009), “evolving” a set of viable pathway designs that meet the specified constraints (Hallinan et al, 2010).…”

Section: Computational Techniques and Advances: Systems Biology Applimentioning

confidence: 99%

Systems approaches for synthetic biology: a pathway toward mammalian design

Rekhi

Qutub

2013

Front. Physiol.

View full text Add to dashboard Cite

We review methods of understanding cellular interactions through computation in order to guide the synthetic design of mammalian cells for translational applications, such as regenerative medicine and cancer therapies. In doing so, we argue that the challenges of engineering mammalian cells provide a prime opportunity to leverage advances in computational systems biology. We support this claim systematically, by addressing each of the principal challenges to existing synthetic bioengineering approaches—stochasticity, complexity, and scale—with specific methods and paradigms in systems biology. Moreover, we characterize a key set of diverse computational techniques, including agent-based modeling, Bayesian network analysis, graph theory, and Gillespie simulations, with specific utility toward synthetic biology. Lastly, we examine the mammalian applications of synthetic biology for medicine and health, and how computational systems biology can aid in the continued development of these applications.

show abstract

Simulated Evolution of Signal Transduction Networks

Cited by 22 publications

References 29 publications

Modeling evolution of crosstalk in noisy signal transduction networks

Modeling evolution of crosstalk in noisy signal transduction networks

A Link Between Alzheimer's and Type II Diabetes Mellitus? Ca⁺²‐Mediated Signal Control and Protein Localization

Systems approaches for synthetic biology: a pathway toward mammalian design

Contact Info

Product

Resources

About

Simulated Evolution of Signal Transduction Networks

Cited by 22 publications

References 29 publications

Modeling evolution of crosstalk in noisy signal transduction networks

Modeling evolution of crosstalk in noisy signal transduction networks

A Link Between Alzheimer's and Type II Diabetes Mellitus? Ca+2‐Mediated Signal Control and Protein Localization

Systems approaches for synthetic biology: a pathway toward mammalian design

Contact Info

Product

Resources

About

A Link Between Alzheimer's and Type II Diabetes Mellitus? Ca⁺²‐Mediated Signal Control and Protein Localization