Robust Network Topologies for Generating Switch-Like Cellular Responses

Shah, Najaf A.; Sarkar, Casim A.

doi:10.1371/journal.pcbi.1002085

Cited by 99 publications

(97 citation statements)

References 51 publications

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“…For example, hundreds of distinct RNA sequences fold in the same secondary structure (3), as do proteins in their 3D structure (4). Similarly, distinct gene regulatory architectures can produce the same gene expression pattern (5,6) or temporal behavior (7,8). However, among these genotypes, some are more evolvable than others.…”

Section: Dynamics Of Gene Circuits Shapes Evolvabilitymentioning

confidence: 99%

Dynamics of gene circuits shapes evolvability

Jiménez

Cotterell

Munteanu

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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To what extent does the dynamical mechanism producing a specific biological phenotype bias the ability to evolve into novel phenotypes? We use the interpretation of a morphogen gradient into a single stripe of gene expression as a model phenotype. Although there are thousands of three-gene circuit topologies that can robustly develop a stripe of gene expression, the vast majority of these circuits use one of just six fundamentally different dynamical mechanisms. Here we explore the potential for gene circuits that use each of these six mechanisms to evolve novel phenotypes such as multiple stripes, inverted stripes, and gradients of gene expression. Through a comprehensive and systematic analysis, we find that circuits that use alternative mechanisms differ in the likelihood of reaching novel phenotypes through mutation. We characterize the phenotypic transitions and identify key ingredients of the evolutionary potential, such as sensitive interactions and phenotypic hubs. Finally, we provide an intuitive understanding on how the modular design of a particular mechanism favors the access to novel phenotypes. Our work illustrates how the dynamical mechanism by which an organism develops constrains how it can evolve. It is striking that these dynamical mechanisms and their impact on evolvability can be observed even for such an apparently simple patterning task, performed by just three-node circuits.

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Section: Dynamics Of Gene Circuits Shapes Evolvabilitymentioning

confidence: 99%

Dynamics of gene circuits shapes evolvability

Jiménez

Cotterell

Munteanu

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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“…A broad array of signaling strategies (e.g. positive feedback loops) have been proposed to underlie this robust ultrasensitivity response (Shah and Sarkar, 2011). Recent mathematical models (Ferrell, 1998;Bhalla, 2011;Santos et al, 2012;Harrington et al, 2013) have revealed that the subcellular spatial organization of signaling molecules is best suited for generating a diverse set of cellular states, including such bistable switches.…”

Section: Discussionmentioning

confidence: 99%

Nuclear to cytoplasmic shuttling of ERK promotes differentiation of muscle stem/progenitor cells

et al. 2014

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The transition between the proliferation and differentiation of progenitor cells is a key step in organogenesis, and alterations in this process can lead to developmental disorders. The extracellular signal-regulated kinase 1/2 (ERK) signaling pathway is one of the most intensively studied signaling mechanisms that regulates both proliferation and differentiation. How a single molecule (e.g. ERK) can regulate two opposing cellular outcomes is still a mystery. Using both chick and mouse models, we shed light on the mechanism responsible for the switch from proliferation to differentiation of head muscle progenitors and implicate ERK subcellular localization. Manipulation of the fibroblast growth factor (FGF)-ERK signaling pathway in chick embryos in vitro and in vivo demonstrated that blockage of this pathway accelerated myogenic differentiation, whereas its activation diminished it. We next examined whether the spatial subcellular localization of ERK could act as a switch between proliferation (nuclear ERK) and differentiation (cytoplasmic ERK) of muscle progenitors. A myristoylated peptide that blocks importin 7-mediated ERK nuclear translocation induced robust myogenic differentiation of muscle progenitor/stem cells in both head and trunk. In the mouse, analysis of Sprouty mutant embryos revealed that increased ERK signaling suppressed both head and trunk myogenesis. Our findings, corroborated by mathematical modeling, suggest that ERK shuttling between the nucleus and the cytoplasm provides a switch-like transition between proliferation and differentiation of muscle progenitors.

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“…Our approach, however, is not biased towards any specific architecture since we evaluate the robustness of every possible three-component network. Similar studies have also been carried out, but for analyzing adaptation (Ma et al 2009), switch-like responses (Shah and Sarkar 2011) and patterning in response to morphogen gradients (Cotterell and Sharpe 2010).…”

Section: Introductionmentioning

confidence: 98%

Design principles for robust oscillatory behavior

2015

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Oscillatory responses are ubiquitous in regulatory networks of living organisms, a fact that has led to extensive efforts to study and replicate the circuits involved. However, to date, design principles that underlie the robustness of natural oscillators are not completely known. Here we study a three-component enzymatic network model in order to determine the topological requirements for robust oscillation. First, by simulating every possible topological arrangement and varying their parameter values, we demonstrate that robust oscillators can be obtained by augmenting the number of both negative feedback loops and positive autoregulations while maintaining an appropriate balance of positive and negative interactions. We then identify network motifs, whose presence in more complex topologies is a necessary condition for obtaining oscillatory responses. Finally, we pinpoint a series of simple architectural patterns that progressively render more robust oscillators. Together, these findings can help in the design of more reliable synthetic biomolecular networks and may also have implications in the understanding of other oscillatory systems.

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Robust Network Topologies for Generating Switch-Like Cellular Responses

Cited by 99 publications

References 51 publications

Dynamics of gene circuits shapes evolvability

Dynamics of gene circuits shapes evolvability

Nuclear to cytoplasmic shuttling of ERK promotes differentiation of muscle stem/progenitor cells

Design principles for robust oscillatory behavior

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