The dynamics of genetic control in the cell: the good and bad of being late

Tiana, Guido; Jensen, Mogens H.

doi:10.1098/rsta.2012.0469

Cited by 13 publications

(11 citation statements)

References 26 publications

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“…-Time-delayed couplings arise naturally in many types of networks, for instance in coupled lasers [1], neural networks [2][3][4], electronic circuits [5], or genetic oscillators [6], due to finite signal transmission and processing times, and memory and latency effects. While investigating real-world systems, it is necessary to take time delay into account, since the presence of time delay is an inherent property of the vast majority of processes that occur in nature [7,8].…”

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confidence: 99%

Time delay control of symmetry-breaking primary and secondary oscillation death

Zakharova¹,

Schneider²,

Kyrychko³

et al. 2013

EPL

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-We show that oscillation death as a specific type of oscillation suppression, which implies symmetry breaking, can be controlled by introducing time-delayed coupling. In particular, we demonstrate that time delay influences the stability of an inhomogeneous steady state, providing the opportunity to modulate the threshold for oscillation death. Additionally, we find a novel type of oscillation death representing a secondary bifurcation of an inhomogeneous steady state.Introduction. -Time-delayed couplings arise naturally in many types of networks, for instance in coupled lasers [1], neural networks [2-4], electronic circuits [5], or genetic oscillators [6], due to finite signal transmission and processing times, and memory and latency effects. While investigating real-world systems, it is necessary to take time delay into account, since the presence of time delay is an inherent property of the vast majority of processes that occur in nature [7,8]. Moreover, time-delayed coupling and feedback represent an important aspect of control [9]. Previous theoretical and experimental works have shown that time delay can be treated as a control parameter and can stabilize initially unstable states. In particular, time-delayed feedback has been used to stabilize unstable periodic orbits embedded in a deterministic chaotic attractor [10,11], or generated by a Hopf bifurcation [12], unstable steady states [13], spatio-temporal patterns [14][15][16], or control the coherence and timescales of stochastic motion [17]. In coupled nonlinear systems and networks time-delayed couplings represent an ubiquitous feature [18] which can also be used to control stability.

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confidence: 99%

Time delay control of symmetry-breaking primary and secondary oscillation death

Zakharova¹,

Schneider²,

Kyrychko³

et al. 2013

EPL

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“…Transmission delays are common in physical networks, where they may impact synchronization processes of functionally similar constituting units [108]. Examples are optical systems [3] and gene expression networks [109]. In reaction-diffusion systems, such as the Gray-Scott model [110,111], delays impact the occurrence of self-organized spatio-temporal patterns.…”

Section: Network With Delay Couplingmentioning

confidence: 99%

Chaos in time delay systems, an educational review

2019

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The time needed to exchange information in the physical world induces a delay term when the respective system is modeled by differential equations. Time delays are hence ubiquitous, being furthermore likely to induce instabilities and with it various kinds of chaotic phases. Which are then the possible types of time delays, induced chaotic states, and methods suitable to characterize the resulting dynamics? This review presents an overview of the field that includes an in-depth discussion of the most important results, of the standard numerical approaches and of several novel tests for identifying chaos. Special emphasis is placed on a structured representation that is straightforward to follow. Several educational examples are included in addition as entry points to the rapidly developing field of time delay systems.

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“…With this platform, we study small ring networks of inhibitory genes, which exhibit nearly periodic oscillations of gene activity that evolve slowly to an asympotically stable periodic state. This is a prominent behavior in regulatory systems of organisms [44][45][46][47][48]. Specifically, we study the so-called repressilator [49] network, illustrated in Fig.…”

Section: Introductionmentioning

confidence: 99%

Transient dynamics and their control in time-delay autonomous Boolean ring networks

et al. 2017

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Biochemical systems with switch-like interactions, such as gene regulatory networks, are well modeled by autonomous Boolean networks. Specifically, the topology and logic of gene interactions can be described by systems of continuous piecewise-linear differential equations, enabling analytical predictions of the dynamics of specific networks. However, most models do not account for time delays along links associated with spatial transport, mRNA transcription, and translation. To address this issue, we we have developed an experimental testbed to realize a time-delay autonomous Boolean network with three inhibitory nodes, known as a repressilator, and use it to study the dynamics that arise as time delays along the links vary. We observe various nearly-periodic oscillatory transient patterns with extremely long lifetime, which emerge in small network motifs due to the delay, and which are distinct from the eventual asymptotically stable periodic attractors. For repeated experiments with a given network, we find that stochastic processes give rise to a broad distribution of transient times with an exponential tail. In some cases, the transients are so long that it is doubtful the attractors will ever be approached in a biological system that has a finite lifetime. To counteract the long transients, we show experimentally that small, occasional perturbations applied to the time delays can force the trajectories to rapidly approach the attractors.

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The dynamics of genetic control in the cell: the good and bad of being late

Cited by 13 publications

References 26 publications

Time delay control of symmetry-breaking primary and secondary oscillation death

Time delay control of symmetry-breaking primary and secondary oscillation death

Chaos in time delay systems, an educational review

Transient dynamics and their control in time-delay autonomous Boolean ring networks

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