Regulation of oscillation dynamics in biochemical systems with dual negative feedback loops

Nguyen, Lan K.

doi:10.1098/rsif.2012.0028

Cited by 33 publications

(39 citation statements)

References 57 publications

(92 reference statements)

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“…Indeed, these properties are not required for the NFkB dimer stabilization/chaperone function recently ascribed to IkBb [28]. Our results illustrate the more general point: that negative feedback regulation in cells is a complex process that depends on multiple molecular properties beyond activator-induced expression [29,30]. These findings may well extend to other transcriptional networks as nuclear transport is a defining feature of many gene regulatory networks.…”

Section: Discussionsupporting

confidence: 59%

Anatomy of a negative feedback loop: the case of I κ B α

Fagerlund

Behar

Fortmann

et al. 2015

J. R. Soc. Interface.

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The magnitude, duration and oscillation of cellular signalling pathway responses are often limited by negative feedback loops, defined as an 'activator-induced inhibitor' regulatory motif. Within the NFkB signalling pathway, a key negative feedback regulator is IkBa. We show here that, contrary to current understanding, NFkB-inducible expression is not sufficient for providing effective negative feedback. We then employ computational simulations of NFkB signalling to identify IkBa molecular properties that are critical for proper negative feedback control and test the resulting predictions in biochemical and single-cell live-imaging studies. We identified nuclear import and nuclear export of IkBa and the IkBa-NFkB complex, as well as the free IkBa half-life, as key determinants of post-induction repression of NFkB and the potential for subsequent reactivation. Our work emphasizes that negative feedback is an emergent systems property determined by multiple molecular and biophysical properties in addition to the required 'activator-induced inhibitor' relationship.

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Section: Discussionsupporting

confidence: 59%

Anatomy of a negative feedback loop: the case of I κ B α

Fagerlund

Behar

Fortmann

et al. 2015

J. R. Soc. Interface.

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“…This observation confirms previous results [21, 35] showing that nested auto-inhibitory feedbacks repress oscillatory dynamics in networks containing DNF.…”

Section: Resultssupporting

confidence: 93%

How time delay and network design shape response patterns in biochemical negative feedback systems

Börsch

Schaber

2016

BMC Syst Biol

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BackgroundNegative feedback in combination with time delay can bring about both sustained oscillations and adaptive behaviour in cellular networks. Here, we study which design features of systems with delayed negative feedback shape characteristic response patterns with special emphasis on the role of time delay. To this end, we analyse generic two-dimensional delay differential equations describing the dynamics of biochemical signal-response networks.ResultsWe investigate the influence of several design features on the stability of the model equilibrium, i.e., presence of auto-inhibition and/or mass conservation and the kind and/or strength of the delayed negative feedback. We show that auto-inhibition and mass conservation have a stabilizing effect, whereas increasing abruptness and decreasing feedback threshold have a de-stabilizing effect on the model equilibrium. Moreover, applying our theoretical analysis to the mammalian p53 system we show that an auto-inhibitory feedback can decouple period and amplitude of an oscillatory response, whereas the delayed feedback can not.ConclusionsOur theoretical framework provides insight into how time delay and design features of biochemical networks act together to elicit specific characteristic response patterns. Such insight is useful for constructing synthetic networks and controlling their behaviour in response to external stimulation.Electronic supplementary materialThe online version of this article (doi:10.1186/s12918-016-0325-9) contains supplementary material, which is available to authorized users.

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“…While a primary function of negative feedback regulation is to enable signal adaptation, it is well known to underlie oscillatory behaviours [50,51]. Under concurrent control of multiple negative feedbacks, it is expected that HIF-1 may oscillate in specific cellular contexts [51].…”

Section: What Controls Hif-1's Oscillation?mentioning

confidence: 99%

“…Under concurrent control of multiple negative feedbacks, it is expected that HIF-1 may oscillate in specific cellular contexts [51].…”

Section: What Controls Hif-1's Oscillation?mentioning

confidence: 99%

Understanding complexity in the HIF signaling pathway using systems biology and mathematical modeling

2016

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Regulation of oscillation dynamics in biochemical systems with dual negative feedback loops

Cited by 33 publications

References 57 publications

Anatomy of a negative feedback loop: the case of I κ B α

Anatomy of a negative feedback loop: the case of I κ B α

How time delay and network design shape response patterns in biochemical negative feedback systems

Understanding complexity in the HIF signaling pathway using systems biology and mathematical modeling

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