Analysis of primitive genetic interactions for the design of a genetic signal differentiator

Halter, Wolfgang; Murray, Richard M.; Allgöwer, Frank

doi:10.1093/synbio/ysz015

Cited by 8 publications

(4 citation statements)

References 30 publications

(33 reference statements)

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“…Recent efforts in this rather underexplored research area include the design of a differentiator module consisting of linear input/output functions realized by specific processes of protein production [14, 15]. It has further been demonstrated that calculation of time derivatives is possible by using ultrasensitive topologies operating within a negative feedback loop [16], and a motif capable of computing positive and negative temporal gradients, which includes input delays and the idea of an incoherent feed-forward loop, has been presented [17].…”

Section: Introductionmentioning

confidence: 99%

Biomolecular mechanisms for signal differentiation

Alexis

Schulte

Cardelli

et al. 2021

Preprint

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Cells can sense temporal changes of molecular signals, allowing them to predict environmental variations and modulate their behaviour. This paper elucidates the underlying biomolecular mechanisms of time derivative computation, facilitating the design of reliable synthetic differentiator devices for a variety of applications, ultimately expanding our understanding of cell behaviour. In particular, we describe and analyse three alternative biomolecular topologies that work as signal differentiators of high accuracy to arbitrary input signals around their nominal operation. We propose strategies to preserve their performance even in the presence of high-frequency input signal components, which are detrimental to the performance of most differentiators. We found that the core of the proposed topologies appears in natural regulatory networks and we further discuss their biological relevance. The simple structure of our designs makes them promising tools for realizing derivative control action in synthetic biology.

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Section: Introductionmentioning

confidence: 99%

Biomolecular mechanisms for signal differentiation

Alexis

Schulte

Cardelli

et al. 2021

Preprint

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“…BioSD modules can also be employed for derivative control, potentially in conjunction with proportional and integral action (PID control) [17]. Note that different approaches to realizing derivative action (including derivative control) via biochemical interactions have been proposed in the recent literature [12]- [16], [18], [20]- [22]. For a concise comparative discussion, we refer the reader to [23].…”

Section: Introductionmentioning

confidence: 99%

AC-BioSD : A biomolecular signal differentiator module with enhanced performance (extended version)

Alexis,

Avalos,

Cardelli

et al. 2024

Preprint

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Temporal gradient estimation is a pervasive phenomenon in natural biological systems and holds great promise for synthetic counterparts with broad-reaching applications. Here, we advance the concept of BioSD signal differentiation by introducing a novel biomolecular topology, termed AC-BioSD. Its structure allows for insensitivity to input signal changes and high precision in terms of signal differentiation, even when operating far from nominal conditions. Concurrently, disruptive high-frequency signal components are effectively attenuated. In addition, the usefulness of our topology in biological regulation is highlighted via a PID bio-control scheme with set point weighting and filtered derivative action in both the deterministic and stochastic domains.

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“…Recent efforts in this rather underexplored research area include the design of a differentiator module consisting of linear input/output functions realized by specific processes of protein production ( Halter et al., 2017 ; Halter et al., 2019 ). It has further been demonstrated that calculation of time derivatives is possible by using ultrasensitive topologies operating within a negative feedback loop ( Samaniego et al., 2019 ), and a motif capable of computing positive and negative temporal gradients, which includes input delays and the idea of an incoherent feedforward loop, has been presented ( Samaniego et al., 2020 ).…”

Section: Introductionmentioning

confidence: 99%

Biomolecular mechanisms for signal differentiation

et al. 2021

View full text Add to dashboard Cite

Summary Cells can sense temporal changes of molecular signals, allowing them to predict environmental variations and modulate their behavior. This paper elucidates biomolecular mechanisms of time derivative computation, facilitating the design of reliable synthetic differentiator devices for a variety of applications, ultimately expanding our understanding of cell behavior. In particular, we describe and analyze three alternative biomolecular topologies that are able to work as signal differentiators to input signals around their nominal operation. We propose strategies to preserve their performance even in the presence of high-frequency input signal components which are detrimental to the performance of most differentiators. We find that the core of the proposed topologies appears in natural regulatory networks and we further discuss their biological relevance. The simple structure of our designs makes them promising tools for realizing derivative control action in synthetic biology.

show abstract

Analysis of primitive genetic interactions for the design of a genetic signal differentiator

Cited by 8 publications

References 30 publications

Biomolecular mechanisms for signal differentiation

Biomolecular mechanisms for signal differentiation

AC-BioSD : A biomolecular signal differentiator module with enhanced performance (extended version)

Biomolecular mechanisms for signal differentiation

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