Bimodality in gene expression without feedback: from Gaussian white noise to log-normal coloured noise

Gerardo Aquino; Andrea Rocco; Gerardo Aquino; Andrea Rocco

doi:10.3934/mbe.2020361

Mathematical Biosciences and Engineering

2020, Volume 17, Issue 6: 6993-7017. doi: 10.3934/mbe.2020361

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Bimodality in gene expression without feedback: from Gaussian white noise to log-normal coloured noise

Gerardo Aquino ¹,
Andrea Rocco ^{1,2
,
,}

1.
Department of Microbial Sciences, Faculty of Health and Medical Sciences, University of Surrey, GU2 7XH Guildford, United Kingdom
2.
Department of Physics, Faculty of Engineering and Physical Sciences, University of Surrey, GU2 7XH Guildford, United Kingdom

Received: 21 June 2020 Accepted: 28 September 2020 Published: 16 October 2020

Extrinsic noise-induced transitions to bimodal dynamics have been largely investigated in a variety of chemical, physical, and biological systems. In the standard approach in physical and chemical systems, the key properties that make these systems mathematically tractable are that the noise appears linearly in the dynamical equations, and it is assumed Gaussian and white. In biology, the Gaussian approximation has been successful in specific systems, but the relevant noise being usually non-Gaussian, non-white, and nonlinear poses serious limitations to its general applicability. Here we revisit the fundamental features of linear Gaussian noise, pinpoint its limitations, and review recent new approaches based on nonlinear bounded noises, which highlight novel mechanisms to account for transitions to bimodal behaviour. We do this by considering a simple but fundamental gene expression model, the repressed gene, which is characterized by linear and nonlinear dependencies on external parameters. We then review a general methodology introduced recently, so-called nonlinear noise filtering, which allows the investigation of linear, nonlinear, Gaussian and non-Gaussian noises. We also present a derivation of it, which highlights its dynamical origin. Testing the methodology on the repressed gene confirms that the emergence of noise-induced transitions appears to be strongly dependent on the type of noise adopted, and on the degree of nonlinearity present in the system.
- noise-induced transitions,
- Langevin equation,
- log-normal noise,
- white and coloured noise,
- gene regulation
Citation: Gerardo Aquino, Andrea Rocco. Bimodality in gene expression without feedback: from Gaussian white noise to log-normal coloured noise[J]. Mathematical Biosciences and Engineering, 2020, 17(6): 6993-7017. doi: 10.3934/mbe.2020361

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Abstract

Extrinsic noise-induced transitions to bimodal dynamics have been largely investigated in a variety of chemical, physical, and biological systems. In the standard approach in physical and chemical systems, the key properties that make these systems mathematically tractable are that the noise appears linearly in the dynamical equations, and it is assumed Gaussian and white. In biology, the Gaussian approximation has been successful in specific systems, but the relevant noise being usually non-Gaussian, non-white, and nonlinear poses serious limitations to its general applicability. Here we revisit the fundamental features of linear Gaussian noise, pinpoint its limitations, and review recent new approaches based on nonlinear bounded noises, which highlight novel mechanisms to account for transitions to bimodal behaviour. We do this by considering a simple but fundamental gene expression model, the repressed gene, which is characterized by linear and nonlinear dependencies on external parameters. We then review a general methodology introduced recently, so-called nonlinear noise filtering, which allows the investigation of linear, nonlinear, Gaussian and non-Gaussian noises. We also present a derivation of it, which highlights its dynamical origin. Testing the methodology on the repressed gene confirms that the emergence of noise-induced transitions appears to be strongly dependent on the type of noise adopted, and on the degree of nonlinearity present in the system.

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