Our world is full of noise sources at different spatial and temporal scales. The temperature and sunlight changes day to night. A receptor protein interacts with its target molecule undergoing Brownian motion. Although the noise can challenge survival of a living system, it can also play important 'active' roles such as random mutation and variations in phenotypes.
One example of noise as an active dynamical player is provided by so-called noise-induced transitions, which have been largely investigated in a variety of chemical, physical, and biological systems. These may occur when the system is affected by stochastic fluctuations of a control parameter, representing for instance a fluctuating environment, and are usually referred to as extrinsic noise. Extrinsic noise can produce highly non-trivial effects, such as the ‘creation’ of stable states, which in turn leads to the emergence of multistability or oscillatory behaviours in systems deterministically monostable.
We have recently formulated a description of extrinsic stochastic fluctuations at the level of gene expression that applies when the noise is nonlinear, non-Gaussian, and slower than typical protein synthesis and degradation processes. The aim of this project is to extend this formalism further, and validate the theoretical predictions in dedicated experiments.
The student will share his/her time equally between mathematical analysis and simulations of specific gene networks, and experimental work in the lab. Theoretically the work will include analysis of stochastic differential equations models, and the respective numerical simulations, while the experimental work will include building a cell mimic using dynamic RNA nanotechnology.
This project will constitute an important step forward in addressing the role of noise in our understanding of the principles of life and of evolutionary processes.
For the experimental work the student will have access to the soft matter physics laboratory and instruments in the Advanced Technology Institute at the University of Surrey.
Dr Andrea Rocco is Senior Lecturer in Physics and Mathematical Biology, with extensive experience in the analysis of stochastic processes in physical, chemical, and biological systems.
Dr Wooli Bae is a lecturer in experimental soft matter physics, specialised in experimental biophysics including DNA/RNA nanotechnology and synthetic biology.
This project is for a student with a UK nationality, EU settled, pre-settled status or indefinite leave to remain starting in October 2022.
Applicants are expected to hold a first or upper-second class degree in a relevant discipline (or equivalent overseas qualification), or a lower second plus a good Masters degree (distinction normally required). Any highly motivated individual with a keen interest in developing their research in stochastic processes at the interface with life sciences is encouraged to apply. Strong analytical and numerical skills, and/or previous wet-lab experience will be an advantage.
English language requirements: IELTS Academic 6.5 or above (or equivalent) with 6.0 in each individual category, or equivalent. More about our English language requirements.
How to apply
Apply via the Physics PhD programme page. Please clearly state the studentship title and supervisor on your application.