Team:KU Leuven/Project/Oscillator/Modelling

In this part of the wiki we will describe how we performed an analysis of our proposed oscillating system and the results. This text starts with a small introduction on what we want to achieve with this oscillator, a topic that is more thoroughly elaborated on the design page. Before we started the analysis that is stated here, we looked up how similar networks have been analyzed before in order to see what direction we will take. A full-scale analysis would go beyond the scope of the project so we will stick to an elaborate indicative study. The first step is to translate our network into ODE’s (ordinary differential equations), which we will make more realistic step by step. We will use these to see how easily sustained oscillations form. This is of course not the most impressive feature since there are many known networks that easily produce oscillations. We chose not to include the effect on amplitude and frequency, since that would make the scope of this study explode and the many assumptions we have to make, render it unrealistic. The important feature of our network is its synchronization features. In order to check whether our model achieves rapid resynchronization, we will solve systems of PDE’s (partial differential equations). Since those are a lot more computationally intense, we used the Flemish Super Computer Centre (VSC) in order to do our computations time-efficiently. The explanation of how the network functions and how it attains synchronized oscillations can be found on the page explaining the design. For the transformation into a biological network, we refer you to the wetlab page.

Firstly, it is important to clarify what we exactly mean with ‘parameter’. A biochemical system has a very high variability in ranges for transcription rates, translation rates, degradation rates, etc. On top of that these parameters are not perfectly quantified and are subject to changes in the conditions. We checked what part of the parameter space (Box 1) creates oscillations. There are possibilities for doing this in a purely mathematical manner. Tyson (2002) gives a good example of how to study systems that produce biochemical oscillations. Polynikis, Hogan and Bernardo (2009) described modelling approaches for gene regulatory networks more generally. This is typically done by investigating the eigenvalues of the Jacobian matrix of the system. This becomes increasingly more difficult when the number of parameters and variables increases. A high level of non-linearity complicates the study of the behavior even further. In order to see what is possible we contacted Professor Dirk Roose, an expert in non-linear systems analysis. We explained him we want to investigate what parameter values create a synchronized oscillation. However, our parameter space consists of about 20 parameters that can each vary with more than a factor ten. On top of that we will have highly non-linear equations. Professor Roose told us this amount of variability would make a clean-cut mathematical examination of our model impossible . Since it is not possible to reduce our parameter space, without diverting from our goal of fully studying our system, we decided to use another strategy. We will study this enormous parameter space by generating random sets of parameters throughout this space. This offers a less theoretical, nonetheless effective means of assuring this model robustly produces oscillations.