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advantage of the method lies in the fact that it is possible to model processes without pre
cise data on the speed (“kinetics”). If, on the other hand, one wants to model a dynamic
process, in particular a signal cascade, in more detail, one must determine these data about
the velocity. This is done by methods of time series analysis: If one has measured the pro
cess (for example the phosphorylation of a kinase that transmits a signal in the cell) for
five or more time points, there is enough data to estimate how fast this process proceeds.
It is therefore possible to describe the speed (kinetics) precisely in mathematical terms
using a parameter (in the example: the speed). There are a number of bioinformatics tools
for estimating parameters. Easy to learn and good to use for this parameter estimation is
the software Potters Wheel (https://www.potterswheel.de/Pages/; Maiwald and Timmer
2008) and its successor Data2Dynamics (Steiert et al., 2019).
This software can also be used to investigate which parameters need to be accurately
estimated and which do not (sensitivity analysis). It also allows to see which of the param
eters can be well estimated from the data (identifiability analysis) and which cannot (either
because the data are not sufficient or because the network is wired in such a way that, for
example, the parameter always depends on another one that cannot be estimated either or
because the parameter is simply not determined by this data at all).
Conclusion
• Systems biology modelling of signalling cascades and protein networks allows deeper
insights into the function of the proteins involved and thus helps to understand the
causes of diseases, to better describe infection processes and immune responses, or to
elucidate complex processes in biology, such as cell differentiation and neurobiology.
Stronger mathematical models describe signalling networks precisely in terms of
changes over time and their speed using differential equations. This explains the pro
cess exactly, but additional time is needed, e.g. with the determination of the velocities
(kinetics, data driven modeling, time series analysis).
• Boolean models only require information about which proteins are involved in the net
work and which protein interacts with which other proteins and how (activating or
inhibiting). Therefore, they are well suited for an introduction. If you want to reproduce
one of the presented examples yourself, it is easy (use the same components and links
and software). However, if you want to create your own new model, many cycles are
necessary, because you have to check again and again in simulations based on the
Boolean model (e.g. with SQUAD or Jimena) whether the behaviour in the computer
model also matches the outcome actually observed in the experiment, at least qualita
tively, and thus adapt the computer model to the data step by step.
• Conversely, the model then allows to describe all situations that have not yet been mea
sured or reproduced in the experiment. In particular, the effect of drugs and their com
binations, the activity of all proteins involved, the effect of signals, mutations or even
immune substances (e.g. cytokines). Systems biology modeling can be described as the
central, current field of bioinformatics. It is also called network analysis, dynamic mod
elling or interactomics in order to emphasize these aspects more strongly. ◄