TY - JOUR
T1 - Transient dynamics and their control in time-delay autonomous Boolean ring networks
AU - Lohmann, Johannes
AU - D'Huys, Otti
AU - Haynes, Nicholas D.
AU - Schöll, Eckehard
AU - Gauthier, Daniel J.
PY - 2017/2/1
Y1 - 2017/2/1
N2 - Biochemical systems with switch-like interactions, such as gene
regulatory networks, are well modeled by autonomous Boolean networks.
Specifically, the topology and logic of gene interactions can be
described by systems of continuous piecewise-linear differential
equations, enabling analytical predictions of the dynamics of specific
networks. However, most models do not account for time delays along
links associated with spatial transport, mRNA transcription, and
translation. To address this issue, we have developed an experimental
test bed to realize a time-delay autonomous Boolean network with three
inhibitory nodes, known as a repressilator, and use it to study the
dynamics that arise as time delays along the links vary. We observe
various nearly periodic oscillatory transient patterns with extremely
long lifetime, which emerge in small network motifs due to the delay,
and which are distinct from the eventual asymptotically stable periodic
attractors. For repeated experiments with a given network, we find that
stochastic processes give rise to a broad distribution of transient
times with an exponential tail. In some cases, the transients are so
long that it is doubtful the attractors will ever be approached in a
biological system that has a finite lifetime. To counteract the long
transients, we show experimentally that small, occasional perturbations
applied to the time delays can force the trajectories to rapidly
approach the attractors.
AB - Biochemical systems with switch-like interactions, such as gene
regulatory networks, are well modeled by autonomous Boolean networks.
Specifically, the topology and logic of gene interactions can be
described by systems of continuous piecewise-linear differential
equations, enabling analytical predictions of the dynamics of specific
networks. However, most models do not account for time delays along
links associated with spatial transport, mRNA transcription, and
translation. To address this issue, we have developed an experimental
test bed to realize a time-delay autonomous Boolean network with three
inhibitory nodes, known as a repressilator, and use it to study the
dynamics that arise as time delays along the links vary. We observe
various nearly periodic oscillatory transient patterns with extremely
long lifetime, which emerge in small network motifs due to the delay,
and which are distinct from the eventual asymptotically stable periodic
attractors. For repeated experiments with a given network, we find that
stochastic processes give rise to a broad distribution of transient
times with an exponential tail. In some cases, the transients are so
long that it is doubtful the attractors will ever be approached in a
biological system that has a finite lifetime. To counteract the long
transients, we show experimentally that small, occasional perturbations
applied to the time delays can force the trajectories to rapidly
approach the attractors.
U2 - 10.1103/PhysRevE.95.022211
DO - 10.1103/PhysRevE.95.022211
M3 - Article
SN - 2470-0045
VL - 95
JO - Physical Review E
JF - Physical Review E
IS - 2
M1 - 022211
ER -