Abstract:
Mutually inhibiting neurons is a common motif across many systems like Hip-
pocampus, CPGs(Central Pattern Generators) and Olfaction. Their synaptic interac-
tion ensures that they show alternating activity. The frequency of switching from an
active to a quiescent period is a function of the biophysical properties of ion channels
present in the neurons, synaptic interaction timescales, network properties, the stim-
ulus and possibly channel
uctuations from a small number of channels. Switching
allows neurons to associate with different networks and coordinate patterns of activity
that may be relevant for function. The frequency of switching dictates the sequential
order of activity of neurons required for locomotion, for example in Lamprey. In this
context, reliable switching might be a critical functional requirement. How do net-
works of mutually inhibiting neurons, a simple most functional module of switching,
achieve this reliability despite a noisy framework and environment? We have devel-
oped a conductance-based model of two mutually inhibiting neurons wherein inherent
switching takes place via a potassium current, sAHP that is triggered by calcium ions.
We systematically study the effect of various sources of noise including channel con-
ductance noise, and input noise on switching and robust generation of sequences. Our
results show that switching frequency can be tuned with noise amplitude of the ex-
trinsic noise. It has been previously shown that calcium channel
uctuations are the
largest contributors of stochasticity at the synapse. As a control simulation experi-
ment, we isolate contributions of calcium channel
uctuations. In this framework, only
the calcium dynamics is modeled with a Markovian scheme, and other components are
deterministic. Our results suggest that an optimal number of calcium channels help
achieve precise switching. This study sheds light on how channel
uctuations affect
the network activity and cannot be ignored a priori when slow decay time scales are
involved in the neuronal dynamics. Our understanding of the effects of various sources
of noise in this illustrative network motif is likely to be applicable to a wide variety of
systems.