Degeneracy in the regulation of short-term plasticity and synaptic filtering by presynaptic mechanisms

Mukunda, Chinmayee L. ; Narayanan, Rishikesh (2017) Degeneracy in the regulation of short-term plasticity and synaptic filtering by presynaptic mechanisms The Journal of Physiology, 595 (8). pp. 2611-2637. ISSN 0022-3751

Full text not available from this repository.

Official URL: http://doi.org/10.1113/JP273482

Related URL: http://dx.doi.org/10.1113/JP273482

Abstract

Information processing in neurons is known to emerge as a gestalt of pre- and post-synaptic filtering. However, the impact of presynaptic mechanisms on synaptic filters has not been quantitatively assessed. Here, we developed a biophysically rooted, conductance-based model synapse that was endowed with six different voltage-gated ion channels, calcium pumps, calcium buffer and neurotransmitter-replenishment mechanisms in the presynaptic terminal. We tuned our model to match the short-term plasticity profile and band-pass structure of Schaffer collateral synapses, and performed sensitivity analyses to demonstrate that presynaptic voltage-gated ion channels regulated synaptic filters through changes in excitability and associated calcium influx. These sensitivity analyses also revealed that calcium- and release-control mechanisms were effective regulators of synaptic filters, but accomplished this without changes in terminal excitability or calcium influx. Next, to perform global sensitivity analysis, we generated 7000 randomized models spanning 15 presynaptic parameters, and computed eight different physiological measurements in each of these models. We validated these models by applying experimentally obtained bounds on their measurements, and found 104 (∼1.5%) models to match the validation criteria for all eight measurements. Analysing these valid models, we demonstrate that analogous synaptic filters emerge from disparate combinations of presynaptic parameters exhibiting weak pairwise correlations. Finally, using virtual knockout models, we establish the variable and differential impact of different presynaptic channels on synaptic filters, underlining the critical importance of interactions among different presynaptic components in defining synaptic physiology. Our results have significant implications for protein-localization strategies required for physiological robustness and for degeneracy in long-term synaptic plasticity profiles.

Item Type:Article
Source:Copyright of this article belongs to Physiological Society.
ID Code:121718
Deposited On:21 Jul 2021 11:11
Last Modified:21 Jul 2021 11:11

Repository Staff Only: item control page