Emergence of Connectivity Motifs in Networks of Model Neurons with Short- and Long-term Plastic Synapses

TL;DR

This study demonstrates how the interaction between short-term synaptic dynamics and long-term plasticity can lead to the emergence of specific connectivity motifs in neural networks, aligning with observed biological patterns.

Contribution

The paper introduces a computational model combining short-term dynamics and spike-timing dependent plasticity to explain the formation of connectivity motifs in neural circuits.

Findings

Depressing synapses lead to unidirectional connectivity motifs.

Facilitating synapses promote reciprocal connectivity motifs.

Model predictions align with experimental observations.

Abstract

Recent evidence in rodent cerebral cortex and olfactory bulb suggests that short-term dynamics of excitatory synaptic transmission is correlated to stereotypical connectivity motifs. It was observed that neurons with short-term facilitating synapses form predominantly reciprocal pairwise connections, while neurons with short-term depressing synapses form unidirectional pairwise connections. The cause of these structural differences in synaptic microcircuits is unknown. We propose that these connectivity motifs emerge from the interactions between short-term synaptic dynamics (SD) and long-term spike-timing dependent plasticity (STDP). While the impact of STDP on SD was shown in vitro, the mutual interactions between STDP and SD in large networks are still the subject of intense research. We formulate a computational model by combining SD and STDP, which captures faithfully short- and long-term dependence on both spike times and frequency. As a proof of concept, we simulate recurrent networks of spiking neurons with random initial connection efficacies and where synapses are either all short-term facilitating or all depressing. For identical background inputs, and as a direct consequence of internally generated activity, we find that networks with depressing synapses evolve unidirectional connectivity motifs, while networks with facilitating synapses evolve reciprocal connectivity motifs. This holds for heterogeneous networks including both facilitating and depressing synapses. Our study highlights the conditions under which SD-STDP might the correlation between facilitation and reciprocal connectivity motifs, as well as between depression and unidirectional motifs. We further suggest experiments for the validation of the proposed mechanism.