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Co-dependent excitatory and inhibitory plasticity accounts for quick, stable and long-lasting memories in biological networks

Everton J. Agnes, Tim P. Vogels

2024Nature Neuroscience58 citationsDOIOpen Access PDF

Abstract

The brain's functionality is developed and maintained through synaptic plasticity. As synapses undergo plasticity, they also affect each other. The nature of such 'co-dependency' is difficult to disentangle experimentally, because multiple synapses must be monitored simultaneously. To help understand the experimentally observed phenomena, we introduce a framework that formalizes synaptic co-dependency between different connection types. The resulting model explains how inhibition can gate excitatory plasticity while neighboring excitatory-excitatory interactions determine the strength of long-term potentiation. Furthermore, we show how the interplay between excitatory and inhibitory synapses can account for the quick rise and long-term stability of a variety of synaptic weight profiles, such as orientation tuning and dendritic clustering of co-active synapses. In recurrent neuronal networks, co-dependent plasticity produces rich and stable motor cortex-like dynamics with high input sensitivity. Our results suggest an essential role for the neighborly synaptic interaction during learning, connecting micro-level physiology with network-wide phenomena.

Topics & Concepts

NeuroscienceInhibitory postsynaptic potentialExcitatory postsynaptic potentialNeuroscientistPsychologyPlasticityNeuroplasticityBiologyCentral nervous systemPhysicsOligodendrocyteMyelinThermodynamicsAdvanced Memory and Neural ComputingPhotoreceptor and optogenetics researchNeuroscience and Neuropharmacology Research