Abstract

We summarize here several studies performed in our laboratory, mainly using serial block-face scanning electron microscopy (SBEM), to assess how sleep, spontaneous waking and short sleep deprivation affect the size and number of synapses in the cerebral cortex and hippocampus. With SBEM, we reconstructed thousands of cortical and hippocampal excitatory, axospinous synapses and compared the distribution of their size after several hours of sleep relative to several hours of waking. Because stronger synapses are on average also bigger, the goal was to test a prediction of the synaptic homeostasis hypothesis, according to which overall synaptic strength increases during waking, owing to ongoing learning, and needs to be renormalized during sleep, to avoid saturation and to benefit memory consolidation and integration. Consistent with this hypothesis, we found that the size of the axon–spine interface (ASI), a morphological measure of synaptic strength, was on average smaller after sleep, but with interesting differences between primary cortex and the CA1 region of the hippocampus. In two-week-old mouse pups, the decline in ASI size after sleep was larger, and affected more cortical synapses, compared with one-month-old adolescent mice, suggesting that synaptic renormalization during sleep may be especially important during early development. This work is still in progress and other brain areas need to be tested after sleep, acute sleep loss and chronic sleep restriction. Still, the current results show that a few hours of sleep or waking lead to significant changes in synaptic morphology that can be linked to changes in synaptic efficacy.This article is part of the Theo Murphy meeting issue ‘Memory reactivation: replaying events past, present and future’.

Highlights

  • In this paper, we discuss the results of several anatomical studies conducted in our laboratory over the last several years, with the goal of characterizing the effects of sleep and waking on synaptic morphology

  • We focus on recent experiments using serial electron microscopy, which tested the prediction of the synaptic homeostasis hypothesis that synapses should get stronger, and bigger, after waking, and weaker, and smaller, after sleep

  • Ultrastructural studies in the cerebral cortex, cerebellum and hippocampus have found that the number of pre-synaptic vesicles, the size of the active zone, the post-synaptic density (PSD) area, the spine head volume and the area of contact between pre-synapse and post-synapse are strongly positively correlated [5,6,7,8,9,10]

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Summary

Introduction

We discuss the results of several anatomical studies conducted in our laboratory over the last several years, with the goal of characterizing the effects of sleep and waking on synaptic morphology. We start by providing a short overview of the morphological features of excitatory synapses and the evidence showing that there is a strong positive correlation between functional and structural synaptic measures, that is, stronger synapses are bigger. We review experiments in mice that assessed changes in spine number after sleep and waking using repeated two-photon imaging. We focus on recent experiments using serial electron microscopy, which tested the prediction of the synaptic homeostasis hypothesis that synapses should get stronger, and bigger, after waking, and weaker, and smaller, after sleep. All studies used YFP-H mice whose sleep/waking pattern and response to sleep deprivation were characterized in our laboratory and are briefly described here

Spines and synaptic elements
Characterization of sleep in YFP-H mice
Findings
Conclusion
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