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Aberrant slow waves in the hippocampus during activation in mice with low cholinergic tone

The effects of acetylcholine on cortical activation were studied in wild‐type (WT) mice, compared to knockout (KO) mice depleted of the vesicular acetylcholine transporter (VAChT) gene in the basal forebrain, and knockdown (KD) mice with heterogeneous depletion of VAChT gene in the brain. Cortical a...

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Published in:Hippocampus 2021-11, Vol.31 (11), p.1233-1253
Main Authors: Leung, L. Stan, Chu, Liangwei
Format: Article
Language:English
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Summary:The effects of acetylcholine on cortical activation were studied in wild‐type (WT) mice, compared to knockout (KO) mice depleted of the vesicular acetylcholine transporter (VAChT) gene in the basal forebrain, and knockdown (KD) mice with heterogeneous depletion of VAChT gene in the brain. Cortical activation was assessed by comparing power spectra of local field potentials (LFPs) during activated states of rapid‐eye‐movement sleep (REM) or walk (WLK), with those during non‐activated states of slow‐wave sleep (SWS) or awake‐immobility (IMM). Activation‐induced suppression of delta (1–4 Hz) and beta (13–30 Hz) power in the hippocampus, and delta power in frontal cortex, were reduced in KO and KD mice compared to WT mice. Mean theta frequency was higher in KD than KO mice during WLK and REM, but not different between WT and KO mice. Peak theta (4–12 Hz) and integrated gamma (30–150 Hz) power were not significantly different among mouse groups. However, theta‐peak‐frequency selected gamma2 (62–100 Hz) power was lower in KO than WT or KD mice during WLK, and theta‐peak‐frequency selected theta power during REM decreased faster with high theta frequency in KO than WT/ KD mice. Theta power increase during REM compared to WLK was lower in KO and KD mice compared to WT mice. Theta–gamma cross‐frequency coherence, a measure of synchronization of gamma with theta phase, was not different among mouse groups. However, during REM, SWS, and IMM, delta‐gamma coherence was significantly higher and proximal–distal delta coherence in CA1 was lower in KO than WT/KD mice. We conclude that a deficiency in basal forebrain acetylcholine release not only enhances slow waves and suppresses theta‐associated gamma waves during activation, but also increases delta‐gamma cross‐frequency coherence during nonactivated states, with a possible effect of disrupting cognitive processing during any brain state.
ISSN:1050-9631
1098-1063
DOI:10.1002/hipo.23387