TY - JOUR
T1 - Conditional knockout of MET receptor tyrosine kinase in cortical excitatory neurons leads to enhanced learning and memory in young adult mice but early cognitive decline in older adult mice
AU - Xia, Baomei
AU - Wei, Jing
AU - Ma, Xiaokuang
AU - Nehme, Antoine
AU - Liong, Katerina
AU - Cui, Yuehua
AU - Chen, Chang
AU - Gallitano, Amelia
AU - Ferguson, Deveroux
AU - Qiu, Shenfeng
N1 - Funding Information: This study was supported by NIH/ NIMH grant R01MH111619 (S.Q.), and institution startup fund from The University of Arizona (S.Q.). We thank Dr. Pat Levitt for his comments on this work. Funding Information: This study was supported by NIH/NIMH grant R01MH111619 (S.Q.), and institution startup fund from The University of Arizona (S.Q.). We thank Dr. Pat Levitt for his comments on this work. Publisher Copyright: © 2021 Elsevier Inc.
PY - 2021/3
Y1 - 2021/3
N2 - Human genetic studies established MET gene as a risk factor for autism spectrum disorders. We have previously shown that signaling mediated by MET receptor tyrosine kinase, expressed in early postnatal developing forebrain circuits, controls glutamatergic neuron morphological development, synapse maturation, and cortical critical period plasticity. Here we investigated how MET signaling affects synaptic plasticity, learning and memory behavior, and whether these effects are age-dependent. We found that in young adult (postnatal 2–3 months) Met conditional knockout (Metfx/fx:emx1cre, cKO) mice, the hippocampus exhibits elevated plasticity, measured by increased magnitude of long-term potentiation (LTP) and depression (LTD) in hippocampal slices. Surprisingly, in older adult cKO mice (10–12 months), LTP and LTD magnitudes were diminished. We further conducted a battery of behavioral tests to assess learning and memory function in cKO mice and littermate controls. Consistent with age-dependent LTP/LTD findings, we observed enhanced spatial memory learning in 2–3 months old young adult mice, assessed by hippocampus-dependent Morris water maze test, but impaired spatial learning in 10–12 months mice. Contextual and cued learning were further assessed using a Pavlovian fear conditioning test, which also revealed enhanced associative fear acquisition and extinction in young adult mice, but impaired fear learning in older adult mice. Lastly, young cKO mice also exhibited enhanced motor learning. Our results suggest that a shift in the window of synaptic plasticity and an age-dependent early cognitive decline may be novel circuit pathophysiology for a well-established autism genetic risk factor.
AB - Human genetic studies established MET gene as a risk factor for autism spectrum disorders. We have previously shown that signaling mediated by MET receptor tyrosine kinase, expressed in early postnatal developing forebrain circuits, controls glutamatergic neuron morphological development, synapse maturation, and cortical critical period plasticity. Here we investigated how MET signaling affects synaptic plasticity, learning and memory behavior, and whether these effects are age-dependent. We found that in young adult (postnatal 2–3 months) Met conditional knockout (Metfx/fx:emx1cre, cKO) mice, the hippocampus exhibits elevated plasticity, measured by increased magnitude of long-term potentiation (LTP) and depression (LTD) in hippocampal slices. Surprisingly, in older adult cKO mice (10–12 months), LTP and LTD magnitudes were diminished. We further conducted a battery of behavioral tests to assess learning and memory function in cKO mice and littermate controls. Consistent with age-dependent LTP/LTD findings, we observed enhanced spatial memory learning in 2–3 months old young adult mice, assessed by hippocampus-dependent Morris water maze test, but impaired spatial learning in 10–12 months mice. Contextual and cued learning were further assessed using a Pavlovian fear conditioning test, which also revealed enhanced associative fear acquisition and extinction in young adult mice, but impaired fear learning in older adult mice. Lastly, young cKO mice also exhibited enhanced motor learning. Our results suggest that a shift in the window of synaptic plasticity and an age-dependent early cognitive decline may be novel circuit pathophysiology for a well-established autism genetic risk factor.
KW - Autism
KW - Cortical circuits
KW - Electrophysiology
KW - Learning and memory
KW - Neurodevelopmental disorders
KW - Synaptic plasticity
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U2 - 10.1016/j.nlm.2021.107397
DO - 10.1016/j.nlm.2021.107397
M3 - Article
C2 - 33524570
SN - 1074-7427
VL - 179
JO - Neurobiology of Learning and Memory
JF - Neurobiology of Learning and Memory
M1 - 107397
ER -