Amygdala depotentiation and fear extinction

Kim, Jeong-Yeon; Lee, Sung‐Hee; Park, Kyungjoon; Hong, Ingie; Song, Beomjong; Son, Gi Hoon; Park, Heewoo; Kim, Woon Ryoung; Park, Eunjin; Choe, Han Kyoung; Kim, Hyun; Lee, Chang‐Joong; Sun, Woong; Kim, Kyungjin; Shin, Ki Soon; Choi, Sukwoo

doi:10.1073/pnas.0710548105

Cited by 234 publications

(304 citation statements)

References 51 publications

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“…First, our data suggest a conversion of some mature contacts to immature or silent type synapses, promoting circuit rewiring that facilitates learning by providing increased synaptic sites for information storage. As a consequence, the rapid effects of estrogens via ERα may cause weakening of some previously established memories (28) and facilitate their overwriting or updating if activated by a stimulus or a learning event (29). Second, the decrease in AMPA responses we observe can lead to an increase in the signal-to-noise ratio that improves learning and memory.…”

Section: Discussionmentioning

confidence: 80%

Rapid increases in immature synapses parallel estrogen-induced hippocampal learning enhancements

Phan

Suschkov

Molinaro

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

129

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Dramatic increases in hippocampal spine synapse density are known to occur within minutes of estrogen exposure. Until now, it has been assumed that enhanced spinogenesis increased excitatory input received by the CA1 pyramidal neurons, but how this facilitated learning and memory was unclear. Delivery of 17β-estradiol or an estrogen receptor (ER)-α (but not ER-β) agonist into the dorsal hippocampus rapidly improved general discrimination learning in female mice. The same treatments increased CA1 dendritic spines in hippocampal sections over a time course consistent with the learning acquisition phase. Surprisingly, estrogen-activated spinogenesis was associated with a decrease in CA1 hippocampal excitatory input, rapidly and transiently reducing CA1 AMPA activity via a mechanism likely reflecting AMPA receptor internalization and creation of silent or immature synapses. We propose that estrogens promote hippocampally mediated learning via a mechanism resembling some of the broad features of normal development, an initial overproduction of functionally immature connections being subsequently "pruned" by experience.immature synapse | short-term memory | structural plasticity | synaptic plasticity | signal-to-noise ratio E stradiol rapidly and dramatically increases hippocampal dendritic spine and synapse density within minutes of application (1-4). There is a strong correlative association between estrogeninduced spinogenesis and improvements in cognition (5); however, the relationship of these structural changes to estrogen-induced alterations in hippocampal function is unclear. Our laboratory recently reported that the density of hippocampal CA1 pyramidal dendritic spines increases very rapidly after systemic treatment with 17β-estradiol or estrogen receptor (ER) -selective agonists in ovariectomized female mice, changes that are paralleled by learning enhancements (2, 3). Estrogen-induced rapid structural changes are substantial, increasing spine density by 30-50% within 15-40 min of hormone application (1-3, 6). As a result, adult rodents can experience the addition of thousands of CA1 synapses within a span of minutes after exposure to estradiol. These effects of estrogens reproduce the changes occurring during the 4-d estrous cycle of female rodents, which include the induction of CA1 spines (7).How these processes contribute to the behavioral changes observed after estradiol treatment is not understood. Estradiol enhances excitatory neurotransmission throughout the hippocampus (8-10), and activates BDNF signaling in the mossy fiber system (11). Dendritic spines turn over more rapidly in the hippocampus than in the neocortex (12), particularly in the case of estradiol-induced spines (13). Such rapid, transient, and apparently indiscriminate increases in excitatory synapse formation would seem, at first sight, to be more likely to interfere with preexisting brain circuits and impair normal information processing than to enhance cognitive function.How then, does enhancement of spine formation lead to improved ...

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Section: Discussionmentioning

confidence: 80%

Rapid increases in immature synapses parallel estrogen-induced hippocampal learning enhancements

Phan

Suschkov

Molinaro

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

129

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“…Interestingly, all three mechanisms seem to interact in endocannabinoid-mediated LTD in the hippocampus, with calcineurin apparently integrating the postsynaptic activation signal provided by LVGCCs and the presynaptic signal mediated by CB1 receptors (Heifets et al 2008). Calcineurin has also been shown to activate downstream targets that can mediate synaptic depression phenomena, such as AMPA receptor endocytosis (Beattie et al 2000;Kim et al 2007) and protein degradation through the ubiquitin-proteasome system (Fukushima et al 2014). Notably, both of these …”

Section: Discussionmentioning

confidence: 99%

“…targets have also been implicated in memory destabilization during reconsolidation Hong et al 2013) and in extinction (Kim et al 2007;Dalton et al 2008;Lee et al 2008), suggesting that this memory labilization system might mediate both the labilization component of reconsolidation and the within-session component of memory extinction.…”

Section: Discussionmentioning

confidence: 99%

Calcineurin inhibition blocks within-, but not between-session fear extinction in mice

et al. 2015

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Memory extinction involves the formation of a new associative memory that inhibits a previously conditioned association. Nonetheless, it could also depend on weakening of the original memory trace if extinction is assumed to have multiple components. The phosphatase calcineurin (CaN) has been described as being involved in extinction but not in the initial consolidation of fear learning. With this in mind, we set to study whether CaN could have different roles in distinct components of extinction. Systemic treatment with the CaN inhibitors cyclosporin A (CsA) or FK-506, as well as i.c.v. administration of CsA, blocked within-session, but not between-session extinction or initial learning of contextual fear conditioning. Similar effects were found in multiple-session extinction of contextual fear conditioning and in auditory fear conditioning, indicating that CaN is involved in different types of short-term extinction. Meanwhile, inhibition of protein synthesis by cycloheximide (CHX) treatment did not affect within-session extinction, but disrupted fear acquisition and slightly impaired between-session extinction. Our results point to a dissociation of within-and between-session extinction of fear conditioning, with the former being more dependent on CaN activity and the latter on protein synthesis. Moreover, the modulation of within-session extinction did not affect between-session extinction, suggesting that these components are at least partially independent.

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“…Electrophysiological experiments were performed as described in a previous report (Kim et al, 2007b). Control mice and maternally stressed mice were anesthetized with halothane and killed.…”

Section: Methodsmentioning

confidence: 99%

“…While voltage clamped, a minor proportion (Ͻ5%) of recorded neurons exhibited spontaneous EPSCs with faster decay times and larger amplitude (Ͼ100 pA). As these are characteristic of inhibitory neurons, they were excluded from the analysis (Kim et al, 2007b). Extracellular field potentials were recorded by using a parylene-insulated microelectrode (573210; A-M Systems) in 400-m-thick slices.…”

Section: Methodsmentioning

confidence: 99%

Impairment of Fear Memory Consolidation in Maternally Stressed Male Mouse Offspring: Evidence for Nongenomic Glucocorticoid Action on the Amygdala

Lee¹,

Son²,

Chung³

et al. 2011

J. Neurosci.

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The environment in early life elicits profound effects on fetal brain development that can extend into adulthood. However, the longlasting impact of maternal stress on emotional learning remains largely unknown. Here, we focus on amygdala-related learning processes in maternally stressed mice. In these mice, fear memory consolidation and certain related signaling cascades were significantly impaired, though innate fear, fear memory acquisition, and synaptic NMDA receptor expression in the amygdala were unaltered. In accordance with these findings, maintenance of long-term potentiation (LTP) at amygdala synapses, but not its induction, was significantly impaired in the maternally stressed animals. Interestingly, amygdala glucocorticoid receptor expression was reduced in the maternally stressed mice, and administration of glucocorticoids (GCs) immediately after fear conditioning and LTP induction restored memory consolidation and LTP maintenance, respectively, suggesting that a weakening of GC signaling was responsible for the observed impairment. Furthermore, microinfusion of a membrane-impermeable form of GC (BSA-conjugated GC) into the amygdala mimicked the restorative effects of GC, indicating that a nongenomic activity of GC mediates the restorative effect. Together, these findings suggest that prenatal stress induces long-term dysregulation of nongenomic GC action in the amygdala of adult offspring, resulting in the impairment of fear memory consolidation. Since modulation of amygdala activity is known to alter the consolidation of emotionally influenced memories allocated in other brain regions, the nongenomic action of GC on the amygdala shown herein may also participate in the amygdaladependent modulation of memory consolidation.

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Amygdala depotentiation and fear extinction

Cited by 234 publications

References 51 publications

Rapid increases in immature synapses parallel estrogen-induced hippocampal learning enhancements

Rapid increases in immature synapses parallel estrogen-induced hippocampal learning enhancements

Calcineurin inhibition blocks within-, but not between-session fear extinction in mice

Impairment of Fear Memory Consolidation in Maternally Stressed Male Mouse Offspring: Evidence for Nongenomic Glucocorticoid Action on the Amygdala

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