Auditory fear memory is thought to be maintained by fear conditioning-induced potentiation of synaptic efficacy, which involves enhanced expression of surface AMPA receptor (AMPAR) at excitatory synapses in the lateral amygdala (LA). Depotentiation, reversal of conditioning-induced potentiation, has been proposed as a cellular mechanism for fear extinction; however, a direct link between depotentiation and extinction has not yet been tested. To address this issue, we applied both ex vivo and in vivo approaches to rats in which fear memory had been consolidated. A unique form of depotentiation reversed conditioning-induced potentiation at thalamic input synapses onto the LA (T-LA synapses) ex vivo. Extinction returned the enhanced T-LA synaptic efficacy observed in conditioned rats to baseline and occluded the depotentiation. Consistently, extinction reversed conditioning-induced enhancement of surface expression of AMPAR subunits in LA synaptosomal preparations. A GluR2-derived peptide that blocks regulated AMPAR endocytosis inhibited depotentiation, and microinjection of a cell-permeable form of the peptide into the LA attenuated extinction. Our results are consistent with the use of depotentiation to weaken potentiated synaptic inputs onto the LA during extinction and provide strong evidence that AMPAR removal at excitatory synapses in the LA underlies extinction.lateral amygdala ͉ fear conditioning ͉ AMPA receptor ͉ endocytosis T he cortical and thalamic input synapses onto the lateral amygdala (LA) (C-LA and T-LA synapses, respectively) carry auditory information from the auditory cortex and auditory thalamus onto the LA, respectively (1). Long-term potentiation (LTP; an in vitro model of memory) (2)-like changes in these pathways are thought to underlie both the encoding and consolidation of auditory fear memory (3-8). The results of a recent study suggest that long-term retention of conditioning-induced potentiation at excitatory synapses in the LA is a critical requirement for consolidated fear memory within the LA (7, 9). Also, LTP requiring the synaptic delivery of AMPA receptors (AMPARs) at excitatory synapses in the LA appears to be necessary for establishing consolidated fear memory (6,8,10). Conditioning-induced potentiation and auditory fear memory encoded in the LA have been shown to be consolidated within 24 h after fear conditioning (5, 7, 11). Moreover, auditory fear memory appears to be maintained in the LA across the adult lifetime of rats (12). Thus, consolidation of auditory fear memory encoded in the LA is rapid and localized, unlike hippocampus-dependent memory, which involves slow and distributed consolidation processes (13).In the present study, we tested the hypothesis that depotentiation of conditioning-induced potentiation at excitatory synapses in the LA underlies extinction of consolidated fear memory. Synaptic weights were monitored ex vivo by using whole-cell (or field potential) recordings in amygdala slices prepared from behaviortrained rats. Results Extinction of Consolidated ...
The circadian nature of mood and its dysfunction in affective disorders is well recognized, but the underlying molecular mechanisms are still unclear. Here, we show that the circadian nuclear receptor REV-ERBα, which is associated with bipolar disorder, impacts midbrain dopamine production and mood-related behavior in mice. Genetic deletion of the Rev-erbα gene or pharmacological inhibition of REV-ERBα activity in the ventral midbrain induced mania-like behavior in association with a central hyperdopaminergic state. Also, REV-ERBα repressed tyrosine hydroxylase (TH) gene transcription via competition with nuclear receptor-related 1 protein (NURR1), another nuclear receptor crucial for dopaminergic neuronal function, thereby driving circadian TH expression through a target-dependent antagonistic mechanism. In conclusion, we identified a molecular connection between the circadian timing system and mood regulation, suggesting that REV-ERBα could be targeting in the treatment of circadian rhythm-related affective disorders.
Glucocorticoid (GC) is an adrenal steroid with diverse physiological effects. It undergoes a robust daily oscillation, which has been thought to be driven by the master circadian clock in the suprachiasmatic nucleus of the hypothalamus via the hypothalamuspituitary-adrenal axis. However, we show that the adrenal gland has its own clock and that the peripheral clockwork is tightly linked to steroidogenesis by the steroidogenic acute regulatory protein.Examination of mice with adrenal-specific knockdown of the canonical clock protein BMAL1 reveals that the adrenal clock machinery is required for circadian GC production. Furthermore, behavioral rhythmicity is drastically affected in these animals, together with altered expression of Period1, but not Period2, in several peripheral organs. We conclude that the adrenal peripheral clock plays an essential role in harmonizing the mammalian circadian timing system by generating a robust circadian GC rhythm.adrenal gland ͉ steroidogenic acute regulatory protein ͉ BMAL1
The novel neuropeptide spexin (SPX) was discovered using bioinformatics. The function of this peptide is currently under investigation. Here, we identified SPX along with a second SPX gene (SPX2) in vertebrate genomes. Syntenic analysis and relocating SPXs and their neighbor genes on reconstructed vertebrate ancestral chromosomes revealed that SPXs reside in the near vicinity of the kisspeptin (KISS) and galanin (GAL) family genes on the chromosomes. Alignment of mature peptide sequences showed some extent of sequence similarity among the 3 peptide groups. Gene structure analysis indicated that SPX is more closely related to GAL than KISS. These results suggest that the SPX, GAL, and KISS genes arose through local duplications before 2 rounds (2R) of whole-genome duplication. Receptors of KISS and GAL (GAL receptor [GALR]) are phylogenetically closest among rhodopsin-like G protein-coupled receptors, and synteny revealed the presence of 3 distinct receptor families KISS receptor, GALR1, and GALR2/3 before 2R. A ligand-receptor interaction study showed that SPXs activate human, Xenopus, and zebrafish GALR2/3 family receptors but not GALR1, suggesting that SPXs are natural ligands for GALR2/3. Particularly, SPXs exhibited much higher potency toward GALR3 than GAL. Together, these results identify the coevolution of SPX/GAL/KISS ligand genes with their receptor genes. This study demonstrates the advantage of evolutionary genomics to explore the evolutionary relationship of a peptide gene family that arose before 2R by local duplications.
CLOCK and BMAL1 are bHLH-PAS-containing transcription factors that bind to E-box elements and are indispensable for expression of core circadian clock components such as the Per and Cry genes. A key step in expression is the heterodimerization of CLOCK and BMAL1 and their accumulation in the nucleus with an approximately 24-h periodicity. We show here that nucleocytoplasmic shuttling of BMAL1 is essential for transactivation and for degradation of the CLOCK/BMAL1 heterodimer. Using serial deletions and point mutants, we identified a functional nuclear localization signal and Crm1-dependent nuclear export signals in BMAL1. Transient-transfection experiments revealed that heterodimerization of CLOCK and BMAL1 accelerates their turnover, as well as E-box-dependent clock gene transcription. Moreover, in embryonic mouse fibroblasts, robust transcription of Per2 is tightly associated with massive degradation of the CLOCK/BMAL1 heterodimer. CRY proteins suppressed this process during the transcription-negative phase and led to nuclear accumulation of the CLOCK/BMAL1 heterodimer. Thus, these findings suggest that the decrease of BMAL1 abundance during the circadian cycle reflects robust transcriptional activation of clock genes rather than inhibition of BMAL1 synthesis.Almost all organisms from bacteria to mammals have developed circadian physiology and behavior to adapt to the environmental changes created by the rotation of our planet. Such daily rhythms are controlled by genetically determined and self-sustaining circadian clocks that are composed of networks of transcription-translation feedback loops involving sets of clock genes (15,30,37). In mammals, a network of feedback loops functions robustly not only in the master circadian pacemaker, the suprachiasmatic nucleus (SCN) of the hypothalamus (26), but also in most tissues (including liver, heart, lung, and muscle) and even in immortalized cell lines (1, 50, 51). These widely dispersed circadian systems are primarily synchronized by the SCN to coordinate circadian timing in vivo (29,36).One of the main questions in clock biology is how the timekeeping system is controlled at the molecular level. Intensive studies in the mouse using genetic and molecular approaches have largely clarified the structure of the central feedback loop (3,30). Two bHLH-PAS-containing transcription factors, CLOCK and BMAL1, form heterodimers that bind to E-box enhancer elements in the promoters of target genes driving the transcription of three period genes (Per1, Per2, and Per3) and two cryptochrome genes (Cry1 and Cry2) (11,14,17,18). After the PER and CRY proteins have been translated in the cytoplasm, they form heterocomplexes that translocate into the nucleus and inhibit their own transcription. CRY plays a crucial role in this negative feedback process by interacting directly with the CLOCK/BMAL1 heterodimers (12,22).Analysis of Bmal1 defective mice has revealed the indispensable role of BMAL1 as the mainspring of the molecular clockwork; thus, targeted disruption of Bmal1 results...
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