Dendritic spines are the postsynaptic sites of most excitatory synapses in the brain and are highly enriched in polymerized F-actin, which drives the formation and maintenance of mature dendritic spines and synapses. We propose that suppressing the activity of the actinsevering protein cofilin plays an important role in the stabilization of mature dendritic spines, and is accomplished through an EphB receptor-focal adhesion kinase (FAK) pathway. Our studies revealed that Cre-mediated knock-out of loxP-flanked fak prompted the reversion of mature dendritic spines to an immature filopodial-like phenotype in primary hippocampal cultures. The effects of FAK depletion on dendritic spine number, length, and morphology were rescued by the overexpression of the constitutively active FAK Y397E , but not FAK Y397F , indicating the significance of FAK activation by phosphorylation on tyrosine 397. Our studies demonstrate that FAK acts downstream of EphB receptors in hippocampal neurons and EphB2-FAK signaling controls the stability of mature dendritic spines by promoting cofilin phosphorylation, thereby inhibiting cofilin activity. While constitutively active nonphosphorylatable cofilin S3A induced an immature spine profile, phosphomimetic cofilin S3D restored mature spine morphology in neurons with disrupted EphB activity or lacking FAK. Further, we found that EphB-mediated regulation of cofilin activity at least partially depends on the activation of Rho-associated kinase (ROCK) and LIMK-1. These findings indicate that EphB2-mediated dendritic spine stabilization relies, in part, on the ability of FAK to activate the RhoA-ROCK-LIMK-1 pathway, which functions to suppress cofilin activity and inhibit cofilin-mediated dendritic spine remodeling.
Dendritic spines are dynamic, actin-rich structures that form the postsynaptic sites of most excitatory synapses in the brain. The F-actin severing protein cofilin has been implicated in the remodeling of dendritic spines and synapses under normal and pathological conditions, by yet unknown mechanisms. Here we report that β-arrestin-2 plays an important role in NMDA-induced remodeling of dendritic spines and synapses via translocation of active cofilin to dendritic spines. NMDAR activation triggers cofilin activation through calcineurin and phosphatidylinositol 3-kinase (PI3K)-mediated dephosphorylation and promotes cofilin translocation to dendritic spines that is mediated by β-arrestin-2. Hippocampal neurons lacking β-arrestin-2 develop mature spines that fail to remodel in response to NMDA. β-Arrestin-2-deficient mice exhibit normal hippocampal long-term potentiation, but significantly impaired NMDA-dependent long-term depression and spatial learning deficits. Moreover, β-arrestin-2-deficient hippocampal neurons are resistant to Aβ-induced dendritic spine loss. Our studies demonstrate unique functions of β-arrestin-2 in NMDAR-mediated dendritic spine and synapse plasticity through spatial control over cofilin activation.T he postsynaptic sites of the majority of excitatory synapses in the central nervous system are found on dynamic protrusions called dendritic spines (1-5). Dendritic spines are filamentous actin (F-actin)-rich structures, which are regulated by actinbinding proteins that sever, bundle, polymerize, or cap F-actin filaments (6). Structural plasticity of dendritic spines has been linked to synaptic plasticity (7,8) and is thought to underlie learning and memory processes (9), whereas defects in dendritic spine morphology are associated with certain neurological disorders (10, 11). Cofilin is an F-actin-severing protein that increases the turnover of F-actin by severing the filaments and creating new barbed ends for F-actin growth (12)(13)(14)(15)(16)(17). Several studies suggest that cofilin activation by dephosphorylation may trigger dendritic spine remodeling in neurons, resulting in the destabilization and transformation of mature mushroom-shaped spines with large heads into immature thin spines in hippocampal neurons (18,19). Moreover, cofilin-mediated plasticity was reported to underlie both dendritic spine enlargement and stabilization induced by long-term potentiation (LTP) (20), as well as spine shrinkage and elimination associated with long-term depression (LTD) (21). Recent studies showing an increased number of mature spines with large heads in cofilin-deficient neurons support the role of cofilin in dendritic spine plasticity (22). Excessive cofilin activity has been implicated in stress-induced cofilin-actin rods that are found in the brain with several neurological disorders associated with dendritic spine loss (23,24). Conversely, the suppression of endogenous cofilin activation by phospho-mimetic cofilin S3D has been reported to protect neurons against amyloid-beta (Aβ)-mediated ...
Tryptophan hydroxylase-2 (TPH2) is the rate-limiting enzyme in raphe serotonin biosynthesis, and polymorphisms of TPH2 are implicated in vulnerability to psychiatric disorders. Dynamic transcription regulation of TPH2 may underlie differences in vulnerability. We identified a transcription element in the TPH2 promoter that resembles the binding motif for RE-1 silencer of transcription (REST; also known as NRSF) transcription factor. REST limits tissue expression of non-neuronal genes through a canonical 21-bp motif called the NRSE (neuron-restrictive silencing element). The NRSE in TPH2 is a novel bipartite variant interrupted by a 6-base insertion. We confirmed that this bipartite NRSE permits transcriptional repression by REST identical to canonical NRSE in rat C6-glioma cells. Synthetic permutations of the motif revealed considerable flexibility in the juxtaposition of the two halves of bipartite NRSE. Computational analysis revealed many bipartite NRSE variants conserved between mouse and human genomes. A subgroup of these was found to bind REST by chromatin immunoprecipitation. Messenger RNAs for TPH2 and potassium channel H6, another gene with a bipartite NRSE, were up-regulated by dominant-negative REST in C6-glioma cells. These findings, which indicate that TPH2 expression is part of the developmental program regulated by REST and suggest that many previously unrecognized genes may be regulated by REST through the novel motif, have implications for the mechanism of REST action.Serotonin levels are regulated by the rate-limiting enzyme tryptophan hydroxylase, of which a neuronal isoform (NCBI Entrez Gene ID: TPH2) 3 was recently identified (1). TPH2 gene expression in the brain is restricted to raphe neurons, and TPH2 is likely the gene coding for the majority of tryptophan hydroxylase in these cells (1, 2). Serotonin modulates a variety of complex behaviors (3), and its signaling is implicated in the mechanism for a subset of antidepressants (4), but its precise role in mood regulation is unclear. A number of manipulations, including restriction of the essential dietary precursor tryptophan (5), stimulant drugs of abuse (6), or adverse developmental experiences (7), result in low brain serotonin levels and may underlie associated depression or anxiety phenotypes. Functional variants of TPH2 in mice are associated with decreased brain serotonin levels (8), and a TPH2 polymorphism in humans arguably (9) confers vulnerability to major depression (10). Associations with TPH2 polymorphisms are also reported for suicide (11), obsessivecompulsive disorder (12), and attention deficit disorder (13)(14)(15).In contrast to the growing number of genetic association studies, little is known about the regulation of TPH2 expression. Limited studies suggest that TPH2 mRNA levels are decreased following stress corticosteroids (16), unchanged (16) or increased by ovarian steroids (17), and increased by hypotensive stress (18) and one recent report suggests that POU3F2 may regulate TPH2 through a functional single-nucleoti...
Odor detection involves hundreds of olfactory receptors from diverse families, making modeling of hedonic valence of an odorant difficult, even in Drosophila melanogaster where most receptors have been deorphanised. We demonstrate that a broadly tuned heteromeric receptor that detects CO (Gr21a, Gr63a) and other odorants is a key determinant of valence along with a few members of the Odorant receptor family in a T-maze, but not in a trap assay. Gr21a and Gr63a have atypically high amino acid conservation in Dipteran insects, and they use both inhibition and activation to convey positive or negative valence for numerous odorants. Inhibitors elicit a robust Gr63a-dependent attraction, while activators, strong aversion. The attractiveness of inhibitory odorants increases with increasing background CO levels, providing a mechanism for behavior modulation in odor blends. In mosquitoes, valence is switched and activation of the orthologous receptor conveys attraction. Reverse chemical ecology enables the identification of inhibitory odorants to reduce attraction of mosquitoes to skin.
Dendritic spines are actin-rich structures that accommodate the postsynaptic sites of most excitatory synapses in the brain. Although dendritic spines form and mature as synaptic connections develop, they remain plastic even in the adult brain, where they can rapidly grow, change, or collapse in response to normal physiological changes in synaptic activity that underlie learning and memory. Pathological stimuli can adversely affect dendritic spine shape and number, and this is seen in neurodegenerative disorders and some forms of mental retardation and autism as well. Many of the molecular signals that control these changes in dendritic spines act through the regulation of filamentous actin (F-actin), some through direct interaction with actin, and others via downstream effectors. For example, cortactin, cofilin, and gelsolin are actin-binding proteins that directly regulate actin dynamics in dendritic spines. Activities of these proteins are precisely regulated by intracellular signaling events that control their phosphorylation state and localization. In this review, we discuss how actin-regulating proteins maintain the balance between F-actin assembly and disassembly that is needed to stabilize mature dendritic spines, and how changes in their activities may lead to rapid remodeling of dendritic spines.
Dendritic spines are actin-rich structures that accommodate the postsynaptic sites of most excitatory synapses in the brain. Although dendritic spines form and mature as synaptic connections develop, they remain plastic even in the adult brain, where they can rapidly grow, change, or collapse in response to normal physiological changes in synaptic activity that underlie learning and memory. Pathological stimuli can adversely affect dendritic spine shape and number, and this is seen in neurodegenerative disorders and some forms of mental retardation and autism as well. Many of the molecular signals that control these changes in dendritic spines act through the regulation of filamentous actin (F-actin), some through direct interaction with actin, and others via downstream effectors. For example, cortactin, cofilin, and gelsolin are actin-binding proteins that directly regulate actin dynamics in dendritic spines. Activities of these proteins are precisely regulated by intracellular signaling events that control their phosphorylation state and localization. In this review, we discuss how actin-regulating proteins maintain the balance between F-actin assembly and disassembly that is needed to stabilize mature dendritic spines, and how changes in their activities may lead to rapid remodeling of dendritic spines.
Ethologically relevant chemical senses and behavioral habits are likely to coadapt in response to selection. As olfaction is involved in intrinsically motivated behaviors in mice, we hypothesized that selective breeding for a voluntary behavior would enable us to identify novel roles of the chemosensory system. Voluntary wheel running (VWR) is an intrinsically motivated and naturally rewarding behavior, and even wild mice run on a wheel placed in nature. We have established 4 independent, artificially evolved mouse lines by selectively breeding individuals showing high VWR activity (High Runners; HRs), together with 4 non-selected Control lines, over 88 generations. We found that several sensory receptors in specific receptor clusters were differentially expressed between the vomeronasal organ (VNO) of HRs and Controls. Moreover, one of those clusters contains multiple single-nucleotide polymorphism loci for which the allele frequencies were significantly divergent between the HR and Control lines, i.e., loci that were affected by the selective breeding protocol. These results indicate that the VNO has become genetically differentiated between HR and Control lines during the selective breeding process. Although the role of the vomeronasal chemosensory receptors in VWR activity remains to be determined, the current results suggest that these vomeronasal chemosensory receptors are important quantitative trait loci for voluntary exercise in mice. We propose that olfaction may play an important role in motivation for voluntary exercise in mammals.
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