Serotonin mediates CA1 spine density but is not crucial for ovarian steroid regulation of synaptic plasticity in the adult rat dorsal hippocampus

The activity of the serotonin (5-hydroxytryptamine, 5-HT) system is sensitive to estradiol and progesterone. During the ovarian cycle, dendritic spines on CA1 pyramidal neurons of the dorsal hippocampus are increased by estradiol and later decreased by progesterone. We sought to determine whether 5-HT is involved in maintaining CA1 spine density and/or in steroid regulation of synaptic plasticity in dorsal hippocampus. Ovariectomized rats were treated (sc) over 10 days with the tryptophan hydroxylase inhibitor parachlorophenylalanine (pCPA) to deplete 5-HT, followed by estradiol benzoate on days 10 and 11. A subset of animals received progesterone on day 12. The day after the last treatment, rats were perfused and brains were processed for Golgi impregnation. Separate groups were processed for radioimmunocytochemistry (RICC) for the spine-associated protein, spinophilin, or high-performance liquid chromatography (HPLC) for monoamine analysis. Golgi and RICC data indicate that CA1 apical spine density was significantly decreased by pCPA (17-20%). Estradiol increased spine density in both saline- and pCPA-treated rats compared to respective controls (30%); however, pCPA animals maintained significantly fewer spines. No differences in spine densities were observed between saline- and pCPA-treated rats given estradiol and progesterone. Depletion of 5-HT by pCPA was confirmed in the CA1 (-90%) and dorsal raphe (-80%) by HPLC analysis. While 5-HT depletion was associated with a 57% decrease in CA1 norepinephrine (NE), there was no difference in dorsal raphe NE. Thus, whereas 5-HT is involved in maintaining spine density in the adult female rat CA1, it is not crucial for steroid-mediated plasticity. 5-HT-regulated spines/synapses may represent distinct populations from those modulated by estradiol and progesterone in dorsal hippocampus.     

Estradiol rapidly increases GluA2‐mushroom spines and decreases GluA2‐filopodia spines in hippocampus CA1

Hippocampal dendritic spine density rapidly increases following estradiol (E₂) treatment, but the types of spines and trafficking of synaptic markers have received little investigation. We assessed rapid effects of E₂ over time on the density of four spine types (stubby, filopodial, long thin, and mushroom) and trafficking of AMPA receptor subunit GluA2 and PSD95 on tertiary, apical dendrites in CA1. Castrated male rats received 20 μg kg^?1 of E₂ or vehicle and were sacrificed 30 or 120 min later. Images of Golgi‐Cox impregnated and PSD95/GluA2 stained dendrites were captured under the confocal microscope and quantified with IMARIS‐XT. Stubby and filopodial spine densities did not change following treatment. Long‐thin spines significantly decreased at 30 min while mushroom spines significantly increased at 120 min. GluA2, PSD95, and GluA2/PSD95 colocalization levels in stubby or long thin spines did not change, but filopodial spines had significantly reduced GluA2 levels at 30 min. Mushroom spines showed significantly increased levels for GluA2, PSD95 and GluA2/PSD95 colocalization at 120 min. Because GluA2 is important for memory consolidation, current results present novel data suggesting that trafficking of GluA2 to mushroom spines provides one mechanism contributing to estradiol's ability to enhance learning and memory by the PI3 signaling pathway.     

Attenuation of dendritic spine density in the perirhinal cortex following 17β‐Estradiol replacement in the rat

Intraperirhinal cortex infusion of 17‐β estradiol (E2) impairs object‐recognition memory. However, it is not currently known whether this hormone modulates synaptic plasticity in this structure. Most excitatory synapses in the central nervous system are located on dendritic spines, and elevated E2 levels influence the density of these spines in several brain areas. The goal of the present study was to determine whether differences in dendritic spine density in the perirhinal cortex are observed following high E2 replacement in ovariectomized rats. The density of total spines, and mushroom‐shaped (i.e. mature) spines were compared between a high E2 replacement (10 µg/kg/day, s.c.) and a no replacement condition. The perirhinal cortex is subdivided into Broadmann's area 35 and 36 and so group comparisons were made within each sub‐region separately. High E2 replacement resulted in lower density of mushroom‐shaped spines in area 35 relative to no replacement. There was no effect of high E2 replacement on dendritic spine density in area 36. These findings are consistent with the idea that higher E2 levels reduce dendritic spine density in area 35, which may result from spine shrinkage, or reduced synapse formation. This study provides preliminary evidence for a mechanism through which E2 may impair object‐recognition memory. © 2015 Wiley Periodicals, Inc.     

Developmental dynamics of Purkinje cells and dendritic spines in rat cerebellar cortex

Quantitative morphological changes of the developing Purkinje cells were studied from 6 to 90 postnatal (PN) days in the IVth lobule of vermis in the cerebellum of rats. The soma size (mean diameter) of Purkinje cells increased rapidly between 6 PN (on average 10 μm) and 18 PN (about 17 μm) days; it did not change between 18 and 25 PN days, but increased moderately again between 25 and 48 PN days (22–23 μm) and stabilized on the same value. In contrast, the number of Purkinje cells/100 μm (the “linear density”) decreased rapidly from 6 to 18 PN days. The molecular layer area belonging to 1 Purkinje cell increased rapidly from 6 to 25 PN days (from about 370 to 6,200 μm²) and less rapidly between PN days 30 to 48 (up to 9,300 μm²), followed by a moderate decrease at PN day 90 (about 6,600 μm²). The volume belonging to 1 Purkinje cell dendritic arbor was about 5,500 μm³ at PN day 6,93,000 μm³ at PN day 25, and 100,000 μm³ at PN day 90. The numerical density of dendritic spines in the molecular layer showed a biphasic curve: a rapid increase from PN days 6 to 21 followed by a significant but short decrease at PN day 25, moderate rise from PN days 25 to 48, and a subsequent decline between PN days 48 and 90. The number of spines belonging to 1 Purkinje cell showed two developmental “peaks”: the first peak at 21 PN days was moderate (5.6 × 10⁴ spines/Purkinje cell) while the second maximum at 48 PN days was more significant (1.2 × 10⁵ spines/Purkinje cell), which then declined to 6.3 × 10⁴ spines/Purkinje cell at PN day 90. It is suggested that the temporary overproduction and the following decline in the number of Purkinje dendritic spines during the development of the cerebellar cortex may be the morphological indicator of the dynamics of synaptogenetic and of synaptic stabilization processes. © 1994 Wiley-Liss, Inc.     

Fast confocal imaging of calcium released from stores in dendritic spines

The emerging significance of calcium stores in neuronal plasticity and the assumed involvement of dendritic spines in long-term plastic properties of neurons have led us to examine the presence and possible regulation of calcium stores in dendritic spines. Immunohistochemical staining for ryanodine receptors was found in dendritic spines of cultured hippocampal neurons. Confocal microscopic imaging of calcium transients in dendritic spines of these neurons in response to caffeine allowed us to demonstrate an independent and unique calcium store in spines. The response to caffeine was blocked by thapsigargin and ryanodine, and maintained in calcium-free medium. The calcium stores were depleted faster in the spines than the dendrites. Furthermore, when calcium was released from stores under calcium-free conditions, and diffused passively between the spine and the dendrite, the length of the spine neck determined the degree of spine independence. Finally, the caffeine-sensitive ryanodine receptor-linked calcium store was instrumental in regulating the response of neurons to glutamate. These results have important implications for understanding the roles of dendritic spines in neuronal integration and plasticity.     

Plasticity of dendritic spines: Molecular function and dysfunction in neurodevelopmental disorders

Dendritic spines are tiny postsynaptic protrusions from a dendrite that receive most of the excitatory synaptic input in the brain. Functional and structural changes in dendritic spines are critical for synaptic plasticity, a cellular model of learning and memory. Conversely, altered spine morphology and plasticity are common hallmarks of human neurodevelopmental disorders, such as intellectual disability and autism. The advances in molecular and optical techniques have allowed for exploration of dynamic changes in structure and signal transduction at single‐spine resolution, providing significant insights into the molecular regulation underlying spine structural plasticity. Here, I review recent findings on: how synaptic stimulation leads to diverse forms of spine structural plasticity; how the associated biochemical signals are initiated and transmitted into neuronal compartments; and how disruption of single genes associated with neurodevelopmental disorders can lead to abnormal spine structure in human and mouse brains. In particular, I discuss the functions of the Ras superfamily of small GTPases in spatiotemporal regulation of the actin cytoskeleton and protein synthesis in dendritic spines. Multiple lines of evidence implicate disrupted Ras signaling pathways in the spine structural abnormalities observed in neurodevelopmental disorders. Both deficient and excessive Ras activities lead to disrupted spine structure and deficits in learning and memory. Dysregulation of spine Ras signaling, therefore, may play a key role in the pathogenesis of multiple neurodevelopmental disorders with distinct etiologies.     

Ovarian steroids increase glutamatergic related gene expression in serotonin neurons of macaques

Dendritic spines are the elementary structural units of neuronal plasticity and their proliferation and stabilization involve components of glutamate neurotransmission. In a model of hormone replacement therapy (HT), we sought the effect of estradiol (E) and progesterone (P) on gene expression related to glutamate neurotransmission in a laser captured preparation enriched for serotonin neurons from rhesus macaques. Microarray analysis was conducted (n = 2 animals/treatment) and then confirmed for pivotal genes with qRT-PCR on additional laser captured material (n = 3 animals/treatment). Ovariectomized rhesus macaques were treated with either placebo, E or E + P via Silastic implants for 1 month prior to euthanasia. The midbrain was obtained, sectioned and immunostained for TPH. TPH-positive neurons were laser captured using an Arcturus Laser Dissection Microscope (Pixel II). RNA from laser captured serotonin neurons (n = 2 animals/treatment) was hybridized to Rhesus Affymetrix GeneChips for screening purposes. There was a 2-fold or greater change in the expression of 28 probe sets related to glutamate processes in E and E + P treated animals. Quantitative (q) RT-PCR was conducted for 11 genes with a custom Taqman PCR array containing monkey specific primers and analyzed with ANOVA followed by Bonferroni's test. The log of the relative expression values indicated that in general, the responses to E and E + P were similar. Comparison of the relative expression or log relative expression in Ovx-controls to combined E and E + P treated groups with t-tests showed a significant increase in AMPA1 (GRIA1), AMPA2 (GRIA2), AMPA4 (GRIA4), NMDA2a (GRIN2A), metabotrophic glutamate receptor (GRM1), glutamine synthetase (GLUL), glutamate dehydrogenase (GLUD), glutamate cysteine ligase modifier subunit (GCLM), the glutamate transporter 2 (SLC1A2) and the glutamate transporter 3 (SLC1A3) with steroid treatment. There was no effect of steroid treatment on gene expression of the glutamate cysteine ligase catalytic subunit (GCLC). These data suggest that ovarian steroids target gene expression of ionotrophic and metabotrophic glutamate receptors in serotonin neurons. These receptors are present on dendritic spines and are necessary for spine maturation. The mRNAs coding for glutamate-related enzymes and transporters are likely derived from astrocytes or glutamate-containing terminals. Their induction by ovarian steroids indicates a complex upregulation of multiple components in the glutamate cycle and antioxidation, in addition to spine proliferation.     

Organization of mitochondria in olfactory bulb granule cell dendritic spines.

In contrast to dendritic spines with only postsynaptic functions, the spines of olfactory bulb granule cells subserve both pre- and postsynaptic roles. In single sections these spines were previously seen to contain mitochondria, most likely needed to provide energy for presynaptic functions, but their frequency and distribution were unknown. In order to understand the organization of mitochondria in these specialized dendritic appendages, we have studied the geometry and cytoplasmic organization of granule cell spines with computer-assisted reconstructions of serial electron micrographs. The spine heads were seen to be elliptical in shape with a single pair of reciprocal synapses on the concave face apposed to the mitral/tufted cell dendrite. Mitochondria were found localized in the spine neck as well as the spine head and often extended between the two compartments. Based on their variable distribution it seems reasonable to suggest that these mitochondria are motile and move in and out of spine compartments from the parent dendrite. Spine apparatus was apparent in most of the spines as membrane bound cisterns of smooth endoplasmic reticulum located close to mitochondria. The possible role of spine apparatus in facilitating the movement of mitochondria in the necks and heads of granule cell spines in the absence of microtubules is discussed.     

Super‐resolution structural analysis of dendritic spines using three‐dimensional structured illumination microscopy in cleared mouse brain slices

Three‐dimensional (3D) super‐resolution microscopy technique structured illumination microscopy (SIM) imaging of dendritic spines along the dendrite has not been previously performed in fixed tissues, mainly due to deterioration of the stripe pattern of the excitation laser induced by light scattering and optical aberrations. To address this issue and solve these optical problems, we applied a novel clearing reagent, LUCID, to fixed brains. In SIM imaging, the penetration depth and the spatial resolution were improved in LUCID‐treated slices, and 160‐nm spatial resolution was obtained in a large portion of the imaging volume on a single apical dendrite. Furthermore, in a morphological analysis of spine heads of layer V pyramidal neurons (L5PNs) in the medial prefrontal cortex (mPFC) of chronic dexamethasone (Dex)‐treated mice, SIM imaging revealed an altered distribution of spine forms that could not be detected by high‐NA confocal imaging. Thus, super‐resolution SIM imaging represents a promising high‐throughput method for revealing spine morphologies in single dendrites.     

The actin-binding domain of spinophilin is necessary and sufficient for targeting to dendritic spines

Spinophilin is enriched in dendritic spines, small protrusions of the postsynaptic membrane along the length of the dendrite that contain the majority of excitatory synapses. Spinophilin binds to protein phosphatase 1 with high affinity and targets it to dendritic spines, therefore placing it in proximity to regulate glutamate receptor activity. Spinophilin also binds to and bundles f-actin, the main cytoskeletal constituent of dendritic spines, and may therefore serve to regulate the structure of the synapse. In this study, we sought to determine the structural basis for the targeting of spinophilin to dendritic spines. Our results show that the actin-binding domain of spinophilin is necessary and sufficient for targeting of spinophilin to dendrites and dendritic spines.     

Glucocorticoid and β‐adrenergic regulation of hippocampal dendritic spines

Glucocorticoid hormones are particularly potent with respect to enhancing memory formation. Notably, this occurs in close synergy with arousal (i.e., when norepinephrine levels are enhanced). In the present study, we examined whether glucocorticoid and norepinephrine hormones regulate the number of spines in hippocampal primary neurons. We report that brief administration of corticosterone or the β‐adrenergic receptor agonist isoproterenol alone increases spine number. This effect becomes particularly prominent when corticosterone and isoproterenol are administered together. In parallel, corticosterone and isoproterenol alone increased the amplitude of miniature excitatory postsynaptic currents, an effect that is not amplified when both hormones are administered together. The effects of co‐application of corticosterone and isoproterenol on spines could be prevented by blocking the glucocorticoid receptor antagonist RU486. Taken together, both corticosterone and β‐adrenergic receptor activation increase spine number, and they exert additive effects on spine number for which activation of glucocorticoid receptors is permissive.     

Hippocampal dendritic spines remodeling and fear memory are modulated by GABAergic signaling within the basolateral amygdala complex

GABAergic signaling in the basolateral amygdala complex (BLA) plays a crucial role on the modulation of the stress influence on fear memory. Moreover, accumulating evidence suggests that the dorsal hippocampus (DH) is a downstream target of BLA neurons in contextual fear. Given that hippocampal structural plasticity is proposed to provide a substrate for the storage of long‐term memories, the main aim of this study is to evaluate the modulation of GABA neurotransmission in the BLA on spine density in the DH following stress on contextual fear learning. The present findings show that prior stressful experience promoted contextual fear memory and enhanced spine density in the DH. Intra‐BLA infusion of midazolam, a positive modulator of GABAa sites, prevented the facilitating influence of stress on both fear retention and hippocampal dendritic spine remodeling. Similarly to the stress‐induced effects, the blockade of GABAa sites within the BLA ameliorated fear memory emergence and induced structural remodeling in the DH. These findings suggest that GABAergic transmission in BLA modulates the structural changes in DH associated to the influence of stress on fear memory. © 2015 Wiley Periodicals, Inc.     

Conditional self‐discrimination enhances dendritic spine number and dendritic length at prefrontal cortex and hippocampal neurons of rats

We studied conditional self‐discrimination (CSD) in rats and compared the neuronal cytoarchitecture of untrained animals and rats that were trained in self‐discrimination. For this purpose, we used thirty 10‐week‐old male rats were randomized into three groups: one control group and two conditioning groups: a comparison group (associative learning) and an experimental group (self‐discrimination). At the end of the conditioning process, the experimental group managed to discriminate their own state of thirst. After the conditioning process, dendritic morphological changes in the pyramidal neurons of the prefrontal cortex and CA1 region of the dorsal hippocampus were evaluated using Golgi‐Cox stain method and then analyzed by the Sholl method. Differences were found in total dendritic length and spine density. Animals trained in self‐discrimination showed an increase in the dendritic length and the number of dendritic spines of neurons of the prefrontal cortex and CA1 region of the dorsal hippocampus. Our data suggest that conditional self‐discrimination improves the connectivity of the prefrontal cortex and dorsal CA1, which has implications for memory and learning processes. Synapse 69:543–552, 2015 . © 2015 Wiley Periodicals, Inc.     

Spatiotemporal expression of PSD‐95 in Fmr1 knockout mice brain

To investigate and compare the spatial and temporal expression of post‐synaptic density‐95 (PSD‐95) in Fmr1 knockout mice (the animal model of fragile X syndrome, FXS) and wild‐type mice brain, on postnatal day 7 (P7), P14, P21, P28 and P90, mice from each group were decapitated, and three principal brain regions (cerebral cortex, hippocampus and cerebellum) were obtained and stored for later experiments. PSD‐95 mRNA in the three brain areas was analyzed with quantitative RT‐PCR. PSD‐95 protein was measured by immunohistochemical staining and Western blot. In the three principal brain areas of Fmr1 knockout mice and wild‐type mice, the expression of PSD‐95 mRNA and protein were detected at the lowest levels on P7, and then significantly increased on P14, reaching the peak levels in adolescents or adults. Moreover, it was found that PSD‐95 mRNA and protein in the hippocampus were significantly decreased in Fmr1 knockout mice during the developmental period (P7, P14, P21 and P28) as well as at adulthood (P90) (P < 0.05, and P < 0.01, respectively). However, there was no significant difference of expression of PSD‐95 in the cortex and cerebellum between Fmr1 knockout and wild mice. The expression of PSD‐95 in the hippocampus might be regulated by fragile X mental retardation protein (FMRP) during mice early developmental and adult periods. It is suggested that impairment of PSD‐95 is possibly involved in hippocampal‐dependent learning defects, which are common in people with FXS.     

Effects of postoperative environments following dorsal hippocampal lesions on dendritic branching and spines in rat occipital cortex

Male Long-Evans rats sustained bilateral dorsal hippocampal lesions or were sham-operated when 31 days old. They were reared thereafter in either an ‘enriched’ (EC) or an ‘improverished’ (IC) environment for one month. The effects of lesion adn rearing conditions were measured on dendritic branching and spines in layer V pyramidal cells of area 17 by using a concentric ring analysis and by counting the number of spines on 50 μm segments of basilar dendrites. Hippocampal lesions significantly decreased the branching and the number of spines in both EC and IC rats. In contrast to what was observed in most behavioral studies, in which the effects of the postoperative environment were even larger in animals with lesions than in control animals, the present experiments showed that the cytological measures were affected by postoperative rearing conditions only in sham-operated rats (EC > IC). It is suggested, thereforem that the morphologic processes underlying the effects of the environment on behavioral recovery after hippocampal lesions can hardly be located in layer V pyramidal cells of area 17, which is considered as one of the most sensitive to environment in intact animals.     

Inhibitory and multisynaptic spines,and hemispherical synaptic specialization in the posterodorsal medial amygdala of male and female rats

The density of dendritic spines is sexually dimorphic and variable throughout the female estrous cycle in the rat posterodorsal medial amygdala (MePD), a relevant area for the modulation of reproductive behavior in rats. The local synaptic activity differs between hemispheres in prepubertal animals. Here we used serial section transmission electron microscopy to produce 3D reconstructions of dendritic shafts and spines to characterize synaptic contacts on MePD neurons of both hemispheres in adult males and in females along the estrous cycle. Pleomorphic spines and nonsynaptic filopodia occur in the MePD. On average, 8.6% of dendritic spines received inputs from symmetric gamma‐aminobutyric acid (GABA)‐immunoreactive terminals, whereas 3.6% received two synaptic contacts on the spine head, neck, or base. Presynaptic terminals in female right MePD had a higher density of synaptic vesicles and docked vesicles than the left MePD, suggesting a higher rate of synaptic vesicle release in the right MePD of female rats. In contrast, males did not show laterality in any of those parameters. The proportion of putative inhibitory synapses on dendritic shafts in the right MePD of females in proestrus was higher than in the left MePD, and higher than in the right MePD in males, or in females in diestrus or estrus. This work shows synaptic laterality depending on sex and estrous cycle phase in mature MePD neurons. Most likely, sexual hormone effects are lateralized in this brain region, leading to higher synaptic activity in the right than in the left hemisphere of females, mediating timely neuroendocrine and social/reproductive behavior. J. Comp. Neurol. 522:2075–2088, 2014. © 2013 Wiley Periodicals, Inc.     

Estradiol increases alpha7 nicotinic receptor in serotonergic dorsal raphe and noradrenergic locus coeruleus neurons of macaques

Acetylcholine, acting on presynaptic nicotinic receptors (nAChRs), modulates the release of neurotransmitters in the brain. The rat dorsal raphe nucleus (DR) and the locus coeruleus (LC) receive cholinergic input and express the alpha7nAChR. In previous reports, we demonstrated that estradiol (E) administration stimulates DR serotonergic and LC noradrenergic function in the macaque. In addition, it has been reported that E induces the expression of the alpha7nAChR in rats. We questioned whether E increased the expression of the alpha7nAChR in the macaque DR and LC. We utilized double immunostaining to study the effect of a simulated preovulatory surge of E on the expression of the alpha7nAChR in the DR and the LC and to determine whether alpha7nAChR colocalizes with serotonin and tyrosine hydroxylase (TH) in macaques. There was no difference in the number of alpha7nAChR-positive neurons between ovariectomized (OVX) controls and OVX animals treated with a silastic capsule containing E (Ecap). However, supplemental infusion of E for 5-30 hours to Ecap animals (Ecap + inf) significantly increased the number of alpha7nAChR-positive neurons in DR and LC. In addition, supplemental E infusion significantly increased the number of neurons in which alpha7nAChR colocalized with serotonin and TH. These results constitute an important antecedent for study of the effects of nicotine and ovarian steroid hormones in the physiological functions regulated by the DR and the LC in women.     

The role of the dorsal raphe nucleus in the development,expression, and treatment of L‐dopa‐induced dyskinesia in hemiparkinsonian rats

Convergent evidence indicates that in later stages of Parkinson's disease raphestriatal serotonin neurons compensate for the loss of nigrostriatal dopamine neurons by converting and releasing dopamine derived from exogenous administration of the pharmacotherapeutic L‐3,4‐dihydroxyphenyl‐L ‐alanine (L ‐dopa). Because the serotonin system is not equipped with dopamine autoregulatory mechanisms, it has been postulated that raphe‐mediated striatal dopamine release may fluctuate dramatically. These fluctuations may portend the development of abnormal involuntary movements called L ‐dopa‐induced dyskinesia (LID). As such, it has been hypothesized that reducing the activity of raphestriatal neurons could dampen supraphysiological stimulation of striatal dopamine receptors thereby alleviating LID. To directly address this, the current study employed the rodent model of LID to investigate the contribution of the rostral raphe nuclei (RRN) in the development, expression and treatment of LID. In the first study, dual serotonin/dopamine selective lesions of the RRN and medial forebrain bundle, respectively, verified that the RRN are essential for the development of LID. In a direct investigation into the neuroanatomical specificity of these effects, microinfusions of ±8‐OH‐DPAT into the intact dorsal raphe nucleus dose‐dependently attenuated the expression of LID without affecting the antiparkinsonian efficacy of L ‐dopa. These current findings reveal the integral contribution of the RRN in the development and expression of LID and implicate a prominent role for dorsal raphe 5‐HT1AR in the efficacious properties of 5‐HT1AR agonists. Synapse 63:610–620, 2009. © 2009 Wiley‐Liss, Inc.