Astrocyte-secreted IL-33 mediates homeostatic synaptic plasticity in the adult hippocampus

Hippocampal synaptic plasticity is important for learning and memory formation. Homeostatic synaptic plasticity is a specific form of synaptic plasticity that is induced upon prolonged changes in neuronal activity to maintain network homeostasis. While astrocytes are important regulators of synaptic transmission and plasticity, it is largely unclear how they interact with neurons to regulate synaptic plasticity at the circuit level. Here, we show that neuronal activity blockade selectively increases the expression and secretion of IL-33 (interleukin-33) by astrocytes in the hippocampal cornu ammonis 1 (CA1) subregion. This IL-33 stimulates an increase in excitatory synapses and neurotransmission through the activation of neuronal IL-33 receptor complex and synaptic recruitment of the scaffold protein PSD-95. We found that acute administration of tetrodotoxin in hippocampal slices or inhibition of hippocampal CA1 excitatory neurons by optogenetic manipulation increases IL-33 expression in CA1 astrocytes. Furthermore, IL-33 administration in vivo promotes the formation of functional excitatory synapses in hippocampal CA1 neurons, whereas conditional knockout of IL-33 in CA1 astrocytes decreases the number of excitatory synapses therein. Importantly, blockade of IL-33 and its receptor signaling in vivo by intracerebroventricular administration of its decoy receptor inhibits homeostatic synaptic plasticity in CA1 pyramidal neurons and impairs spatial memory formation in mice. These results collectively reveal an important role of astrocytic IL-33 in mediating the negative-feedback signaling mechanism in homeostatic synaptic plasticity, providing insights into how astrocytes maintain hippocampal network homeostasis.

Synaptic plasticity, the ability of neurons to alter the structure and strength of synapses, is important for the refinement of neuronal circuits in response to sensory experience during development (1) as well as learning and memory formation in adults (2, 3). To maintain the stability of neuronal network activity, the synaptic strength of neurons is modified through a negative-feedback mechanism termed homeostatic synaptic plasticity (4–6). Specifically, inhibiting neuronal activity in cultured neuronal cells or hippocampal slices by pharmacological administration of the sodium channel blocker tetrodotoxin (TTX) increases the strength of excitatory synapses to rebalance network activity (5–7).The hippocampus, which comprises the cornu ammonis 1 (CA1), CA2, CA3, and dentate gyrus subregions, is important for memory storage and retrieval. In particular, the CA1 subregion constitutes the primary output of the hippocampus, which is thought to be essential for most hippocampus-dependent memories (8, 9). Moreover, experience-driven synaptic changes in the CA1 microcircuitry impact how information is integrated (10, 11). Accordingly, the induction and expression of synaptic plasticity at hippocampal CA1 excitatory synapses are critically dependent on the structural remodeling and composition of synapses as well as functional modifications of pre- and postsynaptic proteins and neurotransmitter receptors (4–6, 12). As such, structural plasticity is a major regulatory mechanism of homeostatic synaptic plasticity in the hippocampal CA1 region. While most excitatory synapses are located at dendritic spines, morphological changes of dendritic spines likely participate in compensatory adaptations of hippocampal network activity and are therefore involved in learning, memory formation (13), and memory extinction (14).The efficacy of synaptic transmission and the wiring of neuronal circuitry are regulated not only by bidirectional communication between pre- and postsynaptic neurons, but also through the interactions between neurons and their associated glial cells (15–17). Astrocytes, as the most abundant type of glia in the central nervous system, actively regulate synapse formation, function, and maintenance during development and in the adult brain (18–20). However, the molecular basis of astrocyte–neuron communication in synaptic plasticity is largely unknown. Nevertheless, one of the mechanisms by which astrocytes regulate synapses is by secreting factors (21–25); the most well-characterized one is TNFα. Notably, pharmacologically induced deprivation of neuronal activity increases TNFα release from astrocytes, which modulates homeostatic plasticity in both excitatory and inhibitory neurons through regulation of neuronal glutamate and GABA receptor trafficking (24, 26). Further in vivo studies on germline knockout mice support the roles of astrocyte-secreted TNFα in homeostatic adaptations of cortical circuitry during sensory deprivation (27, 28). Another cytokine interleukin-33 (IL-33) is secreted by astrocytes to regulate synapse development in spinal cord and thalamus (29). Nevertheless, it remains largely unknown how astrocytes respond to changes in neuronal activity to regulate homeostatic synaptic plasticity in the hippocampus as well as learning and memory formation.In this study, we identified IL-33 as an astrocyte-secreted factor which mediates homeostatic synaptic plasticity in the CA1 subregion of adult hippocampus. Pharmacological blockade of neuronal activity or in vivo optogenetic inhibition of CA1 pyramidal neurons stimulates a local increase in the expression and release of IL-33 from the astrocytes. In turn, this astrocyte-secreted IL-33 and its ST2/IL-1RAcP receptor complex mediate the increase of excitatory synapses and neurotransmission in homeostatic synaptic plasticity. Two-photon imaging of CA1 pyramidal neurons in vivo reveals that IL-33 promotes dendritic spine formation through the synaptic recruitment of postsynaptic scaffolding protein PSD-95. Importantly, conditional knockout of IL-33 in astrocytes decreases excitatory synapses in the CA1 subregion, and inhibition of IL-33/ST2 signaling in adult mice abolishes the homeostatic synaptic plasticity in CA1 pyramidal neurons, resulting in impaired spatial memory formation. Hence, our findings collectively show that astrocyte-secreted IL-33 plays an important role in homeostatic synaptic plasticity in the adult hippocampus and spatial memory formation.     

Estrogen synthesis in the brain--role in synaptic plasticity and memory

Estrogen and androgen are synthesized from cholesterol locally in hippocampal neurons of adult animals. These neurosteroids are synthesized by cytochrome P450s and hydroxysteroid dehydrogenases (HSDs) and 5alpha-reductase. The expression levels of enzymes are as low as 1/200-1/50,000 of those in endocrine organs, however these numbers are high enough for local synthesis. Localization of P450(17alpha), P450arom, 17beta-HSD and 5alpha-reductase is observed in principal glutamatergic neurons in CA1, CA3 and the dendate gyrus. Several nanomolar levels of estrogen and androgen are observed in the hippocampus. Estrogen modulates memory-related synaptic plasticity not only slowly but also rapidly in the hippocampus. Rapid action of 17beta-estradiol via membrane receptors is demonstrated for spinogenesis and long-term depression (LTD). The enhancement of LTD by 1-10nM estradiol occurs within 1 h. The density of spine is increased in CA1 pyramidal neurons within 2h after application of estradiol. The density of spine-like structure is, however, decreased by estradiol in CA3 pyramidal neurons. ERalpha, but not ERbeta, induces the same enhancement/suppression effects on both spinogenesis and LTD.     

NogoA restricts synaptic plasticity in the adult hippocampus on a fast time scale

Whereas the role of NogoA in limiting axonal fiber growth and regeneration following an injury of the mammalian central nervous system (CNS) is well known, its physiological functions in the mature uninjured CNS are less well characterized. NogoA is mainly expressed by oligodendrocytes, but also by subpopulations of neurons, in particular in plastic regions of the CNS, e.g., in the hippocampus where it is found at synaptic sites. We analyzed synaptic transmission as well as long-term synaptic plasticity (long-term potentiation, LTP) in the presence of function blocking anti-NogoA or anti-Nogo receptor (NgR) antibodies and in NogoA KO mice. Whereas baseline synaptic transmission, short-term plasticity and long-term depression were not affected by either approach, long-term potentiation was significantly increased following NogoA or NgR1 neutralization. Synaptic potentiation thus seems to be restricted by NogoA. Surprisingly, synaptic weakening was not affected by interfering with NogoA signaling. Mechanistically of interest is the observation that by blockade of the GABA(A) receptors normal synaptic strengthening reoccurred in the absence of NogoA signaling. The present results show a unique role of NogoA expressed in the adult hippocampus in restricting physiological synaptic plasticity on a very fast time scale. NogoA could thus serve as an important negative regulator of functional and structural plasticity in mature neuronal networks.     

Effects of dihydrotestosterone on synaptic plasticity of hippocampus in male SAMP8 mice

The senescence-accelerated-prone mouse 8 (SAMP8) has been proposed as a suitable, naturally derived animal model for investigating the fundamental mechanisms of Alzheimer's disease (AD). In addition, the serum testosterone levels decrease quickly in the natural growth process of this model. This study investigated the effect of androgen deficiency on the synaptic plasticity of hippocampus in male SAMP8 mice after castration and dihydrotestosterone (DHT) administration. We observed the dendritic spines and synapses using Golgi staining and transmission electron microscope. Androgen deficiency after castration significantly reduced the number of apical dendritic thorns, and the abnormal ultrastructure of excitatory synapses was more obvious. Androgen replacement therapy reversed this change. To explore the protective mechanisms and neurological basis of DHT, we researched the changes of expression of GluN1 subunit-containing N-methyl-d-aspartate receptors (NMDARs) and synaptophysin (SYN), which are closely related to synaptic plasticity. Comparisons were made among results observed with immunohistochemistry techniques, Western blots analysis and RT-PCR analysis. The GluN1 and SYN regulation at the protein and mRNA levels probably be related to the DHT-induced morphological synaptic plasticity. This study will be helpful for understanding the function of androgen, and it provides a valuable theoretical basis about the protective and therapeutic targets of androgen in AD.     

丁苯酞对糖尿病小鼠海马突触可塑性及氧化应激状态的影响

目的观察丁苯酞对糖尿病小鼠海马突触可塑性和氧化应激状态的影响,探索丁苯酞保护糖尿病认知功能的作用机制。方法选取16只db/db小鼠随机分为糖尿病组和丁苯酞组,每组8只,另选取同窝db/m小鼠8只为对照组。丁苯酞组给予丁苯酞灌胃6周,糖尿病组等量植物油灌胃,对照组等量植物油灌胃。Morris水迷宫记录逃避潜伏期和目标象限自由游泳时间检测干预后学习和空间记忆功能;透射电子显微镜观察海马突触超微结构变化;ELISA检测海马超氧化物歧化酶(SOD)、丙二醛和8-羟化脱氧鸟苷(8-OHdG)水平;实时定量PCR和蛋白免疫印迹检测突触素、p67phox、gp91phox mRNA和蛋白表达。结果与对照组比较,糖尿病组和丁苯酞组第5天逃避潜伏期明显延长,目标象限自由游泳时间明显减少(P0.05)。与糖尿病组比较,丁苯酞组逃避潜伏期明显减少,目标象限自由游泳时间明显增加(P0.05),海马CA1区突触间隙结构较清晰、突触和囊泡数量增加,SOD水平明显上升(P0.05),丙二醛、8-OHdG水平明显下降[(1.02±0.04)ng/L vs (1.35±0.11)ng/L,(18.94±0.45)ng/L vs (22.19±0.34)ng/L,P0.05],突触素表达明显升高,p67phox和gp91phox表达明显降低(P0.05)。结论丁苯酞可通过减轻氧化应激、改善糖尿病小鼠海马突触可塑性,提高糖尿病小鼠的认知功能。     

Estrogen synthesis in the brain—Role in synaptic plasticity and memory

Estrogen and androgen are synthesized from cholesterol locally in hippocampal neurons of adult animals. These neurosteroids are synthesized by cytochrome P450s and hydroxysteroid dehydrogenases (HSDs) and 5alpha-reductase. The expression levels of enzymes are as low as 1/200–1/50,000 of those in endocrine organs, however these numbers are high enough for local synthesis. Localization of P450(17alpha), P450arom, 17beta-HSD and 5alpha-reductase is observed in principal glutamatergic neurons in CA1, CA3 and the dendate gyrus. Several nanomolar levels of estrogen and androgen are observed in the hippocampus.Estrogen modulates memory-related synaptic plasticity not only slowly but also rapidly in the hippocampus. Rapid action of 17beta-estradiol via membrane receptors is demonstrated for spinogenesis and long-term depression (LTD). The enhancement of LTD by 1–10 nM estradiol occurs within 1 h. The density of spine is increased in CA1 pyramidal neurons within 2 h after application of estradiol. The density of spine-like structure is, however, decreased by estradiol in CA3 pyramidal neurons. ERalpha, but not ERbeta, induces the same enhancement/suppression effects on both spinogenesis and LTD.     

Follistatin mediates learning and synaptic plasticity via regulation of Asic4 expression in the hippocampus

The biological mechanisms underpinning learning are unclear. Mounting evidence has suggested that adult hippocampal neurogenesis is involved although a causal relationship has not been well defined. Here, using high-resolution genetic mapping of adult neurogenesis, combined with sequencing information, we identify follistatin (Fst) and demonstrate its involvement in learning and adult neurogenesis. We confirmed that brain-specific Fst knockout (KO) mice exhibited decreased hippocampal neurogenesis and demonstrated that FST is critical for learning. Fst KO mice exhibit deficits in spatial learning, working memory, and long-term potentiation (LTP). In contrast, hippocampal overexpression of Fst in KO mice reversed these impairments. By utilizing RNA sequencing and chromatin immunoprecipitation, we identified Asic4 as a target gene regulated by FST and show that Asic4 plays a critical role in learning deficits caused by Fst deletion. Long-term overexpression of hippocampal Fst in C57BL/6 wild-type mice alleviates age-related decline in cognition, neurogenesis, and LTP. Collectively, our study reveals the functions for FST in adult neurogenesis and learning behaviors.

A wide variety of human disorders such as intellectual disability feature impairment of learning and memory. These conditions have a profound impact on quality of life and social functioning. Despite this, the biological mechanisms underpinning learning are not yet fully understood. However, mounting evidence has suggested that hippocampal neurogenesis is involved (1). Several publications report learning or emotional phenotypes in rodent models, which have little or no neurogenesis in adulthood (2–5), although these, and other findings, have been questioned (6). Despite the lack of consensus on the causal relationship about adult hippocampal neurogenesis on learning, it is possible that the same genes affect both neurogenesis and learning. Indeed, in mouse inbred strains, neurogenesis is genetically correlated with performance in spatial learning and memory tasks (7, 8), and spatial memory in rats is related to the levels of hippocampal neurogenesis (9).We hypothesized that one way to identify genes that influence learning is to identify those that contribute to heritable variation in neurogenesis (10). In this study, we used genetic mapping data from heterogeneous stock (HS) mice to identify loci associated with neurogenesis (11). We increased mapping resolution further by the incorporation of sequence information. This technique has been shown to increase mapping resolution to the point of identifying causal variants (12). One of the target genes, Fst, is predominantly expressed in the cortex, olfactory bulb, and dentate gyrus. Interestingly, two of these regions are where adult neurogenesis occurs. Fst is known to encode the protein follistatin (FST), an activin-binding protein (13, 14), which neutralizes activin bioactivity (15). FST also binds to other members of the transforming growth factor-β superfamily but with a 10-fold lower affinity than for activin A (16). In the brain, activin has been shown to play a role in the maintenance of long-term memory (17). Despite numerous studies about the functions of FST in regulation of muscle growth (18) and energy metabolism (19), its roles in the brain are still unknown.In this study, we used brain-specific Fst knockout (KO) mice to confirm its effect on neurogenesis, and we identified learning deficits in the Fst KO mice as well as deficits in long-term potentiation (LTP) through the regulation of acid-sensing ion channel 4 (ASIC4). Our study demonstrates the power of combining genetic mapping with functional work, and we provide insights into the role of FST in the hippocampus and its influence on learning.     

Cholinergic plasticity in the hippocampus

Tests were made for use-dependent plasticity in the cholinergic projections to hippocampus. Transient infusion of the cholinergic agonist carbachol into hippocampal slices induced rhythmic activity that persisted for hours after washout. Comparable effects were obtained with physostigmine, a drug that blocks acetylcholine breakdown and thereby enhances cholinergic transmission. It thus seems that activation of cholinergic synapses induces lasting changes in hippocampal physiology. Two lines of evidence indicated that cholinergic synapses are also the sites at which the plasticity is expressed. First, the induction and expression of the rhythms were not blocked by the N-methyl-D-aspartate receptor antagonist D-2-amino-5-phosphonovaleric acid, indicating that a long-term potentiation effect between pyramidal cells was not involved. Second, a muscarinic antagonist (atropine) completely abolished stable rhythmic activity after agonist washout. This result indicates that endogenous cholinergic activity is responsible for the persistence of rhythmic oscillations. These experiments suggest that short periods of intense cholinergic activity induce lasting changes in cholinergic synapses and thus extend such forms of plasticity to beyond the glutamatergic system.     

Altered expression of histone and synaptic plasticity associated genes in the hippocampus of streptozotocin-induced diabetic mice

Accumulating evidence indicates that hyper-glycaemia is deleterious to brain function, in particular to the hippocampus. It is thought this hippocampal dysfunction may contribute to hyperglycaemia related cognitive impairment, such as that which manifests with diabetes. In the present study, we investigated the effects of diabetes-related hyperglycaemia on hippocampal gene expression, in order to identify potential mechanisms that might be associated with the cognitive dysfunction that develops with diabetes mellitus. Genome-wide gene expression profiling was carried out on the hippocampi from streptozotocin (STZ)-induced diabetic mice, and from vehicle treated control mice. Genes of interest that satisfied expression fold-change and statistical criteria, and that were considered to be potentially associated with cognitive function, were further tested by real time, quantitative polymerase chain reaction (qPCR) analysis. We found that STZ-induced diabetes resulted in decreased hippocampal expression of genes involved in epigenetic regulation and synaptic plasticity, for example, histone deacetylases and glycogen synthase kinase 3 beta (HDACs and GSK3β). We also found increased expression of genes involved in signalling cascades related to cell growth, cell survival and energy metabolism, such as neurotropic tyrosine kinase receptor type 2, apolipoprotein E, and protein tyrosine phosphatase receptor type (Ntrk2, APOE, PTPRT). To our knowledge this is the first study to demonstrate a gene expression profile implicating epigenetic modifications and alterations of synaptic plasticity associated genes in diabetes mellitus. The present study will improve our understanding of the neural mechanisms that might underpin diabetes-related cognitive dysfunction.     

Enhancement of long-term memory retention and short-term synaptic plasticity in cbl-b null mice

The cbl-b gene is a member of the cbl protooncogene family. It encodes a protein with multiple domains, which can interact with other proteins in a variety of signaling pathways. The functions of cbl family genes in the brain are unknown. In this report, we used genetic, immunohistochemical, behavioral, and electrophysiological approaches to study the role of cbl-b in learning and memory. Cbl-b null mice developed normally and had no abnormalities in their locomotor performance. In spatial learning and memory studies, cbl-b null and WT mice performed similarly during training. To test memory retention, two probe trials were used. cbl-b null mice performed slightly better 1 day after training. However, in the probe trial 45 days after training, the cbl-b null group showed significantly higher memory retention than WT mice, suggesting an enhancement of long-term memory. Using electrophysiological approaches, we found there was enhanced paired-pulse facilitation in the Schaffer Collateral-CA1 glutamatergic synapses of the cbl-b null mice. On the other hand, there was no difference in long-term potentiation between the two groups of mice. In summary, we provide evidence that (i) cbl-b protein is concentrated in the synaptic regions of CA1, CA3, and the dentate gyrus of the hippocampus; (ii) cbl-b null mice have enhanced long-term memory; and (iii) cbl-b null mice show an enhancement in short-term plasticity. These results indicate that cbl-b is a negative regulator of long-term memory, and its neuronal mechanism regulates synaptic transmission in the hippocampus.     

Involvement of ryanodine receptors in neurotrophin-induced hippocampal synaptic plasticity and spatial memory formation

Ryanodine receptors (RyR) amplify activity-dependent calcium influx via calcium-induced calcium release. Calcium signals trigger postsynaptic pathways in hippocampal neurons that underlie synaptic plasticity, learning, and memory. Recent evidence supports a role of the RyR2 and RyR3 isoforms in these processes. Along with calcium signals, brain-derived neurotrophic factor (BDNF) is a key signaling molecule for hippocampal synaptic plasticity and spatial memory. Upon binding to specific TrkB receptors, BDNF initiates complex signaling pathways that modify synaptic structure and function. Here, we show that BDNF-induced remodeling of hippocampal dendritic spines required functional RyR. Additionally, incubation with BDNF enhanced the expression of RyR2, RyR3, and PKMζ, an atypical protein kinase C isoform with key roles in hippocampal memory consolidation. Consistent with their increased RyR protein content, BDNF-treated neurons generated larger RyR-mediated calcium signals than controls. Selective inhibition of RyR-mediated calcium release with inhibitory ryanodine concentrations prevented the PKMζ, RyR2, and RyR3 protein content enhancement induced by BDNF. Intrahippocampal injection of BDNF or training rats in a spatial memory task enhanced PKMζ, RyR2, RyR3, and BDNF hippocampal protein content, while injection of ryanodine at concentrations that stimulate RyR-mediated calcium release improved spatial memory learning and enhanced memory consolidation. We propose that RyR-generated calcium signals are key features of the complex neuronal plasticity processes induced by BDNF, which include increased expression of RyR2, RyR3, and PKMζ and the spine remodeling required for spatial memory formation.     

Altered synaptic plasticity and memory formation in nitric oxide synthase inhibitor-treated rats.

Nitric oxide (NO) is a messenger molecule that is produced in the brain from the metabolism of L-arginine to L-citrulline. Growing evidence suggests a physiological role for NO in long-term potentiation (LTP). Since LTP is a form of synaptic plasticity thought to be involved in learning and memory, we have tested whether inhibition of endogenous NO production affects memory capacities of rats. We found that the NO synthase [L-arginine, NADPH:oxygen oxidoreductase (nitric oxide-forming), EC 1.14.13.39] inhibitor N omega-nitro-L-arginine, at doses blocking LTP in hippocampal slices, impairs spatial learning in a radial arm maze and olfactory memory in a social recognition test. In contrast, N omega-nitro-L-arginine left shock-avoidance learning unaffected. These results indicate that NO is involved in some but not all forms of memory and further support the existence of a causal link between LTP and spatial learning.     

Distinct kinetics of synaptic structural plasticity,memory formation,and memory decay in massed and spaced learning

Long-lasting memories are formed when the stimulus is temporally distributed (spacing effect). However, the synaptic mechanisms underlying this robust phenomenon and the precise time course of the synaptic modifications that occur during learning remain unclear. Here we examined the adaptation of horizontal optokinetic response in mice that underwent 1 h of massed and spaced training at varying intervals. Despite similar acquisition by all training protocols, 1 h of spacing produced the highest memory retention at 24 h, which lasted for 1 mo. The distinct kinetics of memory are strongly correlated with the reduction of floccular parallel fiber–Purkinje cell synapses but not with AMPA receptor (AMPAR) number and synapse size. After the spaced training, we observed 25%, 23%, and 12% reduction in AMPAR density, synapse size, and synapse number, respectively. Four hours after the spaced training, half of the synapses and Purkinje cell spines had been eliminated, whereas AMPAR density and synapse size were recovered in remaining synapses. Surprisingly, massed training also produced long-term memory and halving of synapses; however, this occurred slowly over days, and the memory lasted for only 1 wk. This distinct kinetics of structural plasticity may serve as a basis for unique temporal profiles in the formation and decay of memory with or without intervals.During learning, memories are formed in a specific population of neuronal circuits and are consolidated for persistence (1, 2). These memory processes are supported by discrete subcellular events such as reversible modifications in the efficacy of synaptic transmission (3–5) or persistent structural modifications in the size and number of synaptic connections (6–8). However, how these synaptic modifications relate to the dynamics of formation and decay of memories in behaving animals remains elusive. Memory formation and its persistence are also sensitive to the temporal features of stimulus presentation, as observed in the well-known “spacing effect.” Training trials that include resting intervals between them (spaced training) produce stronger and longer-lasting memories than do the same number of trials with no intervals (massed training) (9). The spacing effect has been observed in a variety of explicit and implicit memory tasks (10–13), and the molecular mechanisms supporting this phenomenon have been reported (14–18). Various intracellular signaling molecules such as CREB (19), mitogen-activated protein (MAP) kinase (20, 21), and PKA (22, 23) underlie the spacing effect and are implicated in the remodeling of neuronal structures (23). In vitro studies showed that spaced stimuli induced the protrusion of new filopodia (20) and the recruitment of new synapses (24) in hippocampal neurons. However, despite the existence of numerous behavioral and molecular studies, no conjoint study has elucidated the synaptic correlates that underpin the expression of the spacing effect during learning. Here we studied the temporal evolution and decay of memory and its correlation with synaptic modifications during learning with distinct temporal patterns of training.We used an adaptation of the horizontal optokinetic response (HOKR), which is a simple model of cerebellum-dependent motor learning. It is a compensatory eye movement for stabilization of the visual image on the retina during horizontal motion of the surroundings. A surrounding that oscillates horizontally at a given frequency causes retinal slips in naive animals and facilitates HOKR 1 h after training (HOKR adaptation) (25–27). The amount of adaptation can be quantitatively monitored, and the flocculus (Fl), which is a phylogenetically preserved cerebellar lobule, is involved in the adaptation of the HOKR (28, 29). These features render this paradigm as an experimental model, useful for investigating neural correlates and mechanisms involved in motor learning. In a previous study, we showed that the short-term adaptation of HOKR induced by 1-h training was accompanied by a rapid and transient reduction (28%) in the number of AMPA receptors (AMPARs) in parallel fiber (PF) to Purkinje cell (PC) synapses, whereas the long-term adaptation induced by repeated 1-h training over 5 d was accompanied by a slowly developing reduction (45%) of PF–PC synapses (30). Despite recent controversies on the role of long-term depression (LTD) and a postulated role of long-term potentiation in cerebellar motor learning (31–33), this study first showed that LTD as a form of reduced AMPARs in PF–PC synapses does occur in physiological learning.In the present study, we further examined how the spacing effect is correlated with the structural plasticity in PF–PC synapses. We showed that spaced training including 1-h intervals induced stable long-lasting memories within 4 h after the training, which was accompanied by a rapid and long-lasting (>1 mo) reduction of PF–PC synapses after a transient reduction in AMPAR density and shrinkage of PF–PC synapses and PC spines. One hour of massed training also induced a gradual reduction of the PF–PC synapses, which reached the same level as that observed for the spaced training 5 d later but recovered faster within 10 d. The time course corresponded well with the slower establishment and quicker decay of long-lasting memory induced by massed training. The tight correlation observed between the structural modifications and the kinetics of long-lasting memory pinpoints the distinct temporal regulation of synaptic connections as a mechanism underlying the spacing effect.     

Pre- and postnatal propylthiouracil-induced hypothyroidism impairs synaptic transmission and plasticity in area CA1 of the neonatal rat hippocampus

Thyroid hormones are essential for neonatal brain development. It is well established that insufficiency of thyroid hormone during critical periods of development can impair cognitive functions. The mechanisms that underlie learning deficits in hypothyroid animals, however, are not well understood. As impairments in synaptic function are likely to contribute to cognitive deficits, the current study tested whether thyroid hormone insufficiency during development would alter quantitative characteristics of synaptic function in the hippocampus. Developing rats were exposed in utero and postnatally to 0, 3, or 10 ppm propylthiouracil (PTU), a thyroid hormone synthesis inhibitor, administered in the drinking water of dams from gestation d 6 until postnatal day (PN) 30. Excitatory postsynaptic potentials and population spikes were recorded from the stratum radiatum and the pyramidal cell layer, respectively, in area CA1 of hippocampal slices from offspring between PN21 and PN30. Baseline synaptic transmission was evaluated by comparing input-output relationships between groups. Paired-pulse facilitation, paired-pulse depression, long-term potentiation, and long-term depression were recorded to examine short- and long-term synaptic plasticity. PTU reduced thyroid hormones, reduced body weight gain, and delayed eye-opening in a dose-dependent manner. Excitatory synaptic transmission was increased by developmental exposure to PTU. Thyroid hormone insufficiency was also dose-dependently associated with a reduction paired-pulse facilitation and long-term potentiation of the excitatory postsynaptic potential and elimination of paired-pulse depression of the population spike. The results indicate that thyroid hormone insufficiency compromises the functional integrity of synaptic communication in area CA1 of developing rat hippocampus and suggest that these changes may contribute to learning deficits associated with developmental hypothyroidism.     

Stress in pregnancy activates neurosteroid production in the fetal brain

Neurosteroids such as allopregnanolone are potent agonists at the GABA(A) receptor and suppress the fetal CNS activity. These steroids are synthesized in the fetal brain either from cholesterol or from circulating precursors derived from the placenta. The concentrations of allopregnanolone are remarkably high in the fetal brain and rise further in response to acute hypoxic stress, induced by constriction of the umbilical cord. This response may result from the increased 5alpha-reductase and cytochrome P-450(SCC) expression in the brain. These observations suggest that the rise in neurosteroid concentrations in response to acute hypoxia may represent an endogenous protective mechanism that reduces excitotoxicity following hypoxic stress in the developing brain. In contrast to acute stress, chronic hypoxemia induces neurosteroidogenic enzyme expression without an increase in neurosteroid concentrations and, therefore, may pose a greater risk to the fetus. At birth, the allopregnanolone concentrations in the brain fall markedly, probably due to the loss of placental precursors; however, stressors, including hypoxia and endotoxin-induced inflammation, raise allopregnanolone concentrations in the newborn brain. This may protect the newborn brain from hypoxia-induced damage. However, the rise in allopregnanolone concentrations was also associated with increased sleep. This rise in sedative steroid levels may depress arousal and contribute to the risk of sudden infant death syndrome. Our recent findings indicate that acute hypoxic stress in pregnancy initiates a neurosteroid response that may protect the fetal brain from hypoxia-induced cell death, whereas the decline in allopregnanolone levels after birth may result in greater vulnerability to brain injury in neonates.     

老年小鼠突触可塑性和记忆功能变化与nNOS表达的关系

目的 对老年小鼠突触可塑性和记忆能力变化与海马nNOS表达变化之间的关系进行探讨.方法 2月龄(青年)和16月龄(老年)昆明小鼠分别用Y型迷宫测试自发交替和活动能力,离体脑片细胞外观测海马长时程增强(LTP)的变化,免疫组化检测海马nNOS阳性细胞表达的变化.结果 老年小鼠的自发交替的百分率和活动能力较青年小鼠明显下降(P＜0.01),离体海马脑片LTP诱发成功率和群峰电位振幅增大率明显下降(P＜0.01),海马CA1区、齿状回的nNOS阳性细胞的染色强度减弱(P＜0.01).结论 小鼠在衰老过程中会伴有突触可塑性和记忆功能降低,其病理机制和nNOS神经元丧失有关.     

Reactivation of stalled polyribosomes in synaptic plasticity

Some forms of synaptic plasticity require rapid, local activation of protein synthesis. Although this is thought to reflect recruitment of mRNAs to free ribosomes, this would limit the speed and magnitude of translational activation. Here we provide compelling in situ evidence supporting an alternative model in which synaptic mRNAs are transported as stably paused polyribosomes. Remarkably, we show that metabotropic glutamate receptor activation allows the synthesis of proteins that lead to a functional long-term depression phenotype even when translation initiation has been greatly reduced. Thus, neurons evolved a unique mechanism to swiftly translate synaptic mRNAs into functional protein upon synaptic signaling using stalled polyribosomes to bypass the rate-limiting step of translation initiation. Because dysregulated plasticity is implicated in neurodevelopmental and psychiatric disorders such as fragile X syndrome, this work uncovers a unique translational target for therapies.Most studies of translational control focus on initiation, the process where mRNAs recruit ribosomes and catalyze the first step of translation (1). This highly regulated and normally rate-limiting step of translation is followed by elongation and termination, resulting in completed proteins. Although multiple ribosomes on a given mRNA (a polyribosome) imply active peptide synthesis, we and others identified neuronal RNA granules—motile aggregates of nontranslating ribosomes (2, 3). These electron-dense bodies contain single copies of synaptic mRNAs that are translationally silenced during their transport from soma to synapse (1, 4).Many models assume that neuronally transported mRNAs are translationally paused before completion of the initiation step of translation during transport. An appropriate synaptic signal would then activate translation (initiation/elongation/termination) of the granule mRNA. However, it is not clear how many free ribosomal subunits are present at synapses to support translation initiation. Further, at a typical translation elongation rate of six amino acids per s (5, 6), synthesis of larger synaptic proteins (e.g., microtubule-associated protein 1b; MAP1b) would take over 5 min even if initiation were immediate. These two factors constrain the speed and magnitude of synaptic translation and, thus, plasticity. As some forms of synaptic plasticity require rapid (<10 min) and localized activation of protein synthesis, an alternative model is wanting (7–9).We have previously proposed the concept of a neuronal RNA granule as a stalled polyribosome (10, 11). Ribosomal stalling has been shown to occur in lysates from a mouse neuroblastoma cell line and in an in vitro rabbit reticulocyte lysate translation assay programmed with brain homogenate (12). Whether neuronal ribosome stalling occurs in vivo is uncertain. We hypothesized that neuronal RNA granules contain paused ribosomes with incomplete proteins initiated in the soma before their packaging and transport to dendrites, where translation can be rapidly and locally completed on demand. Here we show that reactivation of translation on stalled polyribosomes is a unique feature of the neuronal landscape that functions in metabotropic glutamate receptor (mGluR) long-term depression (LTD), providing the neuron with the ability to rapidly and specifically respond to stimuli independently of translation initiation.