Alpha-CaMKII-dependent plasticity in the cortex is required for permanent memory

Cortical plasticity seems to be critical for the establishment of permanent memory traces. Little is known, however, about the molecular and cellular processes that support consolidation of memories in cortical networks. Here we show that mice heterozygous for a null mutation of alpha-calcium-calmodulin kinase II (alpha-CaMKII+/-) show normal learning and memory 1-3 days after training in two hippocampus-dependent tasks. However, their memory is severely impaired at longer retention delays (10-50 days). Consistent with this, we found that alpha-CaMKII+/- mice have impaired cortical, but not hippocampal, long-term potentiation. Our results represent a first step in unveiling the molecular and cellular mechanisms underlying the establishment of permanent memories, and they indicate that alpha-CaMKII may modulate the synaptic events required for the consolidation of memory traces in cortical networks.     

离子型谷氨酸受体对海马突触传递长时程增强的影响

海马是完成学习与记忆活动的神经基础,海马部位突触可塑性增强与学习记忆有着密不可分的关系,而这种可塑性的增强主要是以谷氨酸为神经递质的,因此本文就有关海马部位突触可塑性增强与离子型谷氨酸受体的联系进行了阐述．     

Recovery of spatial learning deficits after decay of electrically induced synaptic enhancement in the hippocampus

A widespread interest in a long-lasting form of synaptic enhancement in hippocampal circuits has arisen largely because it might reflect the activation of physiological mechanisms that underlie rapid associative learning. As its induction normally requires the 'Hebbian' association of activity on a number of input fibres, we refer to the process as long-term enhancement (LTE) rather than long-term potentiation (LTP), to emphasize its distinction from the ubiquitous, non-associative 'potentiation' phenomena that occur at most synapses, including those exhibiting LTE. Among other evidence that LTE might actually have a role in associative memory is the demonstration that repeated high-frequency stimulation, which saturated the inducible LTE, caused a severe deficit in spatial learning, although it had no effect on well established spatial memory. These results were consistent with a widespread view that information need only temporarily be stored in the hippocampal formation in order for long-term memories to be established in neocortical circuits. In this context, it is important to understand whether the possible underlying synaptic changes are of a permanent character, or are relatively transient. A second question is whether the actual cause of the observed learning deficit is the distruption of the synaptic weight distribution, and/or the limitation of further synaptic change, which presumably results from experimental saturation of the LTE mechanism. Alternatively, the deficit could be a consequence of some unobserved secondary effect of the high-frequency electrical stimulation. Here we demonstrate that learning capacity recovers in about the same time that it takes LTE to decay, which strongly favours the first possibility and supports the idea that LTE-like processes actually underlie associative memory.     

Fear memories require protein synthesis in the amygdala for reconsolidation after retrieval

'New' memories are initially labile and sensitive to disruption before being consolidated into stable long-term memories. Much evidence indicates that this consolidation involves the synthesis of new proteins in neurons. The lateral and basal nuclei of the amygdala (LBA) are believed to be a site of memory storage in fear learning. Infusion of the protein synthesis inhibitor anisomycin into the LBA shortly after training prevents consolidation of fear memories. Here we show that consolidated fear memories, when reactivated during retrieval, return to a labile state in which infusion of anisomycin shortly after memory reactivation produces amnesia on later tests, regardless of whether reactivation was performed 1 or 14 days after conditioning. The same treatment with anisomycin, in the absence of memory reactivation, left memory intact. Consistent with a time-limited role for protein synthesis production in consolidation, delay of the infusion until six hours after memory reactivation produced no amnesia. Our data show that consolidated fear memories, when reactivated, return to a labile state that requires de novo protein synthesis for reconsolidation. These findings are not predicted by traditional theories of memory consolidation.     

Glutamate-receptor-mediated encoding and retrieval of paired-associate learning

Paired-associate learning is often used to examine episodic memory in humans. Animal models include the recall of food-cache locations by scrub jays and sequential memory. Here we report a model in which rats encode, during successive sample trials, two paired associates (flavours of food and their spatial locations) and display better-than-chance recall of one item when cued by the other. In a first study, pairings of a particular foodstuff and its location were never repeated, so ensuring unique 'what-where' attributes. Blocking N-methyl-d-aspartate receptors in the hippocampus--crucial for the induction of certain forms of activity-dependent synaptic plasticity--impaired memory encoding but had no effect on recall. Inactivating hippocampal neural activity by blocking alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) receptors impaired both encoding and recall. In a second study, two paired associates were trained repeatedly over 8 weeks in new pairs, but blocking of hippocampal AMPA receptors did not affect their recall. Thus we conclude that unique what-where paired associates depend on encoding and retrieval within a hippocampal memory space, with consolidation of the memory traces representing repeated paired associates in circuits elsewhere.     

Presynaptic enhancement shown by whole-cell recordings of long-term potentiation in hippocampal slices

Long-term potentiation (LTP) of synaptic transmission in the hippocampus is a widely studied model system for understanding the cellular mechanisms of memory. In region CA1, LTP is triggered postsynaptically by Ca2(+)-dependent activation of protein kinases, but the locus of persistent modification remains controversial. Statistical analysis of synaptic variability has been proposed as a means of settling this debate, although a major obstacle has been the poor signal-to-noise ratio of conventional intracellular recordings. We have applied the whole-cell voltage clamp technique to study synaptic transmission in conventional hippocampal slices (compare refs 28-30). Here we report that robust LTP can be recorded with much improved signal resolution and biochemical access to the postsynaptic cell. Prolonged dialysis of the postsynaptic cell blocks the triggering of LTP, with no effect on expression of LTP. The improved signal resolution unmasks a large trial-to-trial variability, reflecting the probabilistic nature of transmitter release. Changes in the synaptic variability, and a decrease in the proportion of synaptic failures during LTP, suggest that transmitter release is significantly enhanced.     

RIM1alpha is required for presynaptic long-term potentiation.

Two main forms of long-term potentiation (LTP)-a prominent model for the cellular mechanism of learning and memory-have been distinguished in the mammalian brain. One requires activation of postsynaptic NMDA (N-methyl d-aspartate) receptors, whereas the other, called mossy fibre LTP, has a principal presynaptic component. Mossy fibre LTP is expressed in hippocampal mossy fibre synapses, cerebellar parallel fibre synapses and corticothalamic synapses, where it apparently operates by a mechanism that requires activation of protein kinase A. Thus, presynaptic substrates of protein kinase A are probably essential in mediating this form of long-term synaptic plasticity. Studies of knockout mice have shown that the synaptic vesicle protein Rab3A is required for mossy fibre LTP, but the protein kinase A substrates rabphilin, synapsin I and synapsin II are dispensable. Here we report that mossy fibre LTP in the hippocampus and the cerebellum is abolished in mice lacking RIM1alpha, an active zone protein that binds to Rab3A and that is also a protein kinase A substrate. Our results indicate that the long-term increase in neurotransmitter release during mossy fibre LTP may be mediated by a unitary mechanism that involves the GTP-dependent interaction of Rab3A with RIM1alpha at the interface of synaptic vesicles and the active zone.     

Protein phosphatase 1 is a molecular constraint on learning and memory

Repetition in learning is a prerequisite for the formation of accurate and long-lasting memory. Practice is most effective when widely distributed over time, rather than when closely spaced or massed. But even after efficient learning, most memories dissipate with time unless frequently used. The molecular mechanisms of these time-dependent constraints on learning and memory are unknown. Here we show that protein phosphatase 1 (PP1) determines the efficacy of learning and memory by limiting acquisition and favouring memory decline. When PP1 is genetically inhibited during learning, short intervals between training episodes are sufficient for optimal performance. The enhanced learning correlates with increased phosphorylation of cyclic AMP-dependent response element binding (CREB) protein, of Ca(2+)/calmodulin-dependent protein kinase II (CaMKII) and of the GluR1 subunit of the AMPA receptor; it also correlates with CREB-dependent gene expression that, in control mice, occurs only with widely distributed training. Inhibition of PP1 prolongs memory when induced after learning, suggesting that PP1 also promotes forgetting. This property may account for ageing-related cognitive decay, as old mutant animals had preserved memory. Our findings emphasize the physiological importance of PP1 as a suppressor of learning and memory, and as a potential mediator of cognitive decline during ageing.     

Shaggy/GSK3 antagonizes Hedgehog signalling by regulating Cubitus interruptus

The Drosophila protein Shaggy (Sgg, also known as Zeste-white3, Zw3) and its vertebrate orthologue glycogen synthase kinase 3 (GSK3) are inhibitory components of the Wingless (Wg) and Wnt pathways. Here we show that Sgg is also a negative regulator in the Hedgehog (Hh) pathway. In Drosophila, Hh acts both by blocking the proteolytic processing of full-length Cubitus interruptus, Ci (Ci155), to generate a truncated repressor form (Ci75), and by stimulating the activity of accumulated Ci155 (refs 2-6). Loss of sgg gene function results in a cell-autonomous accumulation of high levels of Ci155 and the ectopic expression of Hh-responsive genes including decapentaplegic (dpp) and wg. Simultaneous removal of sgg and Suppressor of fused, Su(fu), results in wing duplications similar to those caused by ectopic Hh signalling. Ci is phosphorylated by GSK3 after a primed phosphorylation by protein kinase A (PKA), and mutating GSK3-phosphorylation sites in Ci blocks its processing and prevents the production of the repressor form. We propose that Sgg/GSK3 acts in conjunction with PKA to cause hyperphosphorylation of Ci, which targets it for proteolytic processing, and that Hh opposes Ci proteolysis by promoting its dephosphorylation.     

A dual-kinase mechanism for Wnt co-receptor phosphorylation and activation

Signalling by the Wnt family of secreted lipoproteins has essential functions in development and disease. The canonical Wnt/beta-catenin pathway requires a single-span transmembrane receptor, low-density lipoprotein (LDL)-receptor-related protein 6 (LRP6), whose phosphorylation at multiple PPPSP motifs is induced upon stimulation by Wnt and is critical for signal transduction. The kinase responsible for LRP6 phosphorylation has not been identified. Here we provide biochemical and genetic evidence for a 'dual-kinase' mechanism for LRP6 phosphorylation and activation. Glycogen synthase kinase 3 (GSK3), which is known for its inhibitory role in Wnt signalling through the promotion of beta-catenin phosphorylation and degradation, mediates the phosphorylation and activation of LRP6. We show that Wnt induces sequential phosphorylation of LRP6 by GSK3 and casein kinase 1, and this dual phosphorylation promotes the engagement of LRP6 with the scaffolding protein Axin. We show further that a membrane-associated form of GSK3, in contrast with cytosolic GSK3, stimulates Wnt signalling and Xenopus axis duplication. Our results identify two key kinases mediating Wnt co-receptor activation, reveal an unexpected and intricate logic of Wnt/beta-catenin signalling, and illustrate GSK3 as a genuine switch that dictates both on and off states of a pivotal regulatory pathway.     

大鼠在空间辨别性学习记忆时海马CA1,CA3区和DG的ACh能纤维和星形胶质细胞的变化

目的通过建立大鼠空间辨别性学习记忆的动物模型,观察大鼠海马CA1,CA3区和齿状回(DG)的乙酰胆碱(ACh)能纤维密度和含量的变化以及星形胶质细胞的数量及其胶质原纤维酸性蛋白(GFAP)表达的变化,从形态学上探讨中枢ACh和星形胶质细胞与空间辨别性学习记忆的关系.方法建立空间辨别性学习记忆的动物模型,采用乙酰胆碱酯酶(AChE)的组织化学染色及GFAP标记星形胶质细胞.并用显微镜方格目测系统和图像分析仪对大鼠海马CA1,CA3区及DG的GFAP免疫阳性星形胶质细胞的数量及其GFAP表达进行检测.结果模型组与对照组相比大鼠各观察部位的AChE阳性纤维的密度和含量均增高,有显著性差异(P<0.05).而空白组和游水组相比大鼠各观察部位的AChE阳性纤维的密度和含量均无显著性差异(P>0.05),模型组内各组间两两比较大鼠各观察部位的AChE阳性纤维的密度和含量均无显著性差异(P>0.05);模型组与对照组相比大鼠各观察部位的星形胶质细胞的数量及其GFAP的表达均增加,有显著性差异(P<0.05).而空白组和游水组相比大鼠各观察部位的星形胶质细胞的数量及其GFAP的表达均无显著性差异(P>0.05),模型组内各组间两两比较大鼠各观察部位的星形胶质细胞的数量及其GFAP的表达均无显著性差异(P>0.05).结论在空间辨别性学习记忆过程中,大鼠各观察部位的AChE阳性纤维的密度和含量增高,说明中枢ACh参与空间辨别性学习记忆过程;在空间辨别性学习记忆过程中,大鼠各观察部位的星形胶质细胞的数量及其GFAP表达的增加,说明星形胶质细胞参与空间辨别性学习记忆过程.     

即刻早期基因Arc/Arg3.1的表达及其与学习记忆关系概述

Arc/Arg3.1基因为即刻早期基因(Immediate-early genes,IEGs)中的一种,相对于其他作为转录因子的IEGs,Arc/Arg3.1是可以直接作为效应因子的细胞结构元件.Arc/Arg3.1基因在神经元的突触可塑性方面起重要的作用,如果它的蛋白表达受阻则会损坏LTP的维持,从而损坏长期记忆的巩固.就Arc/Arg3.1基因的序列克隆与表达及其与学习记忆之间关系的研究进展进行了阐述.     

Protein kinase C injection into hippocampal pyramidal cells elicits features of long term potentiation

Long-term potentiation (LTP) in the hippocampus is an interesting example of synaptic plasticity because of its induction by physiological discharge rates and its long duration. Of the possible biochemical mechanisms that regulate prolonged changes in cell function, protein phosphorylation is a particularly attractive candidate. We have therefore examined the effect of intracellular injection of calcium/diacylglycerol-dependent protein kinase (protein kinase C (PKC] in CA1 pyramidal neurones in hippocampal slices. Injection of the active enzyme elicited long-lasting enhancement of synaptic transmission, similar to LTP, whereas inactivated kinase failed to do so. The observed changes included an increased amplitude of the excitatory post-synaptic potential (e.p.s.p.) and an increased probability of firing and a reduced latency of the associated actin potential.     

基于双反相二维色谱串联质谱技术的大鼠海马膜蛋白分析

色谱与质谱联用技术在蛋白质组学研究中应用广泛,特别是二维色谱分离技术的发展,为复杂生物样品的分离分析提供了更为精准的技术手段.海马是大脑颞叶内侧的一个重要脑区,主要负责哺乳动物的学习和记忆,实现这些功能的生理过程与海马膜蛋白密切相关,但由于海马膜蛋白具有强疏水性和低丰度的特点,因此在分离和鉴定上难度较高.运用差速离心的方法分离纯化得到成年大鼠的海马膜蛋白,采用双反相二维色谱串联质谱技术进行分离分析.最终鉴定2 502个蛋白,结合生物信息学分析发现,所鉴定到的2 502个蛋白在包含蛋白定位、突触可塑性、蛋白运输以及囊泡转运等在内的与学习记忆功能密切相关的生理过程中均有涉及.这一分析结果为更加全面的揭示海马膜蛋白与脑海马区的特定功能间的具体关系提供了重要的参考.     

Achyranthes bidentata Blume extract promotes neuronal growth in cultured embryonic rat hippocampal neurons

We have prepared an aqueous extract of Achyranthes bidentata Blume, a commonly prescribed Chinese medicinal herb, and reported, in previous studies, that A. bidentata extract benefits nerve growth and prevents neuron apoptosis. In this study, we investigated the actions of A. bidentata extract on survival and growth of primarily cultured rat hippocampal neurons. The morphological observation revealed that neurite growth from hippocampal neurons was significantly enhanced by A. bidentata extract with similar effects to those induced by nerve growth factor (NGF), and the greatest neurite growth appeared on treatment with A. bidentata extract at 1 μg/ml for 24 h. DNA microarray analysis indicated that there were 25 upregulated genes and 47 downregulated genes exhibiting significantly differential expression in hippocampal neurons treated with A. bidentata extract at 1 μg/ml for 6 h when compared to those in untreated hippocampal neurons. Real-time quantitative RT-PCR and Western blot analysis demonstrated that the expression of growth-associated protein-43 in hippocampal neurons was upregulated at both mRNA and protein levels after treatment with A. bidentata extract, and the optimal dosage of the extract was also 1 μg/ml. These data confirm that A. bidentata extract could promote in vitro hippocampal neuronal growth in a dose- and time-dependent manner.     

Role for a cortical input to hippocampal area CA1 in the consolidation of a long-term memory

A dialogue between the hippocampus and the neocortex is thought to underlie the formation, consolidation and retrieval of episodic memories, although the nature of this cortico-hippocampal communication is poorly understood. Using selective electrolytic lesions in rats, here we examined the role of the direct entorhinal projection (temporoammonic, TA) to the hippocampal area CA1 in short-term (24 hours) and long-term (four weeks) spatial memory in the Morris water maze. When short-term memory was examined, both sham- and TA-lesioned animals showed a significant preference for the target quadrant. When re-tested four weeks later, sham-lesioned animals exhibited long-term memory; in contrast, the TA-lesioned animals no longer showed target quadrant preference. Many long-lasting memories require a process called consolidation, which involves the exchange of information between the cortex and hippocampus. The disruption of long-term memory by the TA lesion could reflect a requirement for TA input during either the acquisition or consolidation of long-term memory. To distinguish between these possibilities, we trained animals, verified their spatial memory 24 hours later, and then subjected trained animals to TA lesions. TA-lesioned animals still exhibited a deficit in long-term memory, indicating a disruption of consolidation. Animals in which the TA lesion was delayed by three weeks, however, showed a significant preference for the target quadrant, indicating that the memory had already been adequately consolidated at the time of the delayed lesion. These results indicate that, after learning, ongoing cortical input conveyed by the TA path is required to consolidate long-term spatial memory.     

Neurotrophic regulation of synapse development and plasticity

Neurotrophic factors are traditionally thought to be secretory proteins that regulate long-tern survival and differe, ntiation of neurons. Recent studies have revealed a previously unexpected role for these factors in synaptie de velopment ami plasticity in diverse neuronal populations. Here we review experimeuts carried oul in our own laboratory in the last few years.. We have made two important discoveries.First,we were among the first to report that brain-derived. neurotrophie faclor (BDNF) facilitates hippocampal hmg-term potentiation (LTP), a form of synaptic plaslicity believed to be involved in learning and memory. BDNF modulates LTP al CAI synapses by enhaneing synaptic responses to high frequency, tetanic slimulalion. This is achieved primafily by facilitating synaptie vesicle doeking, possibly due to an in crease in the levels of the vesicle prolein synaptobrevin and synaptoplysin in the nerve terminals. Gene knockout study demonstrates thai the effects of BDNF are primarily mediated through presynaptic mechanisms. Second, we demonstrated a form of long-term, neurotrophin-mediated synaptic regulation. We showed that long-term treatment of the neuromuscu lar synapses with neurotrophin-3 (NT3) resulted in an enhancement of both spontaneous and evoked synaptic currcuts, as well as profound changes in thc number of synaptic varicosities and syuaptic vesicle proteins in motoneurons, all of which are indicative of more mature synapses. Our current work addresses the following issues:(i) activity-dependent trafficking of neurotrophin receptors, and its role in synapse-specific modulation; (ii) signal transduction mechanisms medialing the acute enhancement of synaplic transmission by neurotrophins; (iii) acute and long-tenn synaptie actions of the GDNF family; (iv) role of BDNF in late-phase LTP and in the development of hippocampal circuit.