Impairment of hippocampal long-term depression and defective spatial learning and memory in p35 mice

Cdk5 (cyclin-dependent kinase 5) activity is dependent upon association with one of two neuron-specific activators, p35 or p39. Genetic deletion of Cdk5 causes perinatal lethality with severe defects in corticogenesis and neuronal positioning. p35(-/-) mice are viable with milder histological abnormalities. Although substantial evidence implicates Cdk5 in synaptic plasticity, its role in learning and memory has not been evaluated using mutant mouse models. We report here that p35(-/-) mice have deficiencies in spatial learning and memory. Close examination of hippocampal circuitry revealed subtle histological defects in CA1 pyramidal cells. Furthermore, p35(-/-) mice exhibit impaired long-term depression and depotentiation of long-term potentiation in the Schaeffer collateral CA1 pathway. Moreover, the Cdk5-dependent phosphorylation state of protein phosphatase inhibitor-1 was increased in 4-week-old mice due to increased levels of p39, which co-localized with inhibitor-1 and Cdk5 in the cytoplasm. These results demonstrate that p35-dependent Cdk5 activity is important to learning and synaptic plasticity. Deletion of p35 may shift the substrate specificity of Cdk5 due to compensatory expression of p39.     

Differential involvement of the mu and kappa opioid receptors in spatial learning

In order to test the role of mu and kappa opioid receptors (Mu opioid receptor (MOR) and Kappa opioid receptor (KOR)) in hippocampal-dependent spatial learning, we analyzed genetically engineered null mutant mice missing the functional MOR or KOR gene. Compared to wild-type mice, the homozygous MOR null mutants exhibited an impairment in the ultimate level of spatial learning as shown in two distinct tasks, the 8-arm radial-maze and the Morris water-maze. Control behaviors were normal. The learning impairment could be associated with the impairment we found in the maintenance of long-term potentiation in mossy fibers in CA3. In comparison, there was no impairment in spatial learning in our KOR mutants or in mossy fibers (mf) in CA3 region long-term potentiation (LTP). Our work suggests that the MOR may play a positive role in learning and memory by increasing LTP in CA3 neurons.     

Improved spatial learning is associated with increased hippocampal but not prefrontal long‐term potentiation in mGluR4 knockout mice

Although much information about metabotropic glutamate receptors (mGluRs) and their role in normal and pathologic brain function has been accumulated during the last decades, the role of group III mGluRs is still scarcely documented. Here, we examined mGluR4 knockout mice for types of behavior and synaptic plasticity that depend on either the hippocampus or the prefrontal cortex (PFC). We found improved spatial short‐ and long‐term memory in the radial arm maze, which was accompanied by enhanced long‐term potentiation (LTP) in hippocampal CA1 region. In contrast, LTP in the PFC was unchanged when compared with wild‐type controls. Changes in paired‐pulse facilitation that became overt in the presence of the GABA_A antagonist picrotoxin indicated a function of mGluR4 in maintaining the excitation/inhibition balance, which is of crucial importance for information processing in the brain and the deterioration of these processes in neuropsychological disorders such as autism, epilepsy and schizophrenia .     

α8‐Integrins are required for hippocampal long‐term potentiation but not for hippocampal‐dependent learning

Integrins are heterodimeric transmembrane cell adhesion receptors that are essential for a wide range of biological functions via cell–matrix and cell–cell interactions. Recent studies have provided evidence that some of the subunits in the integrin family are involved in synaptic and behavioral plasticity. To further understand the role of integrins in the mammalian central nervous system, we generated a postnatal forebrain and excitatory neuron‐specific knockout of α8‐integrin in the mouse. Behavioral studies showed that the mutant mice are normal in multiple hippocampal‐dependent learning tasks, including a T‐maze, non‐match‐to‐place working memory task for which other integrin subunits like α3‐ and β1‐integrin are required. In contrast, mice mutant for α8‐integrin exhibited a specific impairment of long‐term potentiation (LTP) at Schaffer collateral–CA1 synapses, whereas basal synaptic transmission, paired‐pulse facilitation and long‐term depression (LTD) remained unaffected. Because LTP is also impaired in the absence of α3‐integrin, our results indicate that multiple integrin molecules are required for the normal expression of LTP, and different integrins display distinct roles in behavioral and neurophysiological processes like synaptic plasticity.     

The function of GluR1 and GluR2 in cerebellar and hippocampal LTP and LTD is regulated by interplay of phosphorylation and O‐GlcNAc modification

Long‐term potentiation (LTP) and long‐term depression (LTD) are the current models of synaptic plasticity and widely believed to explain how different kinds of memory are stored in different brain regions. Induction of LTP and LTD in different regions of brain undoubtedly involve trafficking of AMPA receptor to and from synapses. Hippocampal LTP involves phosphorylation of GluR1 subunit of AMPA receptor and its delivery to synapse whereas; LTD is the result of dephosphorylation and endocytosis of GluR1 containing AMPA receptor. Conversely the cerebellar LTD is maintained by the phosphorylation of GluR2 which promotes receptor endocytosis while dephosphorylation of GluR2 triggers receptor expression at the cell surface and results in LTP. The interplay of phosphorylation and O‐GlcNAc modification is known as functional switch in many neuronal proteins. In this study it is hypothesized that a same phenomenon underlies as LTD and LTP switching, by predicting the potential of different Ser/Thr residues for phosphorylation, O‐GlcNAc modification and their possible interplay. We suggest the involvement of O‐GlcNAc modification of dephosphorylated GluR1 in maintaining the hippocampal LTD and that of dephosphorylated GluR2 in cerebral LTP. J. Cell. Biochem. 109: 585–597, 2010. © 2010 Wiley‐Liss, Inc.     

低频刺激后海马CA1区场兴奋性突触后电位与群体锋电位的变化

在大鼠海马脑片上使用双电极在CA1区进行细胞外记录 ,观察低频刺激 (LFS)诱发同突触长时程抑制 (LTD)时场兴奋性突触后电位 (fEPSP)的斜率 (S EPSP)和群体锋电位 (PS)的幅值 (A PS)的变化。给予 90 0脉冲 1HzLFS后 ,S EPSP和A PS降低的幅度分别是 35 4± 5 3%和 6 8 0± 7 2 % ;而给予 4 5 0脉冲 1HzLFS后 ,S EPSP和A PS分别降低 14 3± 2 3%和 36 8± 6 7%。上述两组中A PS的变化率均显著大于S EPSP (P <0 0 1) ,而 90 0脉冲数组中两个指标的变化率均大于 4 5 0脉冲数组 (P <0 0 5 )。高Mg2 + (4mmol/L)使突触的传递活动减弱 ,但不影响LTD的诱发 ,在高Mg2 + 介质中 ,LFS引起的A PS变化率仍显著大于S EPSP (P <0 0 1)。结果表明 ,由LFS诱发同突触LTD的水平不仅与LFS的脉冲数有关 ,还与评价指标的选择有关     

葛根素对血管性痴呆大鼠海马突触传递长时程增强的影响

目的：探讨葛根素对血管性痴呆大鼠长时程增强（LTP）的影响。方法：采用Morris水迷宫和LTP诱导法检测血管性痴呆模型大鼠空间学习记忆能力和海马突触传递的改变。结果：模型组大鼠不同时间点测得的Morris水迷宫逃逸潜伏期均较假手术组明显延长,海马LTP诱导率明显降低,而药物组大鼠EL均短于模型组,但LTP诱导率明显增强。结论：葛根素可增强血管性痴呆大鼠突触传递功能,改善其长期存在的学习记忆障碍。     

小鼠动物实验方法系列专题(一)——Morris水迷宫实验在小鼠表型分析中的应用

本文以C57和129Sv小鼠为例介绍了Morris水迷宫实验的基本原理和实验步骤。该实验是研究鼠类空间学习记忆功能的重要实验:通过连续多日训练鼠类以水池壁的标记物进行定位导航游泳寻找水中隐藏平台的方法检测小鼠的空间学习能力;接着撤除平台,分析小鼠在水迷宫里搜索原隐藏平台的行为来检测小鼠的空间记忆功能。结果发现,两种小鼠均可成功完成实验,C57综合表现优于129Sv小鼠。Morris水迷宫是对小鼠空间学习和记忆功能研究的重要工具。     

褪黑素对大鼠空间学习记忆的影响及其机制研究

本研究运用Morris水迷宫和电生理学方法 ,以逃避潜伏期、穿环系数和海马CA1区突触长时程增强(long termpotentiation ,LTP)为指标 ,研究褪黑素对大鼠空间学习记忆能力的影响。实验结果显示 :( 1)在Morris水迷宫 6d训练中 ,对照组大鼠后 4d平均逃避潜伏期为 18 4 4± 2 7s,褪黑素组为 3 0 0 2± 3 6s,两者有显著差异 (P <0 0 1) ;训练 6d后 ,褪黑素组穿环系数为 2 5 68± 2 3 2 % ,明显小于对照组的 4 3 3 3± 2 85 % (P <0 0 1)。( 2 )采用微量注射法给予海马CA1区褪黑素 ,强直后 60min ,fEPSP斜率为基准值的 114 2 8± 1 80 % ,显著低于对照组的 169 71±6 4 8% (P <0 0 1)。( 3 )预先给予东莨菪碱 ,不影响褪黑素对海马CA1区LTP的抑制 ,强直后 60minfEPSP斜率为基准值的 113 70± 5 5 5 %。( 4 )提前给予荷包牡丹碱后给予褪黑素 ,强直后 60minfEPSP斜率为基准值的 162 2 9±10 5 2 % ,明显大于褪黑素组 (P <0 0 1) ,而与对照组无显著差异 (P >0 0 5 )。上述结果表明 ,褪黑素对大鼠的空间学习记忆能力及海马CA1区LTP均有明显的抑制作用 ,两者相关 ;东莨菪碱不能阻断褪黑素对海马CA1区LTP的抑制作用 ,而荷包牡丹碱可以阻断褪黑素对LTP的抑制 ,提示褪黑素的作用可能不是由胆碱能系统所介     

Activation of PAF-synthesizing enzymes in rat brain stem slices after LTP induction in the medial vestibular nuclei

LysoPAF acetyltransferase (lysoPAF-AT) and PAF-synthesizing phosphocholinetransferase (PAF-PCT) are the two enzymes which catalyze the final reactions for the synthesis of PAF. Their activities, assayed in the homogenate of rat brain stem slices and under their optimal conditions, increased 5 min after high frequency stimulation of vestibular afferents, inducing LTP in the medial vestibular nuclei. The activity of phosphatidylcholine-synthesizing phosphocholinetransferase, was not affected. Sixty minutes from the induction of LTP, PAF-PCT activity, but not that of lysoPAF-AT, was still significantly higher with respect to 5 min test stimulated control. We used AP-5 to verify whether this increase was strictly dependent upon LTP induction, which requires NMDA receptor activation. In AP-5 treated slices, lysoPAF-acetyltransferase and PAF-synthesizing phosphocholinetransferase activities increased, but they were reduced after high frequency stimulation under AP-5. In conclusion, we have demonstrated that the activities of PAF-synthesizing enzymes are activated soon after the induction of LTP and that this effect is linked to the activation of NMDA-receptors. We suggest that the enzyme activation by AP-5, preventing LTP, might be due to glutamate enhancement but, in neurons showing LTP and under normal conditions, the activation of potentiation mechanisms is critical for the enhancement of enzyme activities.     

Zinc-triggered induction of tissue plasminogen activator by brain-derived neurotrophic factor and metalloproteinases

Tissue plasminogen activator (tPA) is necessary for hippocampal long-term potentiation. Synaptically released zinc also contributes to long-term potentiation, especially in the hippocampal CA3 region. Using cortical cultures, we examined whether zinc increased the concentration and/or activity of tPA. Two hours after a 10-min exposure to 300 μM zinc, expression of tPA and its substrate, plasminogen, were significantly increased, as was the proteolytic activity of tPA. In contrast, increasing extracellular or intracellular calcium levels did not affect the expression or secretion of tPA. Changing zinc influx or chelating intracellular zinc also failed to alter tPA/plasminogen induction by zinc, indicating that zinc acts extracellularly. Zinc-mediated extracellular activation of matrix metalloproteinase (MMP) underlies the up-regulation of brain-derived neurotrophic factor (BDNF) and tropomyosin receptor kinase (Trk) signaling. Consistent with these findings, co-treatment with a neutralizing antibody against BDNF or specific inhibitors of MMPs or Trk largely reversed tPA/plasminogen induction by zinc. Treatment of cortical cultures with p-aminophenylmercuric acetate, an MMP activator, MMP-2, or BDNF alone induced tPA/plasminogen expression. BDNF mRNA and protein expression was also increased by zinc and mediated by MMPs. Thus, an extracellular zinc-dependent, MMP- and BDNF-mediated synaptic mechanism may regulate the levels and activity of tPA.     

Protease‐activated receptor‐1 modulates hippocampal memory formation and synaptic plasticity

Protease‐activated receptor‐1 (PAR1) is an unusual G‐protein coupled receptor (GPCR) that is activated through proteolytic cleavage by extracellular serine proteases. Although previous work has shown that inhibiting PAR1 activation is neuroprotective in models of ischemia, traumatic injury, and neurotoxicity, surprisingly little is known about PAR1's contribution to normal brain function. Here, we used PAR1?/? mice to investigate the contribution of PAR1 function to memory formation and synaptic function. We demonstrate that PAR1?/? mice have deficits in hippocampus‐dependent memory. We also show that while PAR1?/? mice have normal baseline synaptic transmission at Schaffer collateral‐CA1 synapses, they exhibit severe deficits in N‐methyl‐d ‐aspartate receptor (NMDAR)‐dependent long‐term potentiation (LTP). Mounting evidence indicates that activation of PAR1 leads to potentiation of NMDAR‐mediated responses in CA1 pyramidal cells. Taken together, this evidence and our data suggest an important role for PAR1 function in NMDAR‐dependent processes subserving memory formation and synaptic plasticity.     

视皮层LTP维持阶段的突触形态计量学研究

本实验使用１８～２０ｄ的幼年大鼠视皮层脑片标本,在ＬＴＰ出现后３ｈ取局部微脑片固定进行ＬＴＰ维持阶段超微结构的研究。分别与孵育相同时间而未予任何刺激的脑片和仅给予测试刺激的脑片作比较。运用图像分析仪分别对三组电镜结果进行以下参数的测量：（１）突触间隙的宽度;（２）突触后致密物（ＰＳＤ）的厚度;（３）活性区的长度;和（４）突触界面曲率。用双盲法对突触数目进行计量,并用立体计量学方法对各种突触类型进行定量,所得数据用方差分析进行统计学处理。结果显示：（１）ＬＴＰ形成后１５ｈ左右,其反应达到峰值,然后维持在最高水平一直到３ｈ仍无下降趋势;（２）突触间隙的宽度较两个对照组明显增宽;（３）ＰＳＤ的厚度也明显增厚;（４）活性区的面密度及突触界面曲率明显增加;（５）总突触数目和棘突触数目的数密度较空白对照明显增高;（６）穿孔性突触的数密度与对照组相比明显增加。结果提示：活性区面密度的增加及突触界面曲率的增大可能是ＬＴＰ维持的形态学基础。穿孔性突触的形成与ＬＴＰ的维持密切相关。     

Chelation of hippocampal zinc enhances long‐term potentiation and synaptic tagging/capture in CA1 pyramidal neurons of aged rats: implications to aging and memory

Aging is associated with decline in cognitive functions, prominently in the memory consolidation and association capabilities. Hippocampus plays a crucial role in the formation and maintenance of long‐term associative memories, and a significant body of evidence shows that impairments in hippocampal function correlate with aging‐related memory loss. A number of studies have implicated alterations in hippocampal synaptic plasticity, such as long‐term potentiation (LTP), in age‐related cognitive decline although exact mechanisms underlying are not completely clear. Zinc deficiency and the resultant adverse effects on cognition have been well studied. However, the role of excess of zinc in synaptic plasticity, especially in aging, is not addressed well. Here, we have investigated the hippocampal zinc levels and the impairments in synaptic plasticity, such as LTP and synaptic tagging and capture (STC), in the CA1 region of acute hippocampal slices from 82‐ to 84‐week‐old male Wistar rats. We report increased zinc levels in the hippocampus of aged rats and also deficits in the tetani‐induced and dopaminergic agonist‐induced late‐LTP and STC. The observed deficits in synaptic plasticity were restored upon chelation of zinc using a cell‐permeable chelator. These data suggest that functional plasticity and associativity can be successfully established in aged neural networks by chelating zinc with cell‐permeable chelating agents.     

SRC3 acetylates calmodulin in the mouse brain to regulate synaptic plasticity and fear learning

Protein acetylation is a reversible posttranslational modification, which is regulated by lysine acetyltransferase (KAT) and lysine deacetyltransferase (KDAC). Although protein acetylation has been shown to regulate synaptic plasticity, this was mainly for histone protein acetylation. The function and regulation of nonhistone protein acetylation in synaptic plasticity and learning remain largely unknown. Calmodulin (CaM), a ubiquitous Ca²⁺ sensor, plays critical roles in synaptic plasticity such as long-term potentiation (LTP). During LTP induction, activation of NMDA receptor triggers Ca²⁺ influx, and the Ca²⁺ binds with CaM and activates calcium/calmodulin-dependent protein kinase IIα (CaMKIIα). In our previous study, we demonstrated that acetylation of CaM was important for synaptic plasticity and fear learning in mice. However, the KAT responsible for CaM acetylation is currently unknown. Here, following an HEK293 cell-based screen of candidate KATs, steroid receptor coactivator 3 (SRC3) is identified as the most active KAT for CaM. We further demonstrate that SRC3 interacts with and acetylates CaM in a Ca²⁺ and NMDA receptor-dependent manner. We also show that pharmacological inhibition or genetic downregulation of SRC3 impairs CaM acetylation, synaptic plasticity, and contextual fear learning in mice. Moreover, the effects of SRC3 inhibition on synaptic plasticity and fear learning could be rescued by 3KQ-CaM, a mutant form of CaM, which mimics acetylation. Together, these observations demonstrate that SRC3 acetylates CaM and regulates synaptic plasticity and learning in mice.