Dendritic spines elongate after stimulation of group 1 metabotropic glutamate receptors in cultured hippocampal neurons

Changes in the morphology of dendritic spines are correlated with synaptic plasticity and may relate mechanistically to its expression and stabilization. Recent work has shown that spine length can be altered by manipulations that affect intracellular calcium, and spine length is abnormal in genetic conditions affecting protein synthesis in neurons. We have investigated how ligands of group 1 metabotropic glutamate receptors (mGluRs) affect spine shape; stimulation of these receptors leads both to calcium release from intracellular stores and to dendritic protein synthesis. Thirty-minute incubation of cultured hippocampal slices and dissociated neurons with the selective group 1 mGluR agonist (S)-3,5-dihydroxyphenylglycine (DHPG) induced a significant increase in the average length of dendritic spines. This elongation resulted mainly from the growth of existing spines and was also seen even in the presence of antagonists of ionotropic receptors, indicating that activation of these receptors by mGluR-induced glutamate release was not required. Prolonged antagonism of group 1 mGluRs with (S)-alpha-methyl-4-carboxyphenylglycine (MCPG) did not result in shorter average spine length. Elongation of dendritic spines induced by DHPG was blocked by calcium chelation and by preincubation with the protein synthesis inhibitor puromycin. The results suggest that in vivo activation of group 1 mGluRs by synaptically released glutamate affects spine shape in a protein synthesis-dependent manner.     

Acute effects of ethanol on kainate receptors in cultured hippocampal neurons

BACKGROUND: Kainate receptors are a subclass of ionotropic glutamate receptors that regulate excitability and mediate synaptic transmission and plasticity in the hippocampus. The acute effects of ethanol on these receptors are not completely understood. METHODS: The acute effects of ethanol on pharmacologically isolated kainate receptor-mediated currents were studied in cultured hippocampal neurons obtained from neonatal rats. Whole-cell patch-clamp electrophysiological techniques were used for these studies. LY303070 (GYKI-53784), a potent AMPA (alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid) receptor-selective noncompetitive antagonist, was used to isolate kainate currents. RESULTS: Kainate receptor-mediated currents corresponded to 7% of the total non-N-methyl-D-aspartate (non-NMDA) currents in these neurons and were reduced to 24% of control values in the presence of 15 microM lanthanum. These kainate receptor-mediated currents were significantly inhibited by ethanol concentrations of 50 mM or more. Under our recording conditions, ethanol inhibited non-NMDA receptor- and NMDA receptor-mediated currents to a similar extent as kainate receptor-mediated currents. Western blot analysis indicated that glutamate receptor-5 and -6/7 subunits, and kainic acid-2 subunits are expressed in these cultured hippocampal neurons. CONCLUSIONS: The present results suggest that kainate receptors are important targets for the actions of ethanol in the central nervous system.     

大麻素受体在海马CA1区锥体神经元的功能表达

目的观察大麻素受体在孤立的海马CA1区锥体神经元的功能表达。方法将出生15~20d的Wistar大鼠取脑,急性分离出单个CA1区锥体神经元,用膜片钳技术记录神经元电活动,观察非选择性大麻素受体激动剂Win55212-2(5μmol/L)对神经元静息电位、动作电位、自发发放频率的影响。根据Win55212-2对膜电位的影响分为超极化组(n=7)和去极化组(n=6)。组织切片活性用MTT染色法检测。结果与给药前比较,超极化组神经元给药中动作电位频率和膜电压显著降低[0Hz vs(4.3±3.2)Hz,P0.05;(-57.0±4.6)mVvs(-54.1±3.8)mV,P0.01];与给药中比较,给药后动作电位频率及膜电压显著升高,差异有统计学意义(P0.01)。与给药前比较,去极化组神经元给药中动作电位频率显著降低,膜电压显著升高(P0.01);与给药中比较,给药后动作电位频率显著升高,膜电压显著降低,差异有统计学意义(P0.05)。结论 CA1区锥体神经元可能存在大麻素受体功能表达且不限于大麻素受体1;激活大麻素受体可能通过不同的机制起到抑制CA1区锥体神经元的作用。     

Synaptophysin regulates activity-dependent synapse formation in cultured hippocampal neurons.

Synaptophysin is an abundant synaptic vesicle protein without a definite synaptic function. Here, we examined a role for synaptophysin in synapse formation in mixed genotype micro-island cultures of wild-type and synaptophysin-mutant hippocampal neurons. We show that synaptophysin-mutant synapses are poor donors of presynaptic terminals in the presence of competing wild-type inputs. In homogenotypic cultures, however, mutant neurons display no apparent deficits in synapse formation compared with wild-type neurons. The reduced extent of synaptophysin-mutant synapse formation relative to wild-type synapses in mixed genotype cultures is attenuated by blockers of synaptic transmission. Our findings indicate that synaptophysin plays a previously unsuspected role in regulating activity-dependent synapse formation.     

Origin of variability in quantal size in cultured hippocampal neurons and hippocampal slices.

The size of synaptic quanta has been found to display considerable variation in cultured hippocampal neurons, but the source of this variability was previously unknown. We have now compared the properties of locally evoked miniature excitatory postsynaptic currents in cultured hippocampal neurons and in thin hippocampal slices using whole-cell patch-clamp recordings. The variability in miniature excitatory postsynaptic current size was similar in both preparations and occurred in cultured neurons when only one or a few synaptic boutons were stimulated. Thus, the variability in miniature excitatory postsynaptic current amplitude is not an artifact of cultured neurons and arises predominantly from variability within a single bouton. Possible origins of this variability are discussed.     

Rapid desensitization of glutamate receptors in vertebrate central neurons.

We have examined glutamate receptor desensitization in voltage-clamped embryonic chicken spinal cord neurons and postnatal rat hippocampal neurons maintained in culture. Rapid currents that rose in 0.8-3.6 msec were evoked when glutamate was ionophoresed with 0.5- to 1.0-msec pulses. With prolonged pulses or brief, repetitive pulses, glutamate-evoked currents decayed rapidly in a manner that was independent of holding potential. A similar desensitization occurred following close-range pressure ejection of glutamate. The rapid, desensitizing glutamate current exhibited a linear current-voltage relation and it was not blocked by 2-amino-5-phosphonovalerate, suggesting that it was mediated by N-methyl-D-aspartate-insensitive (G2) receptors. Desensitization of G2 receptors may be agonist-dependent: currents evoked by kainate, a selective G2 agonist, did not decay, whereas prior application of glutamate did reduce the size of kainate responses. The appearance of the rapid current depended critically on the position of the ionophoretic pipette. Such glutamate-receptor "hot spots" often corresponded to points of contact with neighboring neurites, which raises the possibility that they are located at synapses.     

Rapid desensitization of glutamate receptors in vertebrate central neurons.

We have examined glutamate receptor desensitization in voltage-clamped embryonic chicken spinal cord neurons and postnatal rat hippocampal neurons maintained in culture. Rapid currents that rose in 0.8-3.6 msec were evoked when glutamate was ionophoresed with 0.5- to 1.0-msec pulses. With prolonged pulses or brief, repetitive pulses, glutamate-evoked currents decayed rapidly in a manner that was independent of holding potential. A similar desensitization occurred following close-range pressure ejection of glutamate. The rapid, desensitizing glutamate current exhibited a linear current-voltage relation and it was not blocked by 2-amino-5-phosphonovalerate, suggesting that it was mediated by N-methyl-D-aspartate-insensitive (G2) receptors. Desensitization of G2 receptors may be agonist-dependent: currents evoked by kainate, a selective G2 agonist, did not decay, whereas prior application of glutamate did reduce the size of kainate responses. The appearance of the rapid current depended critically on the position of the ionophoretic pipette. Such glutamate-receptor "hot spots" often corresponded to points of contact with neighboring neurites, which raises the possibility that they are located at synapses.     

A glutamate receptor regulates Ca2+ mobilization in hippocampal neurons.

We investigated the effect of various excitatory amino acids on intracellular free Ca2+ concentration ( [Ca2+]i) in single mouse hippocampal neurons in vitro by using the Ca2+-sensitive dye fura-2. In normal physiological solution, glutamate, kainate, N-methyl-D-aspartate, and quisqualate all produced increases in [Ca2+]i. When all extracellular Ca2+ was removed, kainate and N-methyl-D-aspartate were completely ineffective, but quisqualate and glutamate were able to produce a spike-like Ca2+ transient, presumably reflecting the release of Ca2+ from intracellular stores. Ca2+ transients of similar shape could also be produced by the alpha 1-adrenergic agonist phenylephrine. After the production of a Ca2+ transient a second addition of quisqualate was ineffective unless intracellular stores were refilled by loading the cell with Ca2+ following depolarization in Ca2+-containing medium. None of the conventional excitatory amino acid receptor antagonists inhibited the Ca2+-mobilizing effects of quisqualate. Furthermore alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) was unable to produce Ca2+ mobilization in Ca2+-free medium, although it could produce Ca2+ influx in Ca2+-containing medium. Thus, glutamate can produce mobilization of Ca2+ from intracellular stores in hippocampal neurons by acting on a quisqualate-sensitive but AMPA-insensitive receptor. This receptor is therefore distinct from the quisqualate receptor that produces cell depolarization. The possibility that this Ca2+-mobilizing effect is mediated by inositol triphosphate production is discussed.     

Depolarizing stimuli regulate nerve growth factor gene expression in cultured hippocampal neurons.

Although trophic factors and neuronal activity have been implicated in regulating functional synaptic circuits, the relationship of trophic interaction to impulse activity in synaptogenesis remains unclear. Using cultured hippocampus as a model system, we provide direct evidence that depolarization and impulse activity specifically increase nerve growth factor gene expression in neurons. Depolarizing stimuli, such as a high K+ concentration or the Na+ channel agonist veratridine, elicited a 3-fold increase of nerve growth factor mRNA levels in both explant and dissociated cultures. Blockade of depolarization by tetrodotoxin prevented the increase of neuronal nerve growth factor mRNA. Further, nerve growth factor gene expression was stimulated by picrotoxin, a gamma-aminobutyric acid antagonist frequently used to enhance hippocampal neuronal activity. Impulse regulation of trophic gene function may be relevant to developmental synaptogenesis and synaptic strengthening in learning and memory.     

Progesterone prevents estradiol-induced dendritic spine formation in cultured hippocampal neurons

Estradiol has been shown to cause an increase in dendritic spine density in cultured hippocampal neurons, an effect mediated by downregulation of brain-derived neurotrophic factor (BDNF) and glutamic acid decarboxylase (GAD), and the subsequent phosphorylation of cAMP response element binding protein (CREB) in response to enhanced activity levels. Interestingly, progesterone was shown to counteract the effects of estradiol on dendritic spine density in vivo and in vitro. The present study examined how progesterone may act to block the effects of estradiol in the molecular cascade of cellular events leading to formation of dendritic spines. Progesterone did not affect the estradiol-induced downregulation of BDNF or GAD, but it did block the effect of estradiol on CREB phosphorylation. The latter effects of progesterone on the pCREB response and spine formation were reversed by indomethacin, which prevents the conversion of progesterone to the neurosteroid tetrahydroprogesterone (THP). We therefore examined if the progesterone effects were caused by its active metabolite THP. Progesterone treatment caused a 60-fold increase in THP in the culture medium. THP itself enhanced spontaneous GABAergic activity in patch-clamped cultured neurons. Finally, THP blocked the estradiol-induced increase in spine density. These results suggest that progesterone, through conversion to THP, blocks the effects of estradiol on dendritic spines not via a direct nuclear receptor interaction but by counteracting the enhanced excitability produced by estradiol in the cultured network.     

Glucocorticoids inhibit glucose transport in cultured hippocampal neurons and glia

A classical action of glucocorticoids (GCs) is to inhibit glucose uptake into various peripheral tissues. Two recent reports suggest that GCs do the same in the brain. Because of the in vivo nature of those studies, it was impossible to determine whether this inhibition occurred at the blood-brain barrier, and/or within neurons and glia themselves. In order to answer this and other mechanistic questions, we examined the effects of GCs on glucose transport in primary brain cultures. We established that uptake of 14C-2-deoxyglucose into hippocampal cultures was linear over a 15-min period and was inhibited by D-glucose and the uptake inhibitor cytochalasin B. Using this system, we found the following. (1) Both corticosterone and dexamethasone inhibited uptake into cultures containing both neurons and glia. (2) The effect was dose-dependent; steroid concentrations in the nanomolar range inhibited uptake from 20 to 33%. The effect was time-dependent, with more than 4 h of steroid exposure needed for inhibition. (3) Non-GC steroids did not inhibit uptake. (4) The GC inhibition seemed to be mediated by the type II (glucocorticoid) corticosteroid receptor. The effect was blocked by a type II, but not a type I (mineralocorticoid) receptor antagonist. Moreover, corticosterone inhibited only at concentrations well above the Kd for the type I receptor. Finally, aldosterone inhibited transport when applied at concentrations that bound heavily to type II receptors. (5) Corticosterone did not inhibit uptake in hypothalamic, cerebellar or cortical cultures, despite the presence of corticosteroid receptors in these cultures. (6) GCs inhibited uptake in both neuron- and glia-enriched hippocampal cultures.     

Single-channel currents trigger action potentials in small cultured hippocampal neurons.

Spontaneous neuronal impulse activity appears toplay a key role in some neural processes, such as the normal establishment ofinterneuronal connections during development. In addition, spontaneous impulsesmay be essential for the functional operation of neuronal networks. Mechanismsof spontaneous non-pacemaker impulse generation are, however, not well known. Inthis work, spontaneous electrical activity in small cultured hippocampal neuronsfrom rat was studied with tight-seal recording techniques. The resultsdemonstrate that spontaneous individual openings of single ion channels cantrigger impulse generation in these high-resistance cells. First, impulsesrecorded in the whole-cell mode were apparently induced by spontaneousplateau-potential events showing the characteristics expected from individualopenings and closures of ion channels. Second, patch-clamp recordings in thecell-attached configuration showed that openings of single ion channels in thepatch membrane could trigger cellular impulses, detected as biphasic currentdeflections. These findings suggest that the random gating of ion channelmolecules can be used as a mechanism for stochastic triggering of spontaneousimpulses in mammalian central neurons.     

Bcl-xL induces Drp1-dependent synapse formation in cultured hippocampal neurons

Maturation of neuronal synapses is thought to involve mitochondria. Bcl-x_L protein inhibits mitochondria-mediated apoptosis but may have other functions in healthy adult neurons in which Bcl-x_L is abundant. Here, we report that overexpression of Bcl-x_L postsynaptically increases frequency and amplitude of spontaneous miniature synaptic currents in rat hippocampal neurons in culture. Bcl-x_L, overexpressed either pre or postsynaptically, increases synapse number, the number and size of synaptic vesicle clusters, and mitochondrial localization to vesicle clusters and synapses, likely accounting for the changes in miniature synaptic currents. Conversely, knockdown of Bcl-x_L or inhibiting it with ABT-737 decreases these morphological parameters. The mitochondrial fission protein, dynamin-related protein 1 (Drp1), is a GTPase known to localize to synapses and affect synaptic function and structure. The effects of Bcl-x_L appear mediated through Drp1 because overexpression of Drp1 increases synaptic markers, and overexpression of the dominant-negative dnDrp1-K38A decreases them. Furthermore, Bcl-x_L coimmunoprecipitates with Drp1 in tissue lysates, and in a recombinant system, Bcl-x_L protein stimulates GTPase activity of Drp1. These findings suggest that Bcl-x_L positively regulates Drp1 to alter mitochondrial function in a manner that stimulates synapse formation.     

Nitric oxide down-regulates brain-derived neurotrophic factor secretion in cultured hippocampal neurons

The regulation of neurotrophin (NT) secretion is critical for many aspects of NT-mediated neuronal plasticity. Neurons release NTs by activity-regulated secretion pathways, initiated either by neurotransmitters and/or by existing NTs by a positive-feedback mechanism. This process depends on calcium release from intracellular stores. Little is known, however, about potential pathways that down-regulate NT secretion. Here we demonstrate that nitric oxide (NO) induces a rapid down-regulation of brain-derived neurotrophic factor (BDNF) secretion in cultured hippocampal neurons. Similar effects occur by activating a downstream target of intracellular NO, the soluble guanylyl cyclase, or by increasing the levels of its product, cGMP. Furthermore, down-regulation of BDNF secretion is mediated by cGMP-activated protein kinase G, which prevents calcium release from inositol 1,4,5-trisphosphate-sensitive stores. Our data indicate that the NO/cGMP/protein kinase G pathway represents a signaling mechanism by which neurons can rapidly down-regulate BDNF secretion and suggest that, in hippocampal neurons, NT secretion is finely tuned by both stimulatory and inhibitory signals.     

Acetylcholine raises excitability by inhibiting the fast transient potassium current in cultured hippocampal neurons.

The effects of acetylcholine on cultured hippocampal neurons were investigated by using the whole-cell version of the patch-clamp technique. The CA1 region of the hippocampus was excised from brain slices of young rats (12-19 day old), incubated in a papain solution, and dissociated. Neurons were plated on a glial feeder layer. The experiments were conducted mostly on neurons cultured for 2-6 days. Upon depolarization under voltage clamp, these cells exhibited a fast transient outward current (A-current), which was inhibited by 4-aminopyridine (2.5 mM). Acetylcholine (0.1 microM) also inhibited this A-current, as did the muscarinic agonists bethanechol and muscarine. As expected from their inhibition of the A-current, acetylcholine and 4-aminopyridine both increased the amplitude of the action potential and prolonged its duration. We conclude that the inhibition of the A-current constitutes a mechanism by which acetylcholine exerts its excitatory influence on hippocampal neurons.     

Functional significance of axonal Kv7 channels in hippocampal pyramidal neurons

Members of the Kv7 family (Kv7.2-Kv7.5) generate a subthreshold K(+) current, the M- current. This regulates the excitability of many peripheral and central neurons. Recent evidence shows that Kv7.2 and Kv7.3 subunits are targeted to the axon initial segment of hippocampal neurons by association with ankyrin G. Further, spontaneous mutations in these subunits that impair axonal targeting cause human neonatal epilepsy. However, the precise functional significance of their axonal location is unknown. Using electrophysiological techniques together with a peptide that selectively disrupts axonal Kv7 targeting (ankyrin G-binding peptide, or ABP) and other pharmacological tools, we show that axonal Kv7 channels are critically and uniquely required for determining the inherent spontaneous firing of hippocampal CA1 pyramids, independently of alterations in synaptic activity. This action was primarily because of modulation of action potential threshold and resting membrane potential (RMP), amplified by control of intrinsic axosomatic membrane properties. Computer simulations verified these data when the axonal Kv7 density was three to five times that at the soma. The increased firing caused by axosomatic Kv7 channel block backpropagated into distal dendrites affecting their activity, despite these structures having fewer functional Kv7 channels. These results indicate that axonal Kv7 channels, by controlling axonal RMP and action potential threshold, are fundamental for regulating the inherent firing properties of CA1 hippocampal neurons.     

Regulation of hippocampal glutamate receptors: evidence for the involvement of a calcium-activated protease.

Specific [3H]glutamate binding to rat hippocampal membranes and the calcium-induced increase in this binding are markedly temperature-sensitive and are inhibited by alkylating or reducing agents as well as by various protease inhibitors. N-Ethylmaleimide, chloromethyl ketone derivatives of lysine and phenylalanine, and tosylarginine methyl ester decrease the maximum number of [3H]glutamate binding sites without changing their affinity for glutamate. Preincubation of the membranes with glutamate does not protect the glutamate "receptors" from the suppressive effects of these agents. The proteases trypsin and alpha-chymotrypsin increase the maximum number of [3H]glutamate binding sites. The effects of calcium on glutamate binding are different across brain regions. Cerebellar membranes are almost insensitive whereas hippocampal and striatal membranes exhibit a strong increase in the number of binding sites after exposure to even low concentrations of calcium. These results suggest that an endogenous membrane-associated thiol protease regulates the number of [3H]glutamate-associated thiol protease regulates the number of [3H]glutamate binding sites in hippocampal membranes and that this is the mechanism by which calcium stimulates glutamate binding. The possibility is discussed that the postulated mechanisms participate in synaptic physiology and in particular may be related to the long-term potentiation of transmission found in hippocampus under certain conditions.     

砷对原代培养海马神经细胞的过氧化损伤

目的观察低剂量砷对新生大鼠海马神经细胞过氧化的影响。方法对原代培养的新生大鼠海马神经细胞经提取、纯化和鉴定后分组进行染毒试验。A组（对照组）、B组（砷50μmol/L）、D组（砷100μmol/L）、F组（砷200μmol/L）、H组（砷400μmol/L）,染毒时间为12 h。经超声波粉碎细胞后,测定神经细胞超氧化物歧化酶（SOD）、过氧化氢酶（CAT）、谷胱甘肽过氧化物酶（GSH-Px）、乙酰胆碱酯酶（TChE）活性和丙二醛（MDA）含量。结果与对照组比较,各染毒组GSH-Px、S0D和TChE活性显著降低（P〈0.05）,CAT活性和MDA含量显著升高（P〈0.05）,具有明显的剂量效应。结论低剂量砷暴露可引起海马神经细胞的过氧化损伤。