Dynamic increases in AMPA receptor phosphorylation in the rat hippocampus in response to amphetamine

Increasing evidence supports the critical role of α‐amino‐3‐hydroxy‐5‐methyl‐4‐isoxazolepropionic acid (AMPA) glutamate receptors in psychostimulant action. These receptors are regulated via a phosphorylation‐dependent mechanism in their trafficking, distribution, and function. The hippocampus is a brain structure important for learning and memory and is emerging as a critical site for processing psychostimulant effects. To determine whether the hippocampal pool of AMPA receptors is regulated by stimulants, we investigated and characterized the impact of amphetamine (AMPH) on phosphorylation of AMPA receptors in the adult rat hippocampus in vivo. We found that AMPH markedly increased phosphorylation of AMPA receptor GluA1 subunits at serine 845 (S845) in the hippocampus. The effect of AMPH was dose dependent. A single dose of AMPH induced a rapid and transient increase in S845 phosphorylation. Among different hippocampal subfields, AMPH primarily elevated S845 phosphorylation in the Cornu Ammonis area 1 and dentate gyrus. In contrast to S845, serine 831 phosphorylation of GluA1 and serine 880 phosphorylation of GluA2 were not altered by AMPH. In addition, surface expression of hippocampal GluA1 was up‐regulated, while the amount of intracellular GluA1 fraction was concurrently reduced in response to AMPH. GluA2 protein levels in either the surface or intracellular pool were insensitive to AMPH. These data demonstrate that the AMPA receptor in the hippocampus is sensitive to dopamine stimulation. Acute AMPH administration induces dose‐, time‐, site‐, and subunit‐dependent phosphorylation of AMPA receptors and facilitates surface trafficking of GluA1 AMPA receptors in hippocampal neurons in vivo.

     

Blunted neuronal calcium response to hypoxia in naked mole-rat hippocampus

Naked mole-rats are highly social and strictly subterranean rodents that live in large communal colonies in sealed and chronically oxygen-depleted burrows. Brain slices from naked mole-rats show extreme tolerance to hypoxia compared to slices from other mammals, as indicated by maintenance of synaptic transmission under more hypoxic conditions and three fold longer latency to anoxic depolarization. A key factor in determining whether or not the cellular response to hypoxia is reversible or leads to cell death may be the elevation of intracellular calcium concentration. In the present study, we used fluorescent imaging techniques to measure relative intracellular calcium changes in CA1 pyramidal cells of hippocampal slices during hypoxia. We found that calcium accumulation during hypoxia was significantly and substantially attenuated in slices from naked mole-rats compared to slices from laboratory mice. This was the case for both neonatal (postnatal day 6) and older (postnatal day 20) age groups. Furthermore, while both species demonstrated more calcium accumulation at older ages, the older naked mole-rats showed a smaller calcium accumulation response than even the younger mice. A blunted intracellular calcium response to hypoxia may contribute to the extreme hypoxia tolerance of naked mole-rat neurons. The results are discussed in terms of a general hypothesis that a very prolonged or arrested developmental process may allow adult naked mole-rat brain to retain the hypoxia tolerance normally only seen in neonatal mammals.     

Robotic and neuronal simulation of the hippocampus and rat navigation.

The properties of hippocampal place cells are reviewed, with particular attention to the nature of the internal and external signals that support their firing. A neuronal simulation of the firing of place cells in open-field environments of varying shape is presented. This simulation is coupled with an existing model of how place-cell firing can be used to drive navigation, and is tested by implementation as a miniature mobile robot. The sensors on the robot provide visual, odometric and short-range proximity data, which are combined to estimate the distance of the walls of the enclosure from the robot and the robot''s current heading direction. These inputs drive the hippocampal simulation, in which the robot''s location is represented as the firing of place cells. If a goal location is encountered, learning occurs in connections from the concurrently active place cells to a set of ''goal cells'', which guide subsequent navigation, allowing the robot to return to an unmarked location. The system shows good agreement with actual place-cell firing, and makes predictions regarding the firing of cells in the subiculum, the effect of blocking long-term synaptic changes, and the locus of search of rats after deformation of their environment.     

pH shifts evoked by neuronal stimulation in slices of rat hippocampus

Extracellular pH was measured with ion-selective microelectrodes in 500-microns thick slices of the CA1 region of the rat hippocampus. The center of the slice was 0.24 pH units more acidic than the surface, thus creating a decreasing pH gradient from the surface to the center, most likely owing to increased anaerobic metabolism. Stimulation at various frequencies created a transient alkaline shift of 0.03 pH unit, followed by a sustained acidification (0.05 pH unit above baseline). The same pattern was seen in both cell body and dendritic layers. The presence of the alkaline shift in slices in vitro is especially significant, implying that it is not due to alterations in blood flow. The HCO3- -Cl- transport inhibitor SITS and the carbonic anhydrase inhibitor acetazolamide increased the alkaline shift to 0.06 and 0.23, respectively. The acid shift was influenced by the Na+-H+ transport inhibitor amiloride, with a reduction of about 50%. Possible mechanisms for these stimulus-evoked changes as discussed. The most likely cause for the alkaline shift is bicarbonate accumulation in the extracellular space. Hydrogen ion and lactic acid release are seen as the major factors contributing to the sustained acid shift.     

学习训练对谷氨酸单钠所致大鼠海马损伤的神经保护作用

目的：探讨学习训练对谷氨酸神经毒性的保护作用。方法：在SD大鼠生后第3～9d腹腔注射谷氨酸单钠复制谷氨酸毒性模型,在1月龄和2月龄时训练大鼠学会以明暗辨别来获得食物,3月龄时取脑,在光镜下计数海马内存活神经元数,电镜下观察海马CA1区的超微结构,并计数突触数,测量突触活性带长度。结果：学习训练组海马CA3区和CA4区内的存活神经元数、海马CA1区内的突触数和突触活性带长度均大于非学习组,结论：结果提示学习训练可在一定程度上减轻MSG对海马的损伤。     

Interferon-gamma plus lipopolysaccharide induction of delayed neuronal apoptosis in rat hippocampus

Interferon-gamma and lipopolysaccharide (IFN-gamma/LPS) induce expression of inducible nitric oxide synthase (iNOS) protein both in cells in vitro and in the brain in vivo. In cultured cells, excessive production of nitric oxide (NO) induces neuronal cell death. However, it is still unclear whether IFN-gamma and LPS might induce neuronal cell death in vivo. In this study, we examined the neuronal cell death and induction of major histocompatibility complex (MHC) antigens after microinjection of IFN-gamma/LPS into the rat hippocampus. Although microglia appeared morphologically ramified in the normal and vehicle-injected hippocampus, microinjection of IFN-gamma/LPS immediately induced the ameboid type. From days 1-7, iNOS was expressed in ameboid microglia surrounding the site of the microinjection. Terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling (TUNEL)-positive cells appeared among the granular neurons of the dentate gyrus on day 3 and peaked about 7 days after microinjection. When the NOS inhibitor N(G)-nitro-L-arginine (L-NA) was intraperitoneally administered prior to the microinjection, the number of TUNEL-positive neurons decreased in a L-NA dose-dependent manner. These results suggest that IFN-gamma/LPS induces delayed neuronal apoptosis in the hippocampus in vivo, and it possibly involves excessive NO production by iNOS. Thus, this animal model may be one of neurodegenerative with extensive inflammatory activation in the hippocampus.     

Dynamic phase-shifts between theta generators in the rat hippocampus.

Winson [13] reported on two independent phase-reversed generators in the rat hippocampus. In the present study the synchrony between the two generators was investigated during the sleep-wakefulness cycle and during a behaviour-dependent discriminative learning task. Electrical activities derived from the CA 1 region and dentate gyrus were in phase during slow wave sleep but phase-reversed during the awake state and paradoxical sleep. The degree of phase-reversal was significantly higher during running than during lever pressing. These findings demonstrate that substantial changes occur within the hippocampal circuitry during dynamic shifts of behaviour.     

Anesthetic and postanesthetic effects of isoflurane on neuronal activity in the rat hippocampus

In this study, we explored anesthetic and postanesthetic effects of isoflurane on GABA-ergic and glutamatergic systems in the rat hippocampus. Our results demonstrate that different neuronal targets affected by isoflurane recover from anesthesia at dissimilar rates. Neirofiziologiya/Neurophysiology, Vol. 39, Nos. 4/5, pp. 371–373, July–October, 2007.     

利多卡因和硫喷妥钠对培养的大鼠海马脑片神经元损伤的影响

目的 :观察利多卡因和硫喷妥钠对生后 2 2d大鼠培养海马脑片的实验型缺血后神经元损伤的影响。方法 :将培养的SD大鼠海马脑片实验型缺血 (缺氧缺糖 ) 1 0min ,给药组在缺血前 1 0min给予 1 0nmol/L、1 0 0nmol/L的利多卡因或 2 50nmol/L、60 0nmol/L的硫喷妥钠 ,缺血后换用正常培养基继续培养 7d ,并用荧光染料PropidiumIo dide(PI)连续观察海马CA1区和齿状回神经元的损伤。结果 :缺血后第 1d缺血组即出现神经元损伤高峰 ,CA1区和齿状回的PI指数显著增加 (P <0 .0 1 ) ;直至缺血后第 7d其损伤指数仍显著高于缺血前水平 (P <0 .0 1 )。两浓度的利多卡因和硫喷妥钠均可降低缺血后CA1区和齿状回神经元损伤的程度 (P <0 .0 1 ) ,并可将CA1区和齿状回的神经元损伤高峰推迟至缺血后第 3d。结论 :利多卡因和硫喷妥可减轻缺血后海马CA1区和齿状回的神经元损伤 ,推迟神经元的损伤高峰。     

A nuclear microscopic study of elemental changes in the rat hippocampus after kainate-induced neuronal injury

The effect of intracerebroventricular kainate injection on the elemental composition of the hippocampus was studied in adult Wistar rats, at 1 day and 1, 2, 3, and 4 weeks postinjection, using a nuclear microscope. An increase in calcium concentration was observed on the injected side from 1 day postinjection. The increase peaked at 3 weeks postinjection, reaching a concentration of 18 times normal. Large numbers of glial cells but no neurons were observed in the lesioned CA fields at this time, suggesting that an increased calcium level was present in glial cells. This was confirmed by high-resolution elemental maps of the lesioned areas, which showed very high intracellular calcium concentrations in almost all glial cells. It is possible that the high intracellular calcium level could activate calcium-dependent enzymes, including calpain II and cytosolic phospholipase A2, shown to be expressed in reactive glial cells after kainate injections. In addition to calcium, an increase in iron content was also observed at the periphery of the glial scar at 4 weeks postinjection. Because free iron could catalyze the formation of free radicals, the late increase in iron content may be related to oxygen radical formation during neurodegeneration.     

Functional regulation of the neuronal activity of the rat hippocampus transplanted into the rabbit septum

Embryonal tissue of the rat hippocampus was grafted into dorsolateral septum of the rabbit after its disconnection from the hippocampus. Extracellular investigation of the grafted neurones was performed in chronic conditions 6 to 7 weeks later. The grafted neurones had some characteristics typical of the rat hippocampus (low spontaneous activity and presence of complex spikes, low-frequency rhythmic modulation--below 1 Hz, significant increase of activity level after physostigmine injection). Weak periodic theta-modulation, observed in spontaneous activity of some grafted neurones, became more stable and appeared in additional units after injection of physostigmine, under the influence of electrical stimulation of the septum and reticular formation and in response to sensory stimulation of the host animal. Its frequency was 4.5-6.0 Hz, as in the host septum. Microelectrode investigation for 5-10 days provoked lymphocyte infiltration of the grafts, which was not observed in the grafts not subjected to such treatment.     

The influence of potassium concentration on epileptic seizures in a coupled neuronal model in the hippocampus

Experiments on hippocampal slices have recorded that a novel pattern of epileptic seizures with alternating excitatory and inhibitory activities in the CA1 region can be induced by an elevated potassium ion (K⁺) concentration in the extracellular space between neurons and astrocytes (ECS-NA). To explore the intrinsic effects of the factors (such as glial K⁺ uptake, Na⁺–K⁺-ATPase, the K⁺ concentration of the bath solution, and K⁺ lateral diffusion) influencing K⁺ concentration in the ECS-NA on the epileptic seizures recorded in previous experiments, we present a coupled model composed of excitatory and inhibitory neurons and glia in the CA1 region. Bifurcation diagrams showing the glial K⁺ uptake strength with either the Na⁺–K⁺-ATPase pump strength or the bath solution K⁺ concentration are obtained for neural epileptic seizures. The K⁺ lateral diffusion leads to epileptic seizure in neurons only when the synaptic conductance values of the excitatory and inhibitory neurons are within an appropriate range. Finally, we propose an energy factor to measure the metabolic demand during neuron firing, and the results show that different energy demands for the normal discharges and the pathological epileptic seizures of the coupled neurons.     

A developmentally regulated switch in neuronal responsiveness to NCAM and N-cadherin in the rat hippocampus.

Monolayers of control 3T3 fibroblasts and 3T3 cells expressing transfected NCAM or N-cadherin have been used as a culture substratum for rat hippocampal neurons. Both NCAM and N-cadherin are expressed in the hippocampus through embryonic day 17 (E17) to postnatal day 4 (PND4); however, whereas E17 neurons responded to transfected NCAM by extending considerably longer neurites, PND4 neurons responded very poorly. The converse was true for responsiveness to N-cadherin. These data demonstrate a switch in neuronal responsiveness to NCAM and N-cadherin in the developing hippocampus. NCAM-dependent neurite outgrowth from E17 neurons was largely dependent on the presence of alpha 2-8-linked polysialic acid (PSA) on neuronal NCAM. NCAM-dependent neurite outgrowth could be fully inhibited by pertussis toxin or a combination of L- and N-type calcium channel antagonists thus providing direct evidence concerning the nature of the second messenger pathway activated in primary neurons by cell adhesion molecules (CAMs).     

Profile of prostaglandin levels in the rat hippocampus in pilocarpine model of epilepsy

Pilocarpine (PILO) administered to rats acutely induces status epilepticus (acute period), which is followed by a transient seizure-free period (silent period), and finally by a chronic phase of spontaneous recurrent seizures (chronic period, SRS) that lasts for the rest of animal's life. Hippocampal neurochemical changes following PILO administration include alteration in monoamines and amino acids content during all phases of this epilepsy model. The present work was delineated to study the content of prostaglandins (PG) levels in hippocampus during the three phases of this model. The levels of PG E₂, PG F₂ alpha and PG D₂ were measured by radioimmunoassay 1 h after PILO, 5 h after PILO, during the silent period, and interictally into the chronic period. The results show, in hippocampus of rats, increase of PG F₂ alpha and PG D₂ during status epilepticus, increase of PG D₂ during the silent period and increase of PG E₂ and PG D₂ during the chronic phase, when compared with control group. These changes match previously reported alteration in monoamines and amino acid levels, showing that altered neurotransmission is accompanied by changes in second messengers and enzyme activity related to PG production during all phases of this epilepsy model.     

Effects of high-fat diet on insulin receptor function in rat hippocampus and the level of neuronal corticosterone

AimChronic consumption of a high-fat (HF) diet contributes to peripheral insulin resistance and elevated plasma corticosterone. However, the effect of HF consumption on the neurofunctional insulin receptors and neuronal corticosterone level is unclear. We tested the hypothesis that HF consumption can lead to peripheral insulin resistance, elevated neuronal corticosterone, and impaired neuronal responses to insulin.Main methodsMale Wistar rats were fed with normal diet or HF diet for 4, 8 or 12 weeks. At the end of each dietary period, plasma was collected for investigating peripheral insulin resistance parameters and corticosterone. Brains were then rapidly removed for studying the function of neuronal insulin receptors (IRs) by extracellular recording in CA1 hippocampus, neuronal IR signaling by immunoblot technique and neuronal corticosterone.Key findingsElevated plasma corticosterone level was initially seen in 4-week HF-fed rats. Peripheral insulin resistance developed at 8-week HF-fed rats. However, the elevated neuronal corticosterone level was found at 12-week HF consumption. The neuronal IR response demonstrated by insulin-mediated long-term depression in CA1 hippocampus was diminished in 12-week HF-fed rats. The phosphorylation levels of neuronal IR, IR substrate 1 and Akt/PKB were decreased in 12-week HF-fed rats with no change in these proteins. There was a correlation among peripheral insulin resistance, neuronal stress (elevated neuronal corticosterone), and neuronal insulin resistance in HF group.SignificanceOur findings suggest that HF consumption can lead to the elevation of corticosterone and peripheral insulin resistance, which could contribute to neuronal insulin resistance and neuronal stress.     

Cell-type specific depression of neuronal excitability in rat hippocampus by activation of ATP-sensitive potassium channels

The contribution of ATP-sensitive potassium (K(ATP)) channels to neuronal excitability was studied in different types of pyramidal cells and interneurones in hippocampal slices prepared from 9- to 15-day-old rats. The presence of functional K(ATP) channels in the neurones was detected through the sensitivity of whole-cell currents to diazoxide, a K(ATP) channel opener, and to tolbutamide, a K(ATP) channel inhibitor. The percentages of neurones with K(ATP) channels increase in the sequence: CA1 pyramidal cells (37%)相似文献   

Brain-derived neurotrophic factor facilitates TrkB down-regulation and neuronal injury after status epilepticus in the rat hippocampus

Brain-derived neurotrophic factor (BDNF) is involved in many aspects of neuronal biology and hippocampal physiology. Status epilepticus (SE) is a condition in which prolonged seizures lead to neuronal degeneration. SE-induced in rodents serves as a model of Temporal Lobe Epilepsy with hippocampal sclerosis, the most frequent epilepsy in humans. We have recently described a strong correlation between TrkB decrease and p75ntr increase with neuronal degeneration ( Neuroscience 154:978, 2008). In this report, we report that local, acute intra-hippocampal infusion of function-blocking antibodies against BDNF prevented both early TrkB down-regulation and neuronal degeneration after SE. Conversely, the infusion of recombinant human BDNF protein after SE greatly increased neuronal degeneration. The inhibition of BDNF mRNA translation by the infusion of antisense oligonucleotides induced a rapid decrease of BDNF protein levels, and a delayed increase. If seizures were induced at the time endogenous BDNF was decreased, SE-induced neuronal damage was prevented. On the other hand, if seizures were induced at the time endogenous BDNF was increased, SE-induced neuronal damage was exacerbated. These results indicate that under a pathological condition BDNF exacerbates neuronal injury.