Ionic mechanisms of endogenous bursting in CA3 hippocampal pyramidal neurons: a model study

A critical property of some neurons is burst firing, which in the hippocampus plays a primary role in reliable transmission of electrical signals. However, bursting may also contribute to synchronization of electrical activity in networks of neurons, a hallmark of epilepsy. Understanding the ionic mechanisms of bursting in a single neuron, and how mutations associated with epilepsy modify these mechanisms, is an important building block for understanding the emergent network behaviors. We present a single-compartment model of a CA3 hippocampal pyramidal neuron based on recent experimental data. We then use the model to determine the roles of primary depolarizing currents in burst generation. The single compartment model incorporates accurate representations of sodium (Na(+)) channels (Na(V)1.1) and T-type calcium (Ca(2+)) channel subtypes (Ca(V)3.1, Ca(V)3.2, and Ca(V)3.3). Our simulations predict the importance of Na(+) and T-type Ca(2+) channels in hippocampal pyramidal cell bursting and reveal the distinct contribution of each subtype to burst morphology. We also performed fast-slow analysis in a reduced comparable model, which shows that our model burst is generated as a result of the interaction of two slow variables, the T-type Ca(2+) channel activation gate and the Ca(2+)-dependent potassium (K(+)) channel activation gate. The model reproduces a range of experimentally observed phenomena including afterdepolarizing potentials, spike widening at the end of the burst, and rebound. Finally, we use the model to simulate the effects of two epilepsy-linked mutations: R1648H in Na(V)1.1 and C456S in Ca(V)3.2, both of which result in increased cellular excitability.     

Neuroprotective effects of lactation against kainic acid treatment in the dorsal hippocampus of the rat

Marked hippocampal changes in response to excitatory amino acid agonists occur during pregnancy (e.g. decreased frequency in spontaneous recurrent seizures in rats with KA lesions of the hippocampus) and lactation (e.g. reduced c-Fos expression in response to N-methyl-d,l-aspartic acid but not to kainic acid). In this study, the possibility that lactation protects against the excitotoxic damage induced by KA in hippocampal areas was explored. We compared cell damage induced 24 h after a single systemic administration of KA (5 or 7.5 mg/kg bw) in regions CA1, CA3, and CA4 of the dorsal hippocampus of rats in the final week of lactation to that in diestrus phase. To determine cellular damage in a rostro-caudal segment of the dorsal hippocampus, we used NISSL and Fluorojade staining, immunohistochemistry for active caspase-3 and TUNEL, and we observed that the KA treatment provoked a significant loss of neurons in diestrus rats, principally in the pyramidal cells of CA1 region. In contrast, in lactating rats, pyramidal neurons from CA1, CA3, and CA4 in the dorsal hippocampus were significantly protected against KA-induced neuronal damage, indicating that lactation may be a natural model of neuroprotection.     

Hippocampal desynchronization of functional connectivity prior to the onset of status epilepticus in pilocarpine-treated rats

Status epilepticus (SE), a pro-epileptogenic brain insult in rodent models of temporal lobe epilepsy, is successfully induced by pilocarpine in some, but not all, rats. This study aimed to identify characteristic alterations within the hippocampal neural network prior to the onset of SE. Sixteen microwire electrodes were implanted into the left hippocampus of male Sprague-Dawley rats. After a 7-day recovery period, animal behavior, hippocampal neuronal ensemble activities, and local field potentials (LFP) were recorded before and after an intra-peritoneal injection of pilocarpine (350 mg/kg). The single-neuron firing, population neuronal correlation, and coincident firing between neurons were compared between SE (n?=?9) and nonSE rats (n?=?12). A significant decrease in the strength of functional connectivity prior to the onset of SE, as measured by changes in coincident spike timing between pairs of hippocampal neurons, was exclusively found in SE rats. However, single-neuron firing and LFP profiles did not show a significant difference between SE and nonSE rats. These results suggest that desynchronization in the functional circuitry of the hippocampus, likely associated with a change in synaptic strength, may serve as an electrophysiological marker prior to SE in pilocarpine-treated rats.     

Enduring Effects of Early Life Stress on Firing Patterns of Hippocampal and Thalamocortical Neurons in Rats: Implications for Limbic Epilepsy

Early life stress results in an enduring vulnerability to kindling-induced epileptogenesis in rats, but the underlying mechanisms are not well understood. Recent studies indicate the involvement of thalamocortical neuronal circuits in the progression of kindling epileptogenesis. Therefore, we sought to determine in vivo the effects of early life stress and amygdala kindling on the firing pattern of hippocampus as well as thalamic and cortical neurons. Eight week old male Wistar rats, previously exposed to maternal separation (MS) early life stress or early handling (EH), underwent amygdala kindling (or sham kindling). Once fully kindled, in vivo juxtacellular recordings in hippocampal, thalamic and cortical regions were performed under neuroleptic analgesia. In the thalamic reticular nucleus cells both kindling and MS independently lowered firing frequency and enhanced burst firing. Further, burst firing in the thalamic reticular nucleus was significantly increased in kindled MS rats compared to kindled EH rats (p<0.05). In addition, MS enhanced burst firing of hippocampal pyramidal neurons. Following a stimulation-induced seizure, somatosensory cortical neurons exhibited a more pronounced increase in burst firing in MS rats than in EH rats. These data demonstrate changes in firing patterns in thalamocortical and hippocampal regions resulting from both MS and amygdala kindling, which may reflect cellular changes underlying the enhanced vulnerability to kindling in rats that have been exposed to early life stress.     

美满霉素对癫痫大鼠海马神经元凋亡的影响

目的探讨美满霉素(minocycline,MC)对癫痫模型大鼠海马神经元的抗凋亡保护作用。方法将大鼠随机分为3组:生理盐水对照组(NS组),海人酸致痫组(KA组)和美满霉素预处理+海人酸组(MC+KA组)。以免疫组化法检测各组大鼠造模后2h、8h和24h海马部位Cytochrome C(CytC)免疫反应性。采用半定量RT-PCR和免疫组化法检测24h、48h caspase-3 mRNA和caspase-3表达情况。结果在KA致痫后2hCytC即开始有表达,8h达到高峰,24h表达减少,而MC预处理明显减弱此效应。caspase-3 mRNA的含量及caspase-3免疫反应性在24h时间点三组之间无明显差异,在48h时间点,KA组明显高于对照组(P0.05),MC预处理则明显拮抗KA诱导的caspase-3高表达。结论 KA致痫能诱导大鼠海马神经元凋亡,而MC能通过抑制凋亡途径对海马神经元发挥神经保护作用。     

大鼠海马癫痫电网络重建中爆发式放电神经元的活动

本文探讨双侧海马(hippoeampus,HPC)神经网络中爆发式放电神经元(bursting-firing neurons,BFN)的活动规律及其与海马癫痫网络重建的关系。实验用雄性SD大鼠140只(150-250 g),急性强直电刺激(60 Hz,2 s,0.4-0.6 mA)右后背HPC CAl区(acute tetanization of the posterior dorsal hippocampus,ATPDH),同步记录同侧或对侧前背HPC单位放电和深部电图;强直电刺激右前背HPC(acute tetanization of the anterior dorsal hippocampus,AT-ADH),同步记录双侧前背HPC单位放电。实验共记录了13.8％(19/138)双侧前背HPC的BFN,其中13个为刺激诱发性BFN,6个为自发性BFN。强直电刺激引起的诱发反应包括:(1)ATPDH明显调制同侧前背HPC的BFN,产生规则的节律性爆发式放电,刺激后串内动作电位间期(bursting interspike interval,BISI)减小(P<0.001);(2)AT-PDH引起对侧前背HPC的BFN出现抑制后轻度调制效应,刺激后动作电位间期(interspike interval,ISI)增大(P<0.001);(3)ATADH后易化对侧前背HPC的自发性BFN节律,增加ISI(P<0.001)和IBI(P=0.01);(4)ATPDH诱导双侧前背HPC的BFN产生规则的节律性爆发式放电,伴有同步或非同步性网络癫痫的形成。上述实验结果提示,ATPDH沿同侧HPC长轴,跨大脑半球诱发前背HPC单个BFN的形成,其节律性爆     

Acute alterations of somatodendritic action potential dynamics in hippocampal CA1 pyramidal cells after kainate-induced status epilepticus in mice

Pathophysiological remodeling processes at an early stage of an acquired epilepsy are critical but not well understood. Therefore, we examined acute changes in action potential (AP) dynamics immediately following status epilepticus (SE) in mice. SE was induced by intraperitoneal (i.p.) injection of kainate, and behavioral manifestation of SE was monitored for 3-4 h. After this time interval CA1 pyramidal cells were studied ex vivo with whole-cell current-clamp and Ca(2+) imaging techniques in a hippocampal slice preparation. Following acute SE both resting potential and firing threshold were modestly depolarized (2-5 mV). No changes were seen in input resistance or membrane time constant, but AP latency was prolonged and AP upstroke velocity reduced following acute SE. All cells showed an increase in AP halfwidth and regular (rather than burst) firing, and in a fraction of cells the notch, typically preceding spike afterdepolarization (ADP), was absent following acute SE. Notably, the typical attenuation of backpropagating action potential (b-AP)-induced Ca(2+) signals along the apical dendrite was strengthened following acute SE. The effects of acute SE on the retrograde spread of excitation were mimicked by applying the Kv4 current potentiating drug NS5806. Our data unveil a reduced somatodendritic excitability in hippocampal CA1 pyramidal cells immediately after acute SE with a possible involvement of both Na(+) and K(+) current components.     

Notch Signaling Activation Promotes Seizure Activity in Temporal Lobe Epilepsy

Notch signaling in the nervous system is often regarded as a developmental pathway. However, recent studies have suggested that Notch is associated with neuronal discharges. Here, focusing on temporal lobe epilepsy, we found that Notch signaling was activated in the kainic acid (KA)-induced epilepsy model and in human epileptogenic tissues. Using an acute model of seizures, we showed that DAPT, an inhibitor of Notch, inhibited ictal activity. In contrast, pretreatment with exogenous Jagged1 to elevate Notch signaling before KA application had proconvulsant effects. In vivo, we demonstrated that the impacts of activated Notch signaling on seizures can in part be attributed to the regulatory role of Notch signaling on excitatory synaptic activity in CA1 pyramidal neurons. In vitro, we found that DAPT treatment impaired synaptic vesicle endocytosis in cultured hippocampal neurons. Taken together, our findings suggest a correlation between aberrant Notch signaling and epileptic seizures. Notch signaling is up-regulated in response to seizure activity, and its activation further promotes neuronal excitation of CA1 pyramidal neurons in acute seizures.     

Chronic social defeat stress-induced enhancement of T-type calcium channels increases burst-firing neurons in the ventral subiculum

The ventral subiculum (vSub), a representative output structure of the hippocampus, serves as a main limbic region in mediating the brain's response to stress. There are three subtypes of subicular pyramidal neurons based on their firing patterns: regular-spiking (RS), weak-bursting (WB) and strong-bursting (SB) neurons, located differently along proximal–distal axis. Here, we found that chronic social defeat stress (CSDS) in mice increased the population of SB neurons but decreased RS neurons in the proximal vSub. Specific blockers of T-type calcium channels inhibited the burst firings with a concomitant reduction of afterdepolarization, suggesting that T-type calcium channels underlie the burst-spiking activity. Consistently, CSDS increased both T-type calcium currents and expression of Cav3.1 proteins, a subtype of T-type calcium channels, in the proximal vSub. Therefore, we conclude that CSDS-induced enhancement of Cav3.1 expression increased bursting neuronal population in the vSub, which may contribute to stress-related behaviors.     

海马mu型阿片肽受体介导大鼠癫痫发作敏感性形成

为探讨海马mu型阿片肽受体介导癫痫发作敏感性形成的作用,实验采用微渗透泵技术,观察大鼠腹侧海马注射mu型阿片肽受体激动剂PL017(2.09、2.59、3.29μg/μ1)、拮抗剂β-funaltrexamine hydrochloride(β-FNA、0.88、1.10、1.35μg/μl)对红藻氨酸(kainic acid,KA)诱导癫痫发作的干预作用.PL017能够明显缩短癫痫发作潜伏期、增加癫痫发作级别(P＜0.05),β-FNA则可显著延长癫痫发作潜伏期、降低发作级别(P＜0.01);PL017和β-FNA的干预作用均表现出剂量依赖效应.结果表明,海马mu型阿片肽受体具有促进KA诱导的癫痫发作敏感性形成作用.     

褪黑素对海人酸致痫大鼠海马内TGF-β3水平的影响

目的探讨褪黑素(me1atonin,MT)对海人酸(kainic acid,KA)致痫大鼠海马内TGF-β3的影响,进一步明确其在中枢内的作用。方法将实验大鼠随机分为3组:生理盐水对照组(NS组)、海人酸组(KA组)、褪黑素+海人酸组(MT+KA组)。各组大鼠给予相应试剂处理后观察并记录大鼠行为学改变,用免疫组织化学方法、RT-PCR检测大鼠海马内TGF-β3(transforming growth factor-β3)的表达情况及其mRNA变化。结果动物行为学观察显示,NS组无癫痫发作,KA组发作程度为Ⅲ-V级,MT+KA组为0-Ⅲ级;免疫组织化学结果显示,TGF-β3在3组大鼠海马内均有表达,其中KA组、MT+KA组较NS组表达增强,MT+KA组较KA组增强,差异具有显著性意义(P0.05);RT-PCR结果显示,与NS组相比较,KA组、MT+KA组大鼠海马内TGF-β3 mRNA含量均升高;但MT+KA组升高较KA组多,差异具有显著性意义(P0.05)。结论褪黑素能明显改善海人酸诱发的大鼠癫痫,增强海马内TGF-β3的表达,减轻海马神经元损伤,发挥中枢保护作用。     

锂-匹罗卡品颞叶癫模型的建立及苔藓纤维出芽的动态变化

目的研究锂-匹罗卡品颞叶癫模型大鼠致后性发作的行为学特点及海马结构病理改变的动态变化。方法将所有Wistar大鼠随机分为对照组和实验组,实验组大鼠腹腔依次注射氯化锂、匹罗卡品诱发癫持续状态（SE）后,观察其自发性癫发作（SRS）,分别于SE后1周至10周5个不同时间点取材,Nissl染色和Timm染色分别观察海马神经元损伤及苔藓纤维出芽（MFS）的变化。结果注射匹罗卡品后84%的大鼠可诱发出SE,经过10～20d的缄默期后,可观察到Ⅰ～Ⅲ级的反复SRS,病理学检查可见海马神经元的损伤及齿状回内分子层MFS。结论锂-匹罗卡品颞叶癫模型与人类颞叶癫有类似发作特点及病理改变,是一种理想的颞叶癫动物模型。     

IQGAP1 Expression in Spared CA1 Neurons After an Excitotoxic Lesion in the Mouse Hippocampus

Repeated seizures induce permanent alterations in the hippocampal circuits in experimental models with intractable temporal lobe epilepsy. Sprouting and synaptic reorganization induced by seizures has been well-studied in the mossy fiber pathway. However, studies investigating sprouting and synaptic reorganization beyond the mossy fiber pathway are limited. The present study examined the biochemical changes of CA1 pyramidal neurons undergoing morphological changes after excitotoxicity-induced hippocampal CA3 neuronal death. IQ-domain GTPase-activating proteins (IQGAP1), is an effector of Rac1 and Cdc42 and an actin-binding protein, was upregulated in CA1 pyramidal neurons after kainic acid-induced hippocampal CA3 neuronal degeneration. IQGAP1 + cells were colocalized with Nestin, but not in astrocytes or mature neurons. Furthermore, IQGAP1 did not originate from newly divided local precursors or NG2 + cells. IQGAP1 and adenomatous polyposis coli localized in CA1 pyramidal neurons, and Cdc42 activation was followed by IQGAP1 recruitment. These findings suggest that IQGAP1 is upregulated in pre-existed sparing neurons of the CA1 layer undergoing morphological changes after excitoxicity-induced hippocampal CA3 neuronal death. It demonstrates the utility of IQGAP1 as a possible marker for spared pyramidal neurons, which may contribute to structural and functional alternations responsible for the development of epilepsy.     

Seizure-induced plasticity of h channels in entorhinal cortical layer III pyramidal neurons

The entorhinal cortex (EC) provides the predominant excitatory drive to the hippocampal CA1 and subicular neurons in chronic epilepsy. Discerning the mechanisms underlying signal integration within EC neurons is essential for understanding network excitability alterations involving the hippocampus during epilepsy. Twenty-four hours following a single seizure episode when there were no behavioral or electrographic seizures, we found enhanced spontaneous activity still present in the rat EC in vivo and in vitro. The increased excitability was accompanied by a profound reduction in I(h) in EC layer III neurons and a significant decline in HCN1 and HCN2 subunits that encode for h channels. Consequently, dendritic excitability was enhanced, resulting in increased neuronal firing despite hyperpolarized membrane potentials. The loss of I(h) and the increased neuronal excitability persisted for 1 week following seizures. Our results suggest that dendritic I(h) plays an important role in determining the excitability of EC layer III neurons and their associated neural networks.     

Does phenobarbital protect against trimethyltin-induced neuropathology of limbic structures?

Because of the similarity in the pattern of limbic sites damaged by both compounds, it has been suggested that trimethyltin (TMT) may be an excitotoxin like kainic acid (KA). KA produces seizures which eventually result in neuronal damage similar to that found in epilepsy. Anticonvulsants reduce both the seizures and pathology associated with KA. Because TMT may also produce seizures, we undertook to determine whether or not some of the TMT-induced limbic neuropathology could result from seizure activity. To do this, a single dose of TMT chloride (either 7.5 or 15 mg/kg) was given per os to rats, and then phenobarbital (30 mg/kg) was administered subcutaneously in repeated doses. Treatment with phenobarbital did not prevent pathologic changes in the hippocampus, dentate gyrus, and pyriform or prepyriform cortex. Since phenobarbital did not protect against TMT-induced neuronal damage, as it has been reported by others to protect against KA-induced damage, the present findings suggest that these two toxicants probably produce hippocampal pathology via different mechanisms and that the TMT-induced pathologic changes do not require sustained electrical seizure activity.     

Neurobiological Correlates of Alpha-Tocopherol Antiepileptogenic Effects and MicroRNA Expression Modulation in a Rat Model of Kainate-Induced Seizures

Seizure-triggered maladaptive neural plasticity and neuroinflammation occur during the latent period as a key underlying event in epilepsy chronicization. Previously, we showed that α-tocopherol (α-T) reduces hippocampal neuroglial activation and neurodegeneration in the rat model of kainic acid (KA)-induced status epilepticus (SE). These findings allowed us to postulate an antiepileptogenic potential for α-T in hippocampal excitotoxicity, in line with clinical evidence showing that α-T improves seizure control in drug-resistant patients. To explore neurobiological correlates of the α-T antiepileptogenic role, rats were injected with such vitamin during the latent period starting right after KA-induced SE, and the effects on circuitry excitability, neuroinflammation, neuronal death, and microRNA (miRNA) expression were investigated in the hippocampus. Results show that in α-T-treated epileptic rats, (1) the number of population spikes elicited by pyramidal neurons, as well as the latency to the onset of epileptiform-like network activity recover to control levels; (2) neuronal death is almost prevented; (3) down-regulation of claudin, a blood–brain barrier protein, is fully reversed; (4) neuroinflammation processes are quenched (as indicated by the decrease of TNF-α, IL-1β, GFAP, IBA-1, and increase of IL-6); (5) miR-146a, miR-124, and miR-126 expression is coherently modulated in hippocampus and serum by α-T. These findings support the potential of a timely intervention with α-T in clinical management of SE to reduce epileptogenesis, thus preventing chronic epilepsy development. In addition, we suggest that the analysis of miRNA levels in serum could provide clinicians with a tool to evaluate disease evolution and the efficacy of α-T therapy in SE.     

Sleepy dialogues between cortex and hippocampus: who talks to whom?

During NREM sleep, neocortical neurons undergo near-synchronous transitions, every second or so, between UP states, during which they are depolarized and fire actively, and DOWN states, during which they are hyperpolarized and completely silent. In this issue of Neuron, Isomura et al. report that slow oscillations of membrane potential occur near-synchronously not only in neocortex but also in entorhinal cortex and subiculum. Within the hippocampus proper, pyramidal neurons lack the bistability of UP and DOWN states, but their firing is strongly modulated by cortical activity during the UP state. Intriguingly, many hippocampal neurons fire during the cortical DOWN state. Thus, during sleep UP states, the cortex can talk to the hippocampus, but it is unclear whether the hippocampus talks back.     

Gabapentin Administration Reduces Reactive Gliosis and Neurodegeneration after Pilocarpine-Induced Status Epilepticus

The lithium-pilocarpine model of epilepsy reproduces in rodents several features of human temporal lobe epilepsy, by inducing an acute status epilepticus (SE) followed by a latency period. It has been proposed that the neuronal network reorganization that occurs during latency determines the subsequent appearance of spontaneous recurrent seizures. The aim of this study was to evaluate neuronal and glial responses during the latency period that follows SE. Given the potential role of astrocytes in the post-SE network reorganization, through the secretion of synaptogenic molecules such as thrombospondins, we also studied the effect of treatment with the α2δ1 thrombospondin receptor antagonist gabapentin. Adult male Wistar rats received 3 mEq/kg LiCl, and 20 h later 30 mg/kg pilocarpine. Once SE was achieved, seizures were stopped with 20 mg/kg diazepam. Animals then received 400 mg/kg/day gabapentin or saline for either 4 or 14 days. In vitro experiments were performed in dissociated mixed hippocampal cell culture exposed to glutamate, and subsequently treated with gabapentin or vehicle. During the latency period, the hippocampus and pyriform cortex of SE-animals presented a profuse reactive astrogliosis, with increased GFAP and nestin expression. Gliosis intensity was dependent on the Racine stage attained by the animals and peaked 15 days after SE. Microglia was also reactive after SE, and followed the same pattern. Neuronal degeneration was present in SE-animals, and also depended on the Racine stage and the SE duration. Polysialic-acid NCAM (PSA-NCAM) expression was increased in hippocampal CA-1 and dentate gyrus of SE-animals. Gabapentin treatment was able to reduce reactive gliosis, decrease neuronal loss and normalize PSA-NCAM staining in hippocampal CA-1. In vitro, gabapentin treatment partially prevented the dendritic loss and reactive gliosis caused by glutamate excitotoxicity. Our results show that gabapentin treatment during the latency period after SE protects neurons and normalizes PSA-NCAM probably by direct interaction with neurons and glia.     

局部高频电刺激海马对海人酸致痫大鼠海马细胞外谷氨酸和γ-氨基丁酸释放的影响

目的：通过高频电刺激海人酸癫痫模型大鼠海马,观察海马细胞外谷氨酸（Glu）和γ-氨基丁酸（GABA）的动态变化。方法：将SD大鼠分成4大组（n=10）：①空白组;②海人酸组;③假刺激组：植入刺激电极未予电刺激;④电刺激组：海人酸注射后予130 Hz电刺激。利用微透析技术收集不同时段海马细胞外液,应用高效液相-荧光检测法测定收集液Glu、GABA的浓度。结果：注射海人酸后Glu明显升高,并持续至第14天,电刺激使Glu明显下降;而注射海人酸后GABA呈短暂性升高,后逐渐下降于第4天后保持稍高于正常水平,电刺激并无明显改变GABA的水平。结论：海马细胞外Glu下降在海马电刺激治疗癫痫中起到重要作用;高频电刺激海马选择性地减少谷氨酸能神经元活动,但不影响GABA的释放。     

Kainic acid increases activity only of some cortical neurons in the rat

The influence of a subconvulsant dose of kainic acid (KA) on the activity of neurons was studied in the sensorimotor cortical area of urethane-anesthetized rats. A total of 41 neurons was recorded, 38 of these in layer V (probably pyramidal cells). The activity of 18 neurons was recorded before as well as more than 30 min after KA administration (6 mg/kg i.p.). Nine out of these 18 neurons increased their firing rate significantly even 20 min after KA injection, whereas the remaining neurons did not change their activity. Altogether, the increase in the firing rate was significant. KA was found to enhance markedly the firing rate of a part of cortical neurons at very early stages of its action.