Effects of prenatal protein malnutrition on hippocampal CA1 pyramidal cells in rats of four age groups

The present study was undertaken to investigate the effect of prenatal protein deprivation on area CA1 hippocampal pyramidal cells on postnatal (P) days 15, 30, 90 and 220 using Golgi techniques. Age related changes in both groups and diet related changes between groups were assessed. There were significant diet effects at all four ages, with one of 12 different measurements showing a significant diet effect on P15, five on P30, one on P90, and seven on P220. The most marked effect of the diet was on pyramidal cell dendrite spine density in the stratum moleculare and stratum radiatum, with a different pattern of diet effects in the two strata. In pyramidal cell dendrites in the stratum moleculare, there was a deficit in spine density that was significant at three of the four ages and there were similar age-related changes in the two diet groups. Spines on pyramidal cell dendrites in the stratum radiatum showed a lack of synchrony of age-related changes in the two diet groups, with an increased spine density in the malnourished rats on P30 and a widening deficit in this parameter on P90 and P220. The bimodal distribution to these changes, with most marked deficits occurring on P30 and P220, with an intervening period of apparent “catch-up” on P90, is of interest and may be a significant brain adaptation to malnutrition. The present study is the final of three morphometric studies on the effect of prenatal protein restriction on three key neurons in the hippocampal trisynaptic circuit. When compared to our previous studies on the dentate granule cell and the CA3 pyramidal cell, it is noted that there is an effect of the low protein diet on all these neurons, with the most marked effect on the predominantly postnatally generated dentate granule cells. Hippocampus 7:192–203, 1997. © 1997 Wiley-Liss, Inc.     

Sensitivity of postsynaptic GABAB receptors on hippocampal CA1 and CA3 pyramidal neurons to ethanol

Baclofen-induced hyperpolarization of hippocampal CA1 and CA3 pyramidal neurons was examined to assess the impact of ethanol on postsynaptic GABA_B receptors. These receptors activate outward K⁺ currents via a pertussis toxin-sensitive G protein cascade to reduce membrane potential during the slow inhibitory postsynaptic potential. This inhibitory action may play a role in ethanol intoxication and withdrawal excitability. In both types of pyramidal neurons, baclofen applied consecutively in increasing concentrations caused concentration dependent hyperpolarization. There were no significant differences in resting membrane potential, input resistance, maximum baclofen-induced hyperpolarization or EC₅₀ between CA1 and CA3 neurons, although slope values were significantly smaller in the former neurons. These parameters were not significantly changed in the presence of ethanol 10–100 mM. Chronic ethanol treatment (12 days) sufficient to induce physical dependence also did not shift sensitivity or maximum response to baclofen in CA1 neurons. These results suggest that GABA_B receptors in this model are essentially insensitive to ethanol and do not confirm our earlier preliminary observation of a possible down-regulation of postsynaptic GABA_B receptor function by chronic ethanol treatment.     

Variation in electrophysiology and morphology of hippocampal CA3 pyramidal cells

A proportion of pyramidal cells in region CA3 of the mammalian hippocampus generate bursts of action potentials when stimulated with an intracellular injection of depolarizing current. Although a previous study has suggested that burst-type cells are more likely to be located in subregion CA3a than CA3b, it has been unclear if, or how, this burst-type firing was related to cell morphology. In the present study, a sample of pyramidal cells located in subregions CA3a, b and c were recorded intracellularly. Many of these cells were filled with Lucifer yellow, allowing correlation of gross morphology with electrophysiology. Contrary to previous results, it was determined that the proportion of cells which generated bursts did not differ significantly across CA3 subregions. It was found, however, that cells with somata located close to the stratum pyramidale (s.p.)/oriens border ('deep' cells) were more than twice as likely to generate burst-type responses than were cells located closer to stratum radiatum ('shallow' cells). One notable morphological feature of the deep cells was the greater length of the initial portion of their apical dendrite, as measured from soma to primary branching point. This observation is consistent with the hypothesis that burst-type responses are generated or modulated by ion channels on this section of the dendrite.     

Dendritic excrescences seem to characterize hippocampal CA3 pyramidal neurons in humans

Summary. Excrescences are unique dendritic postsynaptic structures of the hippocampal formation. Only CA3 pyramidal neurones and hilar mossy cells possess these complex dendritic structures. Dendritic excrescences have so far only been investigated in rabbit, rat and rhesus monkey. Applying a Golgi impregnation method optimized for human brain tissue, we describe the detailed morphology of excrescences of CA3 pyramidal neurons of man. Human thorny excrescences possess a thin and single spine neck and multiple spine heads (4 on average, sometimes more than 10). Human cluster excrescences sit upon the dendrite with a broad stem, and exhibit a “papilloma-like” surface. Some human CA3 pyramidal neurons seem to possess markedly longer spine necks and larger spine heads compared to human neocortical pyramid cells; they were named long-neck spines. Thorny excrescences, cluster excrescences and the newly described long-neck spines can also be found on the dendritic main stem of human CA3 pyramidal neurons. CA2 pyramidal neurons neither possess these long neck spines nor thorny or cluster excrescences. Thus, the unique excrescences of CA3 pyramidal neurones seem to be another criterion for a demarcation between the CA3- and CA2 region of the human hippocampus.     

Denervation-induced dendritic alterations in CA1 pyramidal cells following kainic acid hippocampal lesions in rats

Kainic acid (KA) lesions of the CA3 region of the hippocampus lead to denervation of ipsilateral CA1 neurons. To assess denervation-induced post-synaptic changes, intracellular physiological recordings were performed in the CA1 region in vitro, from both control and KA-treated tissue. The neurons were intracellularly stained with neurobiotin, reconstructed using a quantitative three-dimensional system and analyzed for morphometric and electrotonic parameters. Total dendritic length was slightly longer in the denervated CA1 cells and there was a selective and significant increase in both branches and terminals in the mid-stratum radiatum (300–500 μm from the soma using Sholl analysis) in the KA-treated rats compared to untreated controls, particularly for cells at 5 days post-lesion and later, which exhibited graded synaptically-evoked bursts. However, there was no significant difference in the basal dendritic arborization. Electrotonic modelling of the dendritic structure revealed specific membrane resistivity values of 33.4 kΩ·cm² for the normal CA1 cells and 29.8 KΩ-cm² for the KA-treated cells, assuming an internal resistivity of 200 Ω·cm², shrinkage correction of 1.57 and a spatial distribution of dendritic spines. The number of dendritic terminals of these denervated CA1 neurons at electrotonic distances between 0.5λ and 0.7λ also significantly increased in the cells from KA-treated animals. These findings indicate that there is a selective and specific increase in the number of apical terminals and dendritic branches following the unilateral kainic acid lesion. These apical branch changes may represent dendritic sprouting as a post-synaptic response to the denervation, which was particularly marked in neurons exhibiting graded synaptic bursting behavior.     

Coupling in rat hippocampal slices: Dye transfer between CA1 pyramidal cells

Intracellular injections of Lucifer Yellow-CH (LY) into CA1 pyramidal cells were made in rat hippocampal slices to study dye transfer between neurons as evidence that these cells are electrotonically coupled. Extensive control procedures were performed which substantially reduced inadvertent staining. Over half of the neurons were dye-coupled after injections in stratus pyramidale. Dye coupling occurred even when spike amplitudes were greater than or equal to 70 mV throughout the impalement and was still present after chemical synapses were blocked with a low Ca2+ solution containing Mn2+. Somata of dye-coupled cells were usually located within 35 micrometers (post-fixation) of the injected cell and showed no preferred orientation. Fast prepotentials and dye coupling occurred independently. Neurons in superior cervical ganglia, which were sliced and injected using similar procedures, showed no dye coupling. Intradendritic injections of LY in stratum radiatum also yielded dye coupling between CA 1 pyramidal cells, although the dye coupling was less frequent. Within stratum radiatum, neither extracellular ejections nor intracellular injections of interneurons were associated with multiple staining. Thus, injection of LY into the soma or dendrite of a single CA1 pyramidal cell often resulted in multiple staining, and in many ensembles the somata were well spaced. Control experiments suggested that such dye transfer is not by an extracellular route. This implied that some CA1 cells are electrotonically coupled. Further electrophysiological and morphological studies are required to resolve the discrepancies among various techniques used to evaluate the amount of coupling in the hippocampus.     

Early dendritic changes in hippocampal pyramidal neurones (field CA1) of rats subjected to acute soman intoxication: a light microscopic study

In rats poisoned with soman (s.c. 100 μg/kg), a potent inhibitor of cholinesterase (ChE), the numbers of dendritic spines of Golgi impregnated hippocampal pyramidal cells (CA1 sector) were evaluated within the first hour of the intoxication. Animals that experienced convulsions showed a rapid and striking decrease in the density of dendritic spines which could be reduced by nearly 80% of the controls in the basal dendrites 60 min post-soman exposure. Although the exact mechanisms cannot be determined from the present study, it is suggested that the spine loss may represent: (1) the first sign of the seizure-related neuronal changes which are known to occur later during soman intoxication; and (2) the expression of the ‘dendrotoxic’ effects produced by certain non-cholingergic excitatory transmitters such as glutamate.     

Dendritic spine density of adult hippocampal pyramidal cells is sensitive to thyroid hormone

In order to determine whether pyramidal cells of the adult hippocampus are morphologically sensitive to thyroid hormone, we performed single-section Golgi impregnation analyses on brains from hyperthyroid and control rats. Quantitative analyses of Golgi-impregnated pyramidal cells from the CA1 region showed a significant decrease in the density of apical dendritic spines with hyperthyroidism. In contrast, no changes were observed in spine density of basal dendrites or in cross-sectional cell body area of CA1 pyramidal cells. No changes in any of these morphological variables were detected in pyramidal cells of the CA3 region with hyperthyroidism. These results suggest that spine density of the apical dendrites of CA1 pyramidal cells is specifically affected by thyroid hormone in adulthood. Since dendritic spines are thought to represent postsynaptic sites it is likely that this morphological change results in altered hippocampal function.     

Dopamine decreases the calcium-activated afterhyperpolarization in hippocampal CA1 pyramidal cells

The effect of dopamine (DA) on the calcium-activated potassium conductance underlying the slow afterhyperpolarization (AHP) which follows a train of action potentials in hippocampal pyramidal cells was studied utilizing the in vitro hippocampal slice preparation. Bath-applied DA (1-100 microM) significantly reduced the AHP in a reversible, dose-dependent manner. Neither the amount of current injected to elicit the AHP nor its initial amplitude had an effect on the reduction of the AHP by DA. DA did not depress calcium spikes, suggesting that the blockade of the AHP likely occurs at a step subsequent to the entry of calcium. Since DA's actions on the AHP closely mimicked those of norepinephrine, we examined the effect of beta-adrenergic antagonists on DA's actions. At concentrations which in other systems have been shown not to block DA stimulated adenylate cyclase, beta-adrenergic antagonists completely inhibited the reduction of the AHP by DA. In some cells DA also elicited small hyperpolarizations which were not blocked by application of dopamine receptor antagonists. These findings strongly suggest that a major electrophysiological action of DA in the hippocampus (i.e. blockade of the AHP) is due to its cross reactivity with beta-adrenergic receptors and that rigid pharmacologic criteria must be used before attributing an action of DA unambiguously to its interaction with DA receptors.     

Myricetin protects hippocampal CA3 pyramidal neurons and improves learning and memory impairments in rats with Alzheimer's disease

There is currently no treatment for effectively slowing the progression of Alzheimer's disease, so early prevention is very important. Numerous studies have shown that flavonoids can improve memory impairment. The present study investigated the effects of myricetin, a member of the flavonoids, on intracerebroventricular streptozotocin induced neuronal loss and memory impairment in rat models of Alzheimer's disease. Myricetin at 5 or 10 mg/kg was intraperitoneally injected into rats over 21 days. Control rats were treated with 10 m L/kg saline. Behavioral test(the shuttle box test) was performed on day 22 to examine learning and memory in rats. Immediately after that, hematoxylin-eosin staining was performed to observe the morphological change in hippocampal CA3 pyramidal neurons. Myricetin greatly increased the number of hippocampal CA3 pyramidal neurons and improved learning and memory impairments in rats with Alzheimer's disease. These findings suggest that myricetin is beneficial for treatment of Alzheimer's disease.     

Protein malnutrition differentially alters the number of glutamic acid decarboxylase-67 interneurons in dentate gyrus and CA1-3 subfields of the dorsal hippocampus

In 30- and 90-day-old rats, using immunohistochemistry for glutamic acid decarboxylase 67 (GAD-67), we have tested whether malnutrition during different periods of hippocampal development produces deleterious effects on the population of GABA neurons in the dentate gyrus (DG) and cornu Ammonis (CA1-3) of the dorsal hippocampus. Animals were under one of four nutritional conditions: well-nourished controls (Con), prenatal protein malnourished (PreM), postnatal protein malnourished (PostM), and chronic protein malnourished (ChroM). We found that the number of GAD-67-positive (GAD-67+) interneurons was higher in the DG than in the CA1-3 areas of both Con and malnourished groups. Regarding the DG, the number of GAD-67+ interneurons was increased in PreM and PostM and decreased in ChroM at 30 days. At 90 days of age the number of GAD-67+ interneurons was increased in PostM and ChroM and remained unchanged in PreM. With respect to CA1-3, the number of labeled interneurons was decreased in PostM and ChroM at 30 days of age, but no change was found in PreM. At 90 days no changes in the number of these interneurons were found in any of the groups. These observations suggest that 1) the cell death program starting point is delayed in DG GAD-67+ interneurons, and 2) protein malnutrition differentially affects GAD-67+ interneuron development throughout the dorsal hippocampus. Thus, these changes in the number of GAD-67+ interneurons may partly explain the alterations in modulation of dentate granule cell excitability, as well as in the emotional, motivational, and memory disturbances commonly observed in malnourished rats.     

Blockade of U50488H on sodium currents in acutely isolated mice hippocampal CA3 pyramidal neurons

The effect of opioid agonist U50488H on Na(+) currents was examined in freshly dissociated hippocampal neurons of mice using the whole-cell patch clamp technique. U50488H (1-100 microM) caused a concentration dependent reversible inhibition of the voltage-activated sodium currents. IC50 of 15.5 microM and Hill constant of 1.4 were calculated respectively. The inhibitory actions of U50488H on I(Na) were still observed in the presence of 30 microM naloxone. Moreover, under the action of U50488H, repetitive stimulation induced further inhibition which was frequency-dependent. The activation curve did not change before and after application of 10 microM U50488H. However, after exposure to 10 microM U50488H and repetitive depolarizing at 10 Hz, frequency-dependent inhibition occurred, and a mean shift of half-activation membrane potential by +20 mV could be induced. The inactivation curve was significantly changed toward negative membrane potential with 10 microM U50488H, and further negative shift was observed after repetitive depolarizing at 10 Hz. Our results indicate that U50488H could directly inhibit neuronal Na(+) currents without involvement in the activation of kappa-opioid receptors.     

Unique somato-dendritic distribution pattern of Kv4.2 channels on hippocampal CA1 pyramidal cells

A-type K(+) current (I(A)) plays a critical role in controlling the excitability of pyramidal cell (PC) dendrites. In vitro dendritic patch-pipette recordings have demonstrated a prominent, sixfold increase in I(A) density along the main apical dendrites of rat hippocampal CA1 PCs. In these cells, I(A) is mediated by Kv4.2 subunits, whose precise subcellular distribution and densities in small-diameter oblique dendrites and dendritic spines are still unknown. Here we examined the densities of the Kv4.2 subunit in 13 axo-somato-dendritic compartments of CA1 PCs using a highly sensitive, high-resolution quantitative immunogold localization method (sodium dodecyl sulphate-digested freeze-fracture replica-labelling). Only an approximately 70% increase in Kv4.2 immunogold density was observed along the proximo-distal axis of main apical dendrites in the stratum radiatum with a slight decrease in density in stratum lacunosum-moleculare. A similar pattern was detected for all dendritic compartments, including main apical dendrites, small-diameter oblique dendrites and dendritic spines. The specificity of the somato-dendritic labelling was confirmed in Kv4.2(-/-) tissue. No specific immunolabelling for the Kv4.2 subunit was found in SNAP-25-containing presynaptic axons. Our results demonstrate a novel distribution pattern of a voltage-gated ion channel along the somato-dendritic surface of CA1 PCs, and suggest that the increase in the I(A) along the proximo-distal axis of PC dendrites cannot be solely explained by a corresponding increase in Kv4.2 channel number.     

Effects of GABA on CA3 pyramidal cell dendrites in rabbit hippocampal slices

Using the in vitro rabbit hippocampal slice preparation, we have investigated the effects of gamma-aminobutyric acid (GABA) iontophoresis on CA3 pyramidal cell dendrites. The predominant response (70% of the cells tested) was a hyperpolarization associated with a 30% decrease in cell input resistance (Rm). These hyperpolarizations displayed a very pronounced voltage dependency: they were decreased by cell depolarization and flattened by hyperpolarization. Bicuculline methiodide (BMI, 50 microM) did not abolish this response, nor did intracellular iontophoresis of chloride ions. In 5% of the cells, an additional hyperpolarization was obtained with longer ejection times; it reversed close to the reversal potential of the early component of the IPSP. In 25% of the cells, dendritic GABA application produced a depolarization. This response was reversed with cell membrane depolarization and was associated with a large (80%) decrease in Rm. The depolarizations were abolished by BMI (50 microM) and greatly increased by increasing the intracellular chloride concentration. None of the responses to GABA were affected by blockade of synaptic transmission. We conclude that the predominant response of CA3 pyramidal cell dendrites to GABA application is a hyperpolarization mediated by GABAB receptors and probably carried by potassium ions. The depolarizing responses are mediated via GABAA receptors and depend on an increase in chloride permeability.     

大荨麻提取物对糖尿病幼鼠中CA3海马锥体细胞密度的神经保护作用

背景：采取不同神经保护措施来恢复糖尿病相伴的受损认知功能和结果异常。目的：研讨荨麻提取物的神经保护作用,研究注射大荨麻提取物后糖尿病幼鼠的CA3海马子区中锥体细胞密度。设计,时间和地点：实验神经生物学研究,随进对照试验,于2006年至2007年在Gordan医学大学胚胎组织学教研室完成。材料：从伊朗北方gorgan郊区的栽培植物中提取大荨麻叶。由Mazandaran医科大学生药学进行分类学确认。20只白化病Wistar雄性大鼠,6-7周龄,购自伊朗巴斯德研究所（伊朗德黑兰）。方法：供分成四组,分别为对照组,糖尿病组,预防组和治疗组,每组包括5只6周龄大鼠。糖尿病组和治疗组动物,用80mg/kg链脲霉素诱导糖尿病模型。注射一周后,治疗组动物接受腹膜内注射每天100 mg/kg大荨麻含水酒精提取物。预防组前五天腹膜内注射100 mg/kg大荨麻含水酒精提取物,从第六天开始注射80mg/kg链脲霉素。主要观察指标：实验5周后,处死所有大鼠,右侧大脑半球的背部海马结构提取冠状切片,进行焦油紫染色。测量并比较四组中CA3区锥体细胞表面密度。结果：对照组,糖尿病组,预防组和治疗组的平均细胞密度分别是44.79±10.79, 41.20± 10.38, 41.06± 8.81和37.25± 8.26。同对照组相比,三个实验组的细胞密度均降低（P<0.05）。结论：尽管荨麻提取物对齿状回具有神经保护作用,大荨麻提取物对糖尿病幼鼠的CA3海马子区没有表现出显著的神经元保护作用。     

Hyperexcitability of CA3 pyramidal cells in mice lacking the potassium channel subunit Kv1.1

PURPOSE: To investigate further the membrane properties and postsynaptic potentials of the CA3 pyramidal cells in mice that display spontaneous seizures because of a targeted deletion of the Kcna1 potassium channel gene (encoding the Kv1.1 protein subunit). METHODS: Intracellular recordings were obtained from CA3 pyramidal cells in hippocampal slices prepared from Kcna1-null and control littermates. CA3 pyramidal cells were activated: orthodromically, by stimulating mossy fibers; antidromically, by activating Schaffer collaterals; and by injecting intracellular pulses of current. Responses evoked under these conditions were compared in both genotypes in normal extracellular medium (containing 3 mM potassium) and in medium containing 6 mM potassium. RESULTS: Recordings from CA3 pyramidal cells in Kcna1-null and littermate control slices showed similar membrane and action-potential properties. However, in 33% of cells studied in Kcna1-null slices bathed in normal extracellular medium, orthodromic stimulation evoked synaptically driven bursts of action potentials that followed a short-latency excitatory postsynaptic potential (EPSP)-inhibitory PSP (IPSP) sequence. Such bursts were not seen in cells from control slices. The short-latency gamma-aminobutyric acid (GABA)A-mediated IPSP event appeared similar in null and control slices. When extracellular potassium was elevated and excitatory synaptic transmission was blocked, antidromic activation or short pulses of intracellular depolarizing current evoked voltage-dependent bursts of action potentials in the majority of cells recorded in Kcna1 null slices, but only single spikes in control slices. CONCLUSIONS: Lack of Kv1.1 potassium channel subunits in CA3 pyramidal cells leads to synaptic hyperexcitability, as reflected in the propensity of these cells to generate multiple action potentials. The action-potential burst did not appear to result from loss of GABAA receptor-mediated inhibition. This property of CA3 neurons, seen particularly when tissue conditions become abnormal (e.g., elevated extracellular potassium), helps to explain the high seizure susceptibility of Kcna1-null mice.     

7-硝基吲唑对缺氧缺血新生大鼠海马CA1区神经元凋亡的影响

目的探讨选择性一氧化氮合酶(NOS)抑制剂7-硝基吲唑(7-NI)对缺氧缺血新生大鼠海马CA1区神经元凋亡的影响. 方法 7日龄Wistar大鼠72只,随机分成3组,(1)假手术组12只,仅作颈正中切口,不作颈总动脉结扎;(2)观察组(7-NI组)30只,缺氧缺血性脑损伤(HIBD)模型制作后即刻腹腔内注射7-NI 25 mg/kg;(3)对照组(生理盐水组)30只, HIBD后即刻腹腔注射等体积的生理盐水.假手术组于手术后即刻,观察组、对照组于处置后48小时断头取脑, 分别进行HE和TUNEL染色,光镜下检测脑细胞凋亡数. 结果 HE染色对照组大鼠海马CA1区可见典型的凋亡细胞,表现为细胞固缩,胞浆深染,核浓缩、碎片,核浆分布不清,有凋亡小体形成;7-NI组上述凋亡细胞明显减少;TUNEL染色对照组阳性细胞数与7-NI组比较差异有极显著性(P<0.01). 结论 7-NI对HIBD后海马CA1区神经细胞凋亡有明显的抑制作用.     

Evidence for neuronal interactions by electrical field effects in the CA3 and dentate regions of rat hippocampal slices

During population spikes in slices of rat hippocampus, transmembrane differential recordings (intracellular minus extracellular) revealed electrical field-effect depolarizations in CA3 pyramidal and dentate granule neurons. The field-effect depolarizations were not seen in single-ended recordings, and were consistently shown to increase neuronal excitability. Therefore, as previously shown for the CA1 area, large population spikes from CA3 pyramidal and dentate granule cells are associated with transmembrane depolarizations that increase neuronal excitability.     

Conduction latency along CA3 hippocampal axons from rat

Relatively few physiological studies have been carried out on intrahippocampal axons. We have recorded compound potentials from fiber groups and the activity of individual axons at 22-25 degrees C to characterize the conduction in subsets of the broad fan-shaped CA3 pyramidal axonal tree, including the Schaffer collaterals and longitudinal branches. The same wide axonal branching was indicated by antidromic activation of individual CA3 pyramidal cells. The average compound action potential latency from the CA3 to the CA1 area (Schaffer collaterals) increased by 4.16 +/- 0.06 ms/mm separation between the stimulation and registration electrodes. The impulses spread 31% faster in the 45-degree oblique temporal than in the transverse direction across CA1. The latency of the longitudinal axons in the CA3 area increased by 6.19 +/- 0.19 ms/mm. More impressive than these direction-dependent differences in latency were the large differences between individual axons running in the same direction. For both the longitudinal axons and the Schaffer collaterals, there was a broad distribution of antidromic latencies for a given distance between the stimulation and recording points. Typically, the fastest impulses arrived in half the time of the slowest. The distribution of compound action potential latencies between two points in the tissue could be made narrower by surgical restriction of the thickness and width of the preparation. By comparison, the cerebellar parallel fibers showed a narrower distribution of their latencies than the Schaffer collaterals. Because the cerebellar fibers run more straight than Schaffer collaterals, this suggested that some of the latency differences of the latter were due to differences in the path length of the axons. One consequence of our findings is that synchronous firing of neighboring CA3 pyramidal cells does not necessarily give synchronous inputs to common target CA1 neurons.