Calcium-dependent epileptogenesis in an in vitro model of stroke-induced "epilepsy"

PURPOSE: Stroke is the most common cause of acquired epilepsy. The purpose of this investigation was to characterize the role of calcium in the in vitro, glutamate injury-induced epileptogenesis model of stoke-induced epilepsy. METHODS: Fura-2 calcium imaging and whole-cell current clamp electrophysiology techniques were used to measure short-term changes in neuronal free intracellular calcium concentration and long-term alterations in neuronal excitability in response to epileptogenic glutamate injury (20 microM, 10 min) under various extracellular calcium conditions and in the presence of different glutamate-receptor antagonists. RESULTS: Glutamate injury-induced epileptogenesis was associated with prolonged, reversible elevations of free intracellular calcium concentration during and immediately after injury and chronic hyperexcitability manifested as spontaneous recurrent epileptiform discharges for the remaining life of the cultures. Epileptogenic glutamate exposure performed in solutions containing low extracellular calcium, barium substituted for calcium, or N-methyl-d-aspartate (NMDA)-receptor antagonists reduced the duration of intracellular calcium elevation and inhibited epileptogenesis. Antagonism of non-NMDA-receptor subtypes had no effect on glutamate injury-induced calcium changes or the induction epileptogenesis. The duration of the calcium elevation and the total calcium load statistically correlated with the development of epileptogenesis. Comparable elevations in neuronal calcium induced by non-glutamate receptor-mediated pathways did not cause epileptogenesis. CONCLUSIONS: This investigation indicates that the glutamate injury-induced epileptogenesis model of stroke-induced epilepsy is calcium dependent and requires NMDA-receptor activation. Further, these experiments suggest that prolonged, reversible elevations in neuronal free intracellular calcium initiate the long-term plasticity changes that underlie the development of injury-induced epilepsy.     

Cell type-selective expression of green fluorescent protein and the calcium indicating protein,yellow cameleon,in rat cortical primary cultures

A cell type-specific green fluorescent protein (GFP) expression system in rat cortical primary cultures has been developed for the fluorescence labeling of brain cells. Lipid-mediated transfection (lipofection) was employed, allowing the establishment of a convenient efficient system for the analysis of individual cells. To achieve cell type-specific labeling, GFP expression vectors containing the rat neuron-specific enolase (NSE) gene promoter, human glial fibril acidic protein (GFAP) gene promoter, human elongation factor (EF-1alpha) gene promoter, or human cytomegalovirus (CMV) immediate early promoter were constructed, and their specificities examined. Vectors containing the CMV or GFAP promoter resulted primarily in GFP expression in astrocytes, while those containing the EF1-alpha or NSE promoter resulted primarily in GFP expression in neurons. This labeling system was applied to the morphological analysis of living neurons and to cell type-selective calcium imaging. Confocal microscopy revealed that individual GFP-expressing neurons had processes, which were longer than 500 microm and bore spine-like protrusions. A calcium-indicating GFP variant, yellow cameleon (YC2.1), was expressed in the same system, and cell type-selective calcium imaging performed. On pharmacological stimulation, YC2.1-expressing neurons responded to depolarizing stimuli, but not to the metabotropic glutamate receptor agonist, trans-(1S,3R)-1-amino-1,3-cyclopentanedicarboxylic acid (tACPD), while astrocytes responded only to tACPD.     

Estrogen induces a rapid increase of calcium-calmodulin-dependent protein kinase II activity in the hippocampus

Molecular genetics experiments using gene targeting and transgenic technology demonstrated the importance of -calcium-calmodulin-dependent protein kinase II (CaMKII) in long-term potentiation (LTP) and memory. Little information is available though on how CaMKII activity may be regulated in vivo. We show that estradiol benzoate activates CaMKII in a dose and time-dependent manner in mouse hippocampus after 30 min stimulation. The effect of estrogen is via a very rapid nongenomic mechanism that is blocked in vitro in hippocampal primary neurons by the pure estrogen receptor antagonist, ICI 182,780. These results suggest that estrogen action in the hippocampus is linked to CaMKII activation.     

Role of TRH receptors as possible mediators of analeptic actions of TRH-like peptides

A large family of TRH-like peptides in the limbic region of rat brain including pGlu-Glu-Pro-NH(2) (EEP), pGlu-Val-Pro-NH(2) (Val(2)-TRH), Leu(2)-TRH, Phe(2)-TRH and Tyr(2)-TRH has recently been discovered. TRH (pGlu-His-Pro-NH(2)) has antidepressant, neuroprotective, analeptic, anticonvulsant, antiamnesic and euphoric properties, and other TRH-like peptides such as EEP exert several of these effects. A new TRH receptor (TRHR2) has been reported which is highly expressed in regions of rat brain that regulate attention and learning, arousal, sleep and processing of sensory information. The TRHR1 predominates in limbic structures involved in regulation of mood and in pituitary. This study examined the possibility that some of the newly discovered TRH-like peptides bind with high affinity to TRHR2, and that this receptor acts as the transducer for some of the CNS effects of this new class of neuropeptides. EEP, Val(2)-TRH and Leu(2)-TRH were analeptics, like TRH, but Phe(2)-TRH and Tyr(2)-TRH were not. The affinity and efficacy of TRH-like peptides for TRHR1 and TRHR2 were measured in HEK293 cells stably expressing these receptors. The IC(50) values of TRH-like peptides for displacement of [3H]TRH from TRHR2 were TRH<(Leu(2)-, Phe(2)-TRH)<(Gln(2)-, Ser(2)-TRH)<(Val(2)-, Tyr(2)-, Arg(2)-, Thr(2)-, and Glu(2)-TRH). The IC(50) for Leu(2)-TRH was about 100 times that for TRH. When tested at the calculated IC(50) values, TRH-like peptides stimulated calcium responses in cells expressing TRHR1 and TRHR2, indicating that the peptides act as weak agonists at both receptors. These results indicate that TRHR1 and TRHR2 do not mediate the behavioral effects of TRH-like peptides.     

Histamine H1 receptors in rat dorsal raphe nucleus: pharmacological characterisation and linking to increased neuronal activity

In this work we studied the presence of histamine H(1) receptors in the rat dorsal raphe nucleus (DRN) and the effect of their activation on the activity of presumed serotonergic DRN neurones. [(3)H]-Mepyramine bound to DRN membranes with best-fit values of 107+/-13 fmol/mg protein for maximum binding (B(max)) and 1.2+/-0.4 nM for the equilibrium dissociation constant (K(d)). In DRN slices labelled with [(3)H]-inositol and in the presence of 10 mM LiCl, histamine stimulated the accumulation of [(3)H]-inositol phosphates ([(3)H]-IPs) with maximum effect 172+/-6% of basal and EC(50) 3.2+/-1.3 microM. [(3)H]-IPs accumulation induced by 100 microM histamine (162+/-5% of basal) was markedly, but not fully blocked by the selective H(1) antagonist mepyramine (300 nM; 64+/-6% inhibition). The simultaneous addition of mepyramine and the selective H(2) antagonist ranitidine (10 microM) abolished histamine-induced [(3)H]-IPs accumulation. The presence of H(2) receptors was confirmed by [(3)H]-tiotidine binding and by the determination of histamine-induced [(3)H]-cyclic AMP formation. Extracellular single-unit recording in brain stem slices showed that the exposure to histamine resulted in a marked increase in the firing rate of DRN presumed serotonergic neurones (471+/-10% of basal), that was dependent on the concentration of the agonist (EC(50) 4.5+/-0.3 microM). The action of histamine was not affected by the H(2) antagonist tiotidine (2 microM) but was fully prevented by 1 microM mepyramine. Taken together, our results indicate that histamine modulates the firing of DRN presumed serotonergic neurones through the activation of H(1) receptors coupled to phosphonositide hydrolysis.     

The tractable contribution of synapses and their component molecules to individual differences in learning

Though once of central importance to psychologists and neurophysiologists alike, the elucidation of neural substrates for individual differences in learning no longer attracts a broad research effort and occupies a place of largely historical interest to the contemporary disciplines. The decline in interest in this subject ensued in part from the perception, arrived at decades ago, that individual differences in learning were not quantified as easily as had once been presumed. Furthermore, the dominant hypotheses in the field defied testing within the constraints imposed by the complex and largely inaccessible vertebrate nervous system. Using a ‘model systems’ approach where the individual cells and synaptic interactions that comprise a neural network can be identified, we have returned to this question and have established a framework by which we can begin to discern the basis for much of the variability between individuals in their capacity to learn. In the marine mollusc Hermissenda, we have found that a common influence on transmitter exocytosis is expressed homogeneously throughout the nervous system regardless of transmitter system or receptor class. Though uniformly expressed within an individual, this influence on synaptic efficacy is differentially expressed between animals. Importantly, the basal efficiency of exocytosis expressed in an individual nervous system is strongly correlated with the degree to which activity-dependent forms of neuronal/synaptic facilitation can be induced in that nervous system, and predicts the capacity for the intact animal to learn a Pavlovian association. Furthermore, we have established that a decline in basal synaptic efficacy in aged animals, arising from chronic presynaptic Ca²⁺ ‘leak’, may contribute to age-related learning impairments. Because certain fundamental components of the exocytotic cascade are conserved widely across cell types, transmitter systems and species, the principles that we describe may have broad implications for understanding normal variability in learning, but also, in the development of specific strategies to compensate for mild learning deficits and age-related cognitive decline.     

Role of calcium in neuronal cell injury: which subcellular compartment is involved?

It is widely believed that calcium plays a primary role in the development of neuronal cell injury in different pathological states of the brain. Disturbances of calcium homeostasis may be induced in three different subcellular compartments, the cytoplasm, mitochondria or the endoplasmic reticulum (ER). The traditional calcium hypothesis holds that neuronal cell injury is induced by a marked increase in cytoplasmic calcium activity during stress (e.g., cerebral ischemia). Recently, this hypothesis has been modified, taking into account that under different experimental conditions the extent of cell injury does not correlate closely with calcium load or total calcium influx into the cell, and that neuronal cell injury has been found to be associated with both increases and decreases of cytoplasmic calcium activity. The mitochondrial calcium hypothesis is based on the observation that after a severe form of stress there is a massive influx of calcium ions into mitochondria, which may lead to production of free radicals, opening of the mitochondrial permeability transition (MPT) pore and disturbances of energy metabolism. However, it has still to be established whether drugs such as cyclosporin A are neuroprotective through their effect on MPT or through the blocking of processes upstream of MPT. The ER calcium hypothesis arose from the observation that ER calcium stores are depleted after severe forms of stress, and that the response of cells to disturbances of ER calcium homeostasis (activation of the expression of genes coding for ER resident stress proteins and suppression of the initiation of protein synthesis) resembles their response to a severe form of stress (e.g., transient ischemia) implying common underlying mechanisms. Elucidating the exact mechanisms of calcium toxicity and identifying the subcellular compartment playing the most important role in this pathological process will help to evaluate strategies for specific therapeutic intervention.     

高效液相色谱法测定二维钙赖氨酸片中维生素B_1含量

目的探讨二维钙赖氨酸片中维生素B1(VitB1)的含量测定方法。方法高效液相色谱法。色谱柱为GeminiC18柱(250mm×4.6mm,5μm),流动相为内含5mmol/L庚烷磺酸钠、以磷酸调节pH值至3.5的乙腈-水-三乙胺(16∶84∶0.3)溶液,检测波长为245nm,流速为1.0mL/min。结果VitB1线性范围是0.05～0.25μg,r=0.99999,平均回收率为98.99%,RSD=0.65%。结论方法灵敏快速,结果准确,重现性好,可用于该制剂的质量控制。     

离子选择性电极法测定离子钙

钙是体内生存离不开的元素，离子钙是生理活性钙，它比总钙更能反映出体内钙的代谢状态。钙的正常值范围小，更需要掌握其特点，创造良好的实验条件，用离子选择性电极法（ISE）测定钙优点较多，比EDTA滴定法精确度大，我们用ISE法测钙收到满意效果。