Repetitive pulsed-wave ultrasound stimulation suppresses neural activity by modulating ambient GABA levels via effects on astrocytes.

Ultrasound is highly biopermeable and can non-invasively penetrate deep into the brain. Stimulation with patterned low-intensity ultrasound can induce sustained inhibition of neural activity in humans and animals, with potential implications for research and therapeutics. Although mechanosensitive channels are involved, the cellular and molecular mechanisms underlying neuromodulation by ultrasound remain unknown. To investigate the mechanism of action of ultrasound stimulation, we studied the effects of two types of patterned ultrasound on synaptic transmission and neural network activity using whole-cell recordings in primary cultured hippocampal cells. Single-shot pulsed-wave (PW) or continuous-wave (CW) ultrasound had no effect on neural activity. By contrast, although repetitive CW stimulation also had no effect, repetitive PW stimulation persistently reduced spontaneous recurrent burst firing. This inhibitory effect was dependent on extrasynaptic-but not synaptic-GABAA receptors, and the effect was abolished under astrocyte-free conditions. Pharmacological activation of astrocytic TRPA1 channels mimicked the effects of ultrasound by increasing the tonic GABAA current induced by ambient GABA. Pharmacological blockade of TRPA1 channels abolished the inhibitory effect of ultrasound. These findings suggest that the repetitive PW low-intensity ultrasound used in our study does not have a direct effect on neural function but instead exerts its sustained neuromodulatory effect through modulation of ambient GABA levels via channels with characteristics of TRPA1, which is expressed in astrocytes.

Syntaxin 1B regulates synaptic GABA release and extracellular GABA concentration, and is associated with temperature-dependent seizures.

De novo heterozygous mutations in the STX1B gene, encoding syntaxin 1B, cause a familial, fever-associated epilepsy syndrome. Syntaxin 1B is an essential component of the pre-synaptic neurotransmitter release machinery as a soluble N-ethylmaleimide-sensitive factor attachment protein receptor protein that regulates the exocytosis of synaptic vesicles. It is also involved in regulating the functions of the SLC6 family of neurotransmitter transporters that reuptake neurotransmitters, including inhibitory neurotransmitters, such as γ-aminobutyric acid (GABA) and glycine. The purpose of the present study was to elucidate the molecular mechanisms underlying the development of febrile seizures by examining the effects of syntaxin 1B haploinsufficiency on inhibitory synaptic transmission during hyperthermia in a mouse model. Stx1b gene heterozygous knockout (Stx1b+/- ) mice showed increased susceptibility to febrile seizures and drug-induced seizures. In cultured hippocampal neurons, we examined the temperature-dependent properties of neurotransmitter release and reuptake by GABA transporter-1 (GAT-1) at GABAergic neurons using whole-cell patch-clamp recordings. The rate of spontaneous quantal GABA release was reduced in Stx1b+/- mice. The hyperthermic temperature increased the tonic GABAA current in wild-type (WT) synapses, but not in Stx1b+/- synapses. In WT neurons, recurrent bursting activities were reduced in a GABA-dependent manner at hyperthermic temperature; however, this was abolished in Stx1b+/- neurons. The blockade of GAT-1 increased the tonic GABAA current and suppressed recurrent bursting activities in Stx1b+/- neurons at the hyperthermic temperature. These data suggest that functional abnormalities associated with GABA release and reuptake in the pre-synaptic terminals of GABAergic neurons may increase the excitability of the neural circuit with hyperthermia.

Syntaxin 1B contributes to regulation of the dopaminergic system through GABA transmission in the CNS.

In neuronal plasma membrane, two syntaxin isoforms, HPC-1/syntaxin 1A (STX1A) and syntaxin 1B (STX1B), are predominantly expressed as soluble N-ethylmaleimide-sensitive fusion attachment protein receptors, also known as t-SNAREs. We previously reported that glutamatergic and GABAergic synaptic transmissions are impaired in Stx1b null mutant (Stx1b-/- ) mice but are almost normal in Stx1a null mutant (Stx1a-/- ) mice. These observations suggested that STX1A and STX1B have distinct functions in fast synaptic transmission in the central nervous system (CNS). Interestingly, recent studies indicated that Stx1a-/- or Stx1a+/- mice exhibit disruption in the monoaminergic system in the CNS, causing unusual behaviour that is similar to neuropsychological alterations observed in psychiatric patients. Here, we studied whether STX1B contributes to the regulation of monoaminergic system and if STX1B is related to neuropsychological properties in human neuropsychological disorders similar to STX1A. We found that monoamine release in vitro was normal in Stx1b+/- mice unlike Stx1a-/- or Stx1a+/- mice, but the basal extracellular dopamine (DA) concentration in the ventral striatum was increased. DA secretion in the ventral striatum is regulated by GABAergic neurons, and Stx1b+/- mice exhibited reduced GABA release both in vitro and in vivo, disrupting the DAergic system in the CNS of these mice. We also found that Stx1b+/- mice exhibited reduced pre-pulse inhibition (PPI), which is believed to represent one of the prominent schizotypal behavioural profiles of human psychiatric patients. The reduction in PPI was rescued by DA receptor antagonists. These observations indicated that STX1B contributes to excess activity of the DAergic system through regulation of GABAergic transmission.

Super-Protective Child-Rearing by Japanese Bess Beetles, Cylindrocaulus patalis: Adults Provide Their Larvae with Chewed and Predigested Wood.

Beetles of the family Passalidae (Coleoptera: Scarabaeoidea) are termed subsocial. The insects inhabit rotten wood as family groups consisting of the parents and their offspring. The Japanese species Cylindrocaulus patalis has the lowest fecundity among passalids because siblicide occurs among the first-instar larvae; accordingly, parental care toward the survived larva is the highest among Passalidae. To clarify the nutritional relationships between the parents and their offspring, we investigated their ability to digest three types of polysaccharides that are components of wood (cellulose and ß-1,4-xylan) and fungal cell walls (ß-1,3-glucan). Although carboxymethyl-cellulase activity was barely detectable, ß-xylosidase, ß-glucosidase, ß-1,4-xylanase and ß-1,3-glucanase activities were clearly detected in both adults and larvae. Because the activities of enzymes that digest ß-1,3-glucan were much higher than those for degrading ß-1,4-xylan, in both adults and larvae, it is concluded that they are mainly fungivorous. Furthermore, these digestive enzymatic activities in second- and third-instar larvae were much lower than they were in adults. Although all larval instars grew rapidly when fed chewed wood by their parents, larvae ceased growing and died when fed only artificially ground wood meals. We conclude that the larvae are assumed to be provided with chewed predigested wood in which ß-1,3-glucan is degraded by parental enzymes.

Data for the effects of ER and Golgi stresses on the ER-Golgi SNARE Syntaxin5 expression and on the ßAPP processing in cultured hippocampal neurons.

This paper reports the data for the effects of organelle stresses on the ER-Golgi-soluble N-ethylmaleimide-sensitive factor-attachment protein receptors (ER-Golgi SNAREs) syntaxin 5 (Syx5) in neuronal cells. Quantitative as well as qualitative data are presented here to verify the upregulation of Syntaxin 5 (Syx5) under ER and Golgi stresses in hippocampal neurons. Changes in the processing of ß-amyloid precursor protein (ßAPP) under ER stress were analyzed by immunological assays. In addition, our data shows the specific increase of Syx5 expression under ER and Golgi stresses. Interpretation of our data and further extensive insights into the role of Syx5 in ßAPP processing under organelle stress can be found in "ER and Golgi stresses increase ER-Golgi SNARE Syntaxin5: Implications for organelle stress and ßAPP processing" [1].

ER and Golgi stresses increase ER-Golgi SNARE Syntaxin5: Implications for organelle stress and ßAPP processing.

Unresolved endoplasmic reticulum (ER) stress causes neuronal death and has been implicated in neurodegenerative conditions such as Alzheimer's disease (AD). However, the mechanisms by which stress signals propagate from the ER through the Golgi apparatus and their effects on the transport and processing of AD-related proteins, such as ß-amyloid precursor protein (ßAPP), are unknown. We recently found that in the NG108-15 cell line, ER stress upregulates ER-Golgi-soluble N-ethylmaleimide-sensitive factor-attachment protein receptors (ER-Golgi SNAREs) Syx5 and Bet1. In the present study, we examined the effects of apoptosis and ER stress inducers on the expression of ER-Golgi SNARE proteins and cell viability in a primary culture of rat hippocampal neurons. An apoptosis inducer significantly downregulated the expression of ER-Golgi SNARE Syx5. ER-stress inducers upregulated the expression of Syx5 isoforms and Bet1 proteins via de novo synthesis of their mRNA transcripts. Knockdown of Syx5 during apoptosis or ER stress induction enhanced vulnerability of neurons. Additionally, we examined the effects of Golgi stress on Syx5 expression and ßAPP processing. Golgi stress also induced upregulation of ER-Golgi SNARE Syx5, and concomitantly, suppressed amyloid-ß peptide secretion. These findings suggest that Syx5 is a potential stress responsive factor that participates in ßAPP processing and the survival pathways of neuronal cells.

Syntaxin 1B, but not syntaxin 1A, is necessary for the regulation of synaptic vesicle exocytosis and of the readily releasable pool at central synapses.

Two syntaxin 1 (STX1) isoforms, HPC-1/STX1A and STX1B, are coexpressed in neurons and function as neuronal target membrane (t)-SNAREs. However, little is known about their functional differences in synaptic transmission. STX1A null mutant mice develop normally and do not show abnormalities in fast synaptic transmission, but monoaminergic transmissions are impaired. In the present study, we found that STX1B null mutant mice died within 2 weeks of birth. To examine functional differences between STX1A and 1B, we analyzed the presynaptic properties of glutamatergic and GABAergic synapses in STX1B null mutant and STX1A/1B double null mutant mice. We found that the frequency of spontaneous quantal release was lower and the paired-pulse ratio of evoked postsynaptic currents was significantly greater in glutamatergic and GABAergic synapses of STX1B null neurons. Deletion of STX1B also accelerated synaptic vesicle turnover in glutamatergic synapses and decreased the size of the readily releasable pool in glutamatergic and GABAergic synapses. Moreover, STX1A/1B double null neurons showed reduced and asynchronous evoked synaptic vesicle release in glutamatergic and GABAergic synapses. Our results suggest that although STX1A and 1B share a basic function as neuronal t-SNAREs, STX1B but not STX1A is necessary for the regulation of spontaneous and evoked synaptic vesicle exocytosis in fast transmission.

HPC-1/syntaxin 1A and syntaxin 1B play distinct roles in neuronal survival.

Two types of syntaxin 1 isoforms, HPC-1/syntaxin 1A (STX1A) and syntaxin 1B (STX1B), are thought to have similar functions in exocytosis of synaptic vesicles. STX1A(-/-) mice which we generated previously develop normally, possibly because of compensation by STX1B. We produced STX1B(-/-) mice using targeted gene disruption and investigated their phenotypes. STX1B(-/-) mice were born alive, but died before postnatal day 14, unlike STX1A(-/-) mice. Morphologically, brain development in STX1B(-/-) mice was impaired. In hippocampal neuronal culture, the cell viability of STX1B(-/-) neurons was lower than that of WT or STX1A(-/-) neurons after 9 days. Interestingly, STX1B(-/-) neurons survived on WT or STX1A(-/-) glial feeder layers as well as WT neurons. However, STX1B(-/-) glial feeder layers were less effective at promoting survival of STX1B(-/-) neurons. Conditioned medium from WT or STX1A(-/-) glial cells had a similar effect on survival, but that from STX1B(-/-) did not promote survival. Furthermore, brain-derived neurotrophic factor (BDNF) or neurotrophin-3 supported survival of STX1B(-/-) neurons. BDNF localization in STX1B(-/-) glial cells was disrupted, and BDNF secretion from STX1B(-/-) glial cells was impaired. These results suggest that STX1A and STX1B may play distinct roles in supporting neuronal survival by glia. Syntaxin 1A (STX1A) and syntaxin 1B (STX1B) are thought to have similar functions as SNARE proteins. However, we found that STX1A and STX1B play distinct roles in neuronal survival using STX1A(-/-) mice and STX1B(-/-) mice. STX1B was important for neuronal survival, possibly by regulating the secretion of neurotrophic factors, such as BDNF, from glial cells.

FRET-based evaluation of Bid cleavage in a single primary cultured neuron.

Apoptosis is a cell death modality that is initiated by the activation of caspases. Theoretically, fluorescence resonance energy transfer (FRET) analysis should be a convenient tool for visualizing the activation of caspase. Since the FRET probe cannot be transfected in primary neuronal cultures effectively, the FRET signal is not sufficiently strong for evaluations. We developed a method of extracting the significant signals from the fluorescent FRET images that enables the initiation of apoptosis to be analyzed. We used primary hippocampal cultures transfected with a vector encoding Bid fused with YFP and CFP. Apoptosis was induced using staurosporine (STS; 1µM). The CFP and YFP signals were observed using an inverted fluorescence microscope and were processed using imaging software for analysis. After the background signal was subtracted, the area of caspase activation and the significant signals were extracted from the localized intense signals originating from mitochondria. The CFP and YFP intensities of a selected area in a single neuron were integrated, and the CFP/YFP ratio was obtained. To confirm caspase activation in a similar experimental setting, a luminescence analysis was also performed. The FRET signals from the cultured neuron were confined to foci, since the Bid linker was specifically localized in the mitochondria. The extracted CFP and YFP signals from the foci were strong enough to be evaluated. The average CFP/YFP ratio in the neuron increased significantly after an STS challenge, from 0.673±0.024 (control) to 1.008±0.134 (STS) (mean±SD) (P<0.05). Our study demonstrated, for the first time, the quantification of Bid cleavage as expressed by FRET in a primary neuron. Since Bid is localized in the mitochondria, the region of interest was restricted to a specific area, enabling the signal to be analyzed. This methodology may be useful for the application of FRET analyses in primary cultured cells.

Impairment of catecholamine systems during induction of long-term potentiation at hippocampal CA1 synapses in HPC-1/syntaxin 1A knock-out mice.

The membrane protein HPC-1/syntaxin 1A is believed to play a key role in synaptic vesicle exocytosis, and it was recently suggested to be required for synaptic plasticity. Despite evidence for the function of HPC-1/syntaxin 1A in synaptic plasticity, the underlying cellular mechanism is unclear. We found that although fast synaptic transmission and long-term depression were unaffected, HPC-1/syntaxin 1A knock-out (STX1A(-/-)) mice showed impaired long-term potentiation (LTP) in response to theta-burst stimulation in CA1 hippocampal slices. The impairment in LTP was rescued by the application of forskolin, an adenylyl cyclase activator, or more robust stimulation, suggesting that cAMP/protein kinase A signaling was suppressed in these mice. In addition, catecholamine release from the hippocampus was significantly reduced in STX1A(-/-) mice. Because HPC-1/syntaxin 1A regulates exocytosis of dense-core synaptic vesicles, which contain neuromodulatory transmitters such as noradrenaline, dopamine and 5-HT, we examined the effect of neuromodulatory transmitters on LTP induction. Noradrenaline and dopamine enhanced LTP induction in STX1A(-/-) mice, whereas catecholamine depletion reduced LTP induction in wild-type mice. Theses results suggest that HPC-1/syntaxin 1A regulates catecholaminergic systems via exocytosis of dense-core synaptic vesicles, and that deletion of HPC-1/syntaxin 1A causes impairment of LTP induction.

Neurons associated with the flip-flop activity in the lateral accessory lobe and ventral protocerebrum of the silkworm moth brain.

The lateral accessory lobe (LAL) and the ventral protocerebrum (VPC) are a pair of symmetrical neural structures in the insect brain. The LAL-VPC is regarded as the major target of olfactory responding neurons as well as the control center for olfactory-evoked sequential zigzag turns. Previous studies of the silkworm moth Bombyx mori showed that these turns are controlled by long-lasting anti-phasic activities of the flip-flopping descending neurons with dendrites in the LAL-VPC. To elucidate the neural mechanisms underlying the generation of this alternating activity between the LAL-VPC units of both hemispheres, we first analyzed the detailed neural architecture of the LAL-VPC and identified five subregions. We then investigated the morphology and physiological responses of the LAL-VPC neurons by intracellular recording and staining and morphologically identified three types of bilateral neurons and three types of unilateral neurons. Bilateral neurons showed either brief or cyclic long-lasting responses. At least some neurons of the latter type produced gamma-aminobutyric acid (GABA). Unilateral neurons linking the LAL and VPC, in contrast, showed long-lasting or quick alternating activity. Timing analysis of the activity onset of each neural type suggests that quick reciprocal neural transmission between unilateral neurons would be responsible for the generation of long-lasting activity in one LAL-VPC unit, which lasts for up to a few seconds. Reciprocal inhibition and excitation by the bilateral neurons with long-lasting activities would mediate the alternating long-lasting activity between both LAL-VPC units, which might last for up to 20 seconds.

Ca(2+) buffering capacity of mitochondria after oxygen-glucose deprivation in hippocampal neurons.

In an earlier study, we showed that mitochondria hyperpolarized after short periods of oxygen-glucose deprivation (OGD), and this response appeared to be associated with subsequent apoptosis or survival. Here, we demonstrated that hyperpolarization following short periods of OGD (30 min; 30OGD group) increased the cytosolic Ca(2+) ([Ca(2+)](c)) buffering capacity in mitochondria. After graded OGD (0 min (control), 30 min, 120 min), rat cultured hippocampal neurons were exposed to glutamate, evoking Ca(2+)influx. The [Ca(2+)](c) level increased sharply, followed by a rapid increase in mitochondrial Ca(2+) [Ca(2+)](m). The increase in the [Ca(2+)](m) level accompanied a reduction in the [Ca(2+)](c) level. After reaching a peak, the [Ca(2+)](c) level decreased more rapidly in the 30OGD group than in the control group. This buffering reaction was pronounced in the 30OGD group, but not in the 120OGD group. The enhanced buffering capacity of the mitochondria may be linked to preconditioning after short-term ischemic episodes.

Calcium loading capacity and morphological changes in mitochondria in an ischemic preconditioned model.

The concept of the mitochondrial permeability transition (mPT) has been used to explain cell death induced by calcium deregulation, which is in turn induced by a disruption in the mitochondrial loading capacity of cytosolic calcium (CLC). Whether mitochondria have specific morphologies representing the CLC and the mPT remains controversial. We examined ultrastructural changes in the mitochondria of cultured hippocampal neurons preconditioned with oxygen-glucose deprivation (OGD) for 30 min (30OGD) or 120 min (120OGD). The CLC was then evaluated using simultaneous imaging of the mitochondrial and plasma Ca++ concentrations after the induction of Ca++ influx by the application of glutamate. In the 30OGD group, the CLC increased as the mitochondria rapidly reacted to the increase in plasma Ca++, which was soon cleared. In the 120OGD group, however, the CLC was disturbed because the mitochondrial uptake of Ca was blunted, and the plasma Ca++ was not cleared after glutamate application. We classified the specific morphological changes in the mitochondria according to a previously reported classification. Rounded mitochondria with scarce interior content were observed in the 120OGD group, a model of prolonged lethal OGD, and disruptions in the mitochondrial outer membrane were frequently confirmed, suggesting mPT. The 30OGD group, a model of enhanced CLC in preconditioned neurons, was characterized by round mitochondria with condensed matrices. After glutamate application, the mitochondria became even more rounded with expanded matrices, and outer membrane disruptions were occasionally seen. Our observations suggest that subpopulations of mitochondria with specific morphologies are linked to the CLC and mPT.

Neuroprotective effect of propofol on necrosis and apoptosis following oxygen-glucose deprivation--relationship between mitochondrial membrane potential and mode of death.

Mitochondrial membrane potential (MMP) appears to play an important role in apoptotic cascade and has been proposed as an index for apoptosis or necrosis. We examined the neuroprotective effect of propofol on mode of death, focusing on MMP. Hippocampal cell culture was divided into three groups: control, oxygen-glucose deprivation for 30 min (30OGD), 90 min (90OGD). Propofol was added to each culture group at a concentration of 0 microM (Vehicle), 0.1 microM (Pro0.1) or 1.0 microM (Pro1.0). MMP was expressed as normalized JC-1 fluorescence. ATP content was assayed using the luciferin-luciferase reaction. Neuronal viability and appearance of apoptosis were also assessed. ATP content was decreased after OGD (0.276 +/- 0.115 microM/microg (control), 0.172 +/- 0.125 microM/microg (30OGD) and 0.096 +/- 0.092 microM/microg (90OGD)). Propofol did not alter ATP content. MMP was hyperpolarized after 30OGD (1.26 +/- 0.23 (vehicle), 1.29 +/- 0.13 (Pro0.1) and 1.18 +/- 0.06 (Pro1.0)) but was depolarized after 90OGD (0.77 +/- 0.04 (vehicle), 0.89 +/- 0.04 (Pro0.1), but Pro1.0 prevented depolarization (1.03 +/- 0.15 (P < 0.05)). Viability of cells significantly decreased to 50.3 +/- 5.7% (vehicle), 46.1 +/- 7.5% (Pro0.1), but Pro1.0 significantly salvaged neurons 65.1 +/- 6.2% (higher than vehicle and Pro0.1 value, P < 0.05) after 90OGD. At 24 h after OGD, TUNEL-positive cells were increased to 34.5 +/- 6.2% (vehicle), 26.7 +/- 7.9% (Pro0.1) and 30.4 +/- 7.1% (Pro1.0) in the 30OGD group. No pharmacological effect of propofol on the incidence of apoptosis was found. Propofol inhibited acute neuronal death accompanied with the maintenance of MMP but did not prevent subsequent apoptosis. Propofol induces a moratorium on neuronal death, during which pharmacological intervention might be able to prevent cell death.

Analysis of knock-out mice to determine the role of HPC-1/syntaxin 1A in expressing synaptic plasticity.

The protein HPC-1/syntaxin 1A is abundantly expressed in neurons and localized in the neuronal plasma membrane. It forms a complex with SNAP-25 (25 kDa synaptosomal-associated protein) and VAMP-2 (vesicle-associated membrane protein)/synaptobrevin called SNARE (a soluble N-ethylmaleimide-sensitive fusion protein attachment protein receptor) complex, which is considered essential for synaptic vesicle exocytosis; thus, HPC-1/syntaxin 1A is considered crucial for synaptic transmission. To examine the physiological function of HPC-1/syntaxin 1A in vivo, we produced knock-out (KO) mice by targeted gene disruption. Although HPC-1/syntaxin 1A expression was completely depleted without any effect on the expression of other SNARE proteins, the KO mice were viable. They grew normally, were fertile, and displayed no difference in appearance compared with control littermate. In cultured hippocampal neurons derived from the KO mice, the basic synaptic transmission in vitro was normal. However, the mutant mice had impaired long-term potentiation in the hippocampal slice. Also, although KO mice exhibited normal spatial memory in the hidden platform test, consolidation of conditioned fear memory was impaired. Interestingly, the KO mice had impaired conditioned fear memory extinction. These observations suggest that HPC-1/syntaxin 1A may be closely related to synaptic plasticity.

Mitochondrial hyperpolarization after transient oxygen-glucose deprivation and subsequent apoptosis in cultured rat hippocampal neurons.

Mitochondrial membrane potential (MMP) regulates the production of high-energy phosphate and apoptotic cascade, both occurring after ischemic impact. The timed profile of MMP differing from grading ischemic impact has to be determined. Primary rat hippocampal cultures were exposed to oxygen-glucose deprivation (OGD) for 30, 60, and 90 min and then were reoxygenated. MMP was expressed as a voltage-dependent dye, JC-1 fluorescence, under confocal microscopy. Cell viability was assessed by calcein AM and ethidium homodimer, each at 3 hours and 24 hours after 30, 60, and 90 min of OGD. The appearance of apoptosis was also evaluated by the TUNEL method at 24 hours. Hyperpolarization of MMP (2.31+/-0.94 normalized JC-1 fluorescence ratio between red and green) was observed during reoxygenation after 30 min OGD, while 60 min OGD induced depolarization (0.66+/-0.22, Valinomycin (potassium ionophore)-induced depolarization: 0.53+/-0.19). The fluorescence of mitochondria became weak after 90 min OGD. Most of the neurons were shrunken after 90 min and neurons were TUNEL-positive 24 hours after 30 min OGD, although most neurons were viable at 3 hours. A longer period of OGD induced necrosis, and most neurons remained viable after only 3 hours. Our data present that the short (30 min) OGD induced hyperpolarization of MMP during reoxygenation, while a longer OGD (60 or 90 min) induced depolarization and acute necrosis. Neurons were still viable even during hyperpolarization of mitochondria, but this hyperpolarization appears to be linked to subsequent apoptotic change.

Mitochondrial membrane potential and intracellular ATP content after transient experimental ischemia in the cultured hippocampal neuron.

Ischemia limits the delivery of oxygen and glucose to cells and disturbs the maintenance of mitochondrial membrane potential (MMP). MMP regulates the production of high-energy phosphate and apoptotic cascading. Thus, MMP is an important parameter determining the fate of neurons. Differences in the time course of MMP according to the grading of the ischemic impact have not been clarified. MMP and intracellular ATP contents were monitored before and after short-term oxygen-glucose deprivation. A primary hippocampal culture seeded in a 35 mm fenestrated dish for fluorescence microscopy was mounted in a sealed chamber for an anaerobic incubation. A continuous flow of 100% nitrogen into the chamber and a replacement of glucose-free medium allowed the condition of oxygen-glucose deprivation (OGD), thereby extrapolating ischemia. MMP was evaluated by the fluorescence of a voltage-dependent dye, JC-1, under fluorescence microscopy. The intracellular ATP content was evaluated in a hippocampal culture seeded in a 96-well plate by the luciferin-luciferase reaction after a designated period of OGD. During OGD, MMP decreased to 0.72+/-0.03 (normalized JC-1 fluorescence), then increased to the hyperpolarized level 1.99+/-0.12 during 60 min reoxygenation after 30 min OGD. MMP after 60 min OGD decreased and recovered occasionally during reoxygenation. After 90 min OGD and reoxygenation, MMP was reduced and never recovered. The intracellular ATP content was 8.1+/-6.6 and 3.2+/-1.9% after 30 min OGD and 30 min reoxygenation following 30 min OGD, respectively; 60 min OGD did not significantly change these levels (7.1+/-5.8, 2.6+/-0.5%). Hyperpolarization after OGD did not accompany ATP production. This observation suggests the inhibition of electron reentry into an inner membrane during reoxygenation and the disturbance of FoF1-ATP synthase. This pathological finding of an energy-producing system after OGD may provide a clue to explain post-ischemic energy failure.

Reduction of neurotransmitter release by the exogenous H3 domain peptide of HPC-1/syntaxin 1A in cultured rat hippocampal neurons.

The membrane protein HPC-1/syntaxin 1A plays a key role in synaptic vesicle exocytosis in the presynaptic terminal. In particular, the H3 domain of HPC-1/syntaxin 1A participates in several protein-protein interactions that regulate neurotransmitter release. To investigate H3 domain function in neurotransmitter release, we used paired whole-cell patch clamping to record the evoked inhibitory postsynaptic currents in cultured hippocampal neurons. Introducing H3 domain peptide into the presynaptic neuron with a patch electrode depressed neurotransmitter release in a stimulation-frequency-dependent manner. Recovery from synaptic vesicle depletion induced by tetanic stimulation was significantly slowed by exogenous H3 domain peptide. These results suggest that the H3 domain peptide reduces neurotransmitter release by retarding the refilling of readily releasable vesicles.