Characteristics of Na+ current in Schwann cells cultured from frog sciatic nerve

Characteristics of voltage-dependent currents in cultured frog Schwann cells were investigated by the whole-cell clamp technique. An inward current was detectable at a membrane potential level more positive than-50 mV and reached a maximum value at about-10 mV, while no rectifying channel was present. The inward current was carried by Na⁺ ions, because the extrapolated reversal potential of the current agreed with the calculated E_Na, and the current was sensitive to tetrodotoxin. The membrane potential for half-maximal inactivation was-82 mV. The inactivation curve indicated that more than 90% of the Na⁺ channels were inactivated at the resting membrane potential, suggesting that the cultured frog Schwann cells could not generate an action potential under physiological conditions. The time constant for the inactivation at a maximum current was 5.3 ms (-10 mV, 13°C). The electrophysiological characteristics of the Na⁺ current in the cultured frog Schwann cells were compared with those in other tissues. This Na⁺ current was quantitatively different from that observed in the amphibian node of Ranvier but was similar to that in the mammalian Schwann or glial cells, especially in the more hyperpolarized half-maximal inactivation potential and in the slower inactivation time course. © 1994 Wiley-Liss, Inc.     

Hyperpolarization-activated current, Ih, in inspiratory brainstem neurons and its inhibition by hypoxia

A hyperpolarization-activated current, Ih, is often implied in pacemaker-like depolarizations during rhythmic oscillatory activity. We describe Ih in the isolated respiratory centre of immature mice (P6-P11). Ih was recorded in 15% (22/146) of all inspiratory neurons examined. The mean half-maximal Ih activation occurred at -78 mV and the reversal potential was -40 mV. Ih was inhibited by Cs+ (1-5 mM) and by organic blockers N-ethyl-1,6-dihydro-1, 2-dimethyl-6-(methylimino)-N-phenyl-4-pyrimidinamine (ZD 7288; 0.3-3 microM) and N,N'-bis-(3,4-dimethylphenylethyl)-N-methylamine (YS 035, 3-30 microM), but not by Ba2+ (0.5 mM). The organic Ih blockers did not change the inspiratory bursts recorded from the XIIth nerve and synaptic drives in inspiratory neurons. Hypoxia reversibly inhibited Ih but, in the presence of organic blockers, the hypoxic reaction remained unchanged. We conclude that although Ih channels are functional in a minority of inspiratory neurons, Ih does not contribute to respiratory rhythm generation or its modulation by hypoxia.     

重度缺氧中海马神经元KATP通道的表达改变

目的 探讨重度缺氧状态中ATP敏感性钾通道(KATP)通道在海马神经元上的表达变化. 方法 取培养1周的新生大鼠海马神经元分为4组:第1组为正常对照组,在正常氧状态中(5%CO_2、95%空气)孵育8 h;第2组为处理组,在模拟的缺氧状态(5% CO_2、95%N_2)孵育8h(单纯缺氧组);第3组为二氮嗪+缺氧组,在缺氧处理的同时添加KATP通道激动剂二氮嗪(100μmo1/L1,处理时间为8 h;第4组为甲糖宁+缺氧组,在缺氧处理的同时添加KATP通道阻断剂甲糖宁(100 μmol/L),处理时间为8h.利用MTT、免疫印迹及RT-PCR技术,比较4组细胞存活情况以及缺氧状态中神经元上KATP通道的表达改变. 结果 缺氧8h后,二氮嗪能明显降低细胞的凋亡数量,甲糖宁使细胞的凋亡数量增加,与正常对照组比较,差异均有统计学意义(P<0.05).缺氧状态中KATP通道的SUR1亚基的表达明显增加,而Kir6.2亚基表达量则无明显改变,与正常对照组比较,差异均有统计学意义(P<0.05). 结论 KATP通道的活性及表达改变,对缺氧中的海马神经元的保护起到重要作用.     

Neuropathic pain is associated with increased nodal persistent Na+ currents in human diabetic neuropathy

Abstract Peripheral nerve injury alters function and expression of voltage gated Na⁺ channels on the axolemma, leading to ectopic firing and neuropathic pain/paresthesia. Hyperglycemia also affects nodal Na⁺ currents, presumably due to activation of polyol pathway and impaired Na⁺–K⁺ pump. We investigated changes in nodal Na⁺ currents in peripheral sensory axons and their relation with pain in human diabetic neuropathy. Latent addition using computerized threshold tracking was used to estimate nodal persistent Na⁺ currents in radial sensory axons of 81 diabetic patients. Of these, 36 (44%) had chronic neuropathic pain and severe paresthesia. Compared to patients without pain, those with pain had greater nodal Na⁺ currents (p = 0.001), smaller amplitudes of sensory nerve action potentials (SNAP) (p = 0.0003), and lower hemoglobin A1c levels (p = 0.006). Higher axonal Na⁺ conductance was associated with smaller SNAP amplitudes (p = 0.03) and lower hemoglobin A1c levels (p = 0.008). These results suggest that development of neuropathic pain depends on axonal hyperexcitability due to increased nodal Na⁺ currents associated with structural changes, but the currents could also be affected by the state of glycemic control. Our findings support the view that altered Na⁺ channels could be responsible for neuropathic pain/paresthesia in diabetic neuropathy.     

Changes in Na(+) channel expression and nodal persistent Na(+) currents associated with peripheral nerve regeneration in mice

Patients with peripheral neuropathy frequently suffer from positive sensory (pain and paresthesias) and motor (muscle cramping) symptoms even in the recovery phase of the disease. To investigate the pathophysiology of increased axonal excitability in peripheral nerve regeneration, we assessed the temporal and spatial expression of voltage-gated Na(+) channels as well as nodal persistent Na(+) currents in a mouse model of Wallerian degeneration. Crushed sciatic nerves of 8-week-old C57/BL6J male mice underwent complete Wallerian degeneration at 1 week. Two weeks after crush, there was a prominent increase in the number of Na(+) channel clusters per unit area, and binary or broad Na(+) channel clusters were frequently found. Excess Na(+) channel clusters were retained up to 20 weeks post-injury. Excitability testing using latent addition suggested that nodal persistent Na(+) currents markedly increased beginning at week 3, and remained through week 10. These results suggest that axonal regeneration is associated with persistently increased axonal excitability resulting from increases in the number and conductance of Na(+) channels.     

Dependence of axon initial segment formation on Na+ channel expression

Spinal motor neurons were isolated from embryonic rats, and grown in culture. By 2 days in vitro, the axon initial segment was characterized by colocalization and clustering of Na+ channels and ankyrinG. By 5 days, NrCAM, and neurofascin could also be detected at most initial segments. We sought to determine, as one important aim, whether Na+ channels themselves played an essential role in establishing this specialized axonal region. Small hairpin RNAs (shRNAs) were used to target multiple subtypes of Na+ channels for reduced expression by RNA interference. Transfection resulted in substantial knockdown of these channels within the cell body and also as clusters at initial segments. Furthermore, Na+ currents originating at the initial segment, and recorded under patch clamp, were strongly reduced by shRNA. Control shRNA against a nonmammalian protein was without effect. Most interestingly, targeting Na+ channels also blocked clustering of ankyrinG, NrCAM, and neurofascin at the initial segment, although these proteins were seen in the soma. Thus, both Na+ channels and ankyrinG are required for formation of this essential axonal domain. Knockdown of Na+ channels was somewhat less effective when introduced after the initial segments had formed. Disruption of actin polymerization by cytochalasin D resulted in multiple initial segments, each with clusters of both Na+ channels and ankyrinG. The results indicate that initial segment formation occurs as Na+ channels are transported into the nascent axon membrane, diffuse distally, and link to the cytoskeleton by ankyrinG. Subsequently, other components are added, and stability is increased. A computational model closely reproduced the experimental results.     

Ionic channel currents in cultured neurons from human cortex

Ionic channels in human cortical neurons have not been studied extensively. HCN-1 and HCN-1A cells, which recently were established as continuous cultures from human cortical tissue, have been shown by histochemical and immunochemical methods to exhibit a neuronal phenotype, but expression of functional ionic channels was not demonstrated. For the present study, HCN-1 and HCN-1A cells were cultured in Dulbecco's modified Eagle's medium with 15% fetal calf serum, in some cases supplemented with 10 ng/ml nerve growth factor, 10 μM forskolin, and 1 mM dibutyryl cyclic adenosine monophosphate to promote differentiation. Cells or membrane patches were voltage clamped using conventional patch clamp techniques. In HCN-1A cells, we identified a tetrodotoxin-sensitive Na⁺ current, two types of Ca²⁺ channel current, including L-type current and a second type that in some respects resembled N-type current, and four types of K⁺ current, including a delayed outward rectifier that showed voltage-dependent inactivation, two types of noninactivating Ca²⁺-activated K⁺ channels with slope conductances of 146 and 23 pS (K⁺ _iK⁺ _o 145 mM/5 mM), and less frequently, a noninactivating, intermediate conductance channel that was not sensitive to internal Ca²⁺. When HCN-1A cells were examined after 3 days of exposure to differentiating agents, pronounced morphological changes were evident but no differences in ionic currents were apparent. HCN-1 cells also exhibited K⁺ and Ca²⁺ channel currents, but Na⁺ currents were not detected in these cells. Our data provide additional evidence indicating a functional neuronal phenotype for HCN-1A cells, and represent the most comprehensive survey to date of the variety of ionic channels expressed by human cortical neurons. © 1993 Wiley-Liss, Inc.     

Glial Na+‐dependent ion transporters in pathophysiological conditions

Sodium dynamics are essential for regulating functional processes in glial cells. Indeed, glial Na⁺ signaling influences and regulates important glial activities, and plays a role in neuron‐glia interaction under physiological conditions or in response to injury of the central nervous system (CNS). Emerging studies indicate that Na⁺ pumps and Na⁺‐dependent ion transporters in astrocytes, microglia, and oligodendrocytes regulate Na⁺ homeostasis and play a fundamental role in modulating glial activities in neurological diseases. In this review, we first briefly introduced the emerging roles of each glial cell type in the pathophysiology of cerebral ischemia, Alzheimer's disease, epilepsy, Parkinson's disease, Amyotrophic Lateral Sclerosis, and myelin diseases. Then, we discussed the current knowledge on the main roles played by the different glial Na⁺‐dependent ion transporters, including Na⁺/K⁺ ATPase, Na⁺/Ca²⁺ exchangers, Na⁺/H⁺ exchangers, Na⁺‐K⁺‐Cl^? cotransporters, and Na⁺‐ cotransporter in the pathophysiology of the diverse CNS diseases. We highlighted their contributions in cell survival, synaptic pathology, gliotransmission, pH homeostasis, and their role in glial activation, migration, gliosis, inflammation, and tissue repair processes. Therefore, this review summarizes the foundation work for targeting Na⁺‐dependent ion transporters in glia as a novel strategy to control important glial activities associated with Na⁺ dynamics in different neurological disorders. GLIA 2016;64:1677–1697     

Functional expression of constitutive nitric oxide synthases regulated by voltage-gated Na+ and Ca2+ channels in cultured human astrocytes

We report the functional characterization of constitutive nitric oxide synthase(s) (NOS) such as neuronal and endothelial NOS in cultured human astrocytes. Exposure of cultured human astrocytes to 1 microM veratridine or 50 mM KCl produced a pronounced increase in a calmodulin-dependent NOS activity estimated from cGMP formation. The functional expression of voltage-gated Na(+) channel, which is estimated by the response to veratridine, appeared to be earlier (at second day in culture) than that of voltage-gated Ca(2+) channels, which are estimated by the response to the KCl stimulation (at fourth day in culture). The KCl-evoked NO synthesis was totally reversed by L-type Ca(2+) channel blockers such as nifedipine and verapamil, but not by omega-conotoxin GVIA, an N-type Ca(2+) channel blocker, or omega-agatoxin IVA, a P/Q-type Ca(2+) channel blocker. In addition, verapamil abolished the KCl-induced increase in the intracellular free Ca(2+) concentration. RT-PCR analysis revealed that mRNA for neuronal and endothelial NOS was expressed in human astrocytes. In addition, Western blot analysis and double labeling of NOS and glial fibrillary acidic protein (GFAP) showed that cultured human astrocytes expressed neuronal NOS and endothelial NOS as well as the alpha(1) subunit of Ca(2+) channel. These results suggest that human astrocytes express constitutive NOS that are regulated by voltage-gated L-type Ca(2+) channel as well as Na(+) channel.     

K+-dependence of Na+-Ca2+ exchange in type I vestibular sensory cells of guinea-pig.

The properties of the vestibular Na+-Ca2+ exchanger in mammalian type I vestibular sensory cells were studied using fura-2 fluorescence and immunocytochemical techniques. In the absence of external Na+, the activation of Na+-Ca2+ exchange in reverse mode required the presence of external K+ (K+o) and depended on K+o concentration. Alkali cations Rb+ and NH4+ but not Li+ or Cs+ substituted for K+o to activate the exchange. For pressure applications of 10 mm K+, the contribution of voltage-sensitive calcium channels to the increase in [Ca2+]i was < 15%. The dependence of the exchange on [K+]o was also recorded when the membrane potential was clamped using carbonyl cyanide p-trifluoromethoxy-phenylhydrazone (FCCP) and monensin ionophores. In these conditions, where there was no intracellular Na+, the increase in [Ca2+]i was completely blocked. These physiological results suggest that in reverse mode, Ca2+ entry is driven by both an outward transport of Na+ and an inward transport of K+. The dependence of the vestibular Na+-Ca2+ exchanger on K+ is more reminiscent of the properties of the retinal type Na+-Ca2+ exchanger than those of the more widely distributed cardiac type exchanger. Moreover, the immunocytochemical localization of both types of exchange proteins in the vestibular sensory epithelium confirmed the presence in the vestibular sensory cells of a Na+-Ca2+ exchanger which is recognized by an antibody raised against retinal type and not by an antibody raised against the cardiac type.     

Riluzole inhibits the persistent sodium current in mammalian CNS neurons

The effects of 0.1-100 microM riluzole, a neuroprotective agent with anticonvulsant properties, were studied on neurons from rat brain cortex. Patch-clamp whole-cell recordings in voltage-clamp mode were performed on thin slices to examine the effects of the drug on a noninactivating (persistent) Na+ current (INa,p). INa,p was selected because it enhances neuronal excitability near firing threshold, which makes it a potential target for anticonvulsant drugs. When added to the external solution, riluzole dose-dependently inhibited INa,p up to a complete blocking of the current (EC50 2 microM), showing a significant effect at therapeutic drug concentrations. A comparative dose-effect study was carried out in the same cells for the other main known action of riluzole, the inhibitory effect on the fast transient sodium current. This effect was confirmed in our experiments, but we found that it was achieved at levels much higher than putative therapeutic concentrations. Only the effect on INa,p, and not that on fast sodium current, can account for the reduction in neuronal excitability observed in cortical neurons following riluzole treatment at therapeutic concentrations, and this might represent a novel mechanism accounting for the anticonvulsant and neuroprotective properties of riluzole.     

Effect of neonatal hypothyroidism on the kinetic properties of Na+, K+ -ATPase from rat brain microsomes

The effects of neonatal hypothyroidism on the kinetic properties of Na+, K+ -ATPase from rat brain microsomes were examined. Neonatal hypothyroidism resulted in decreased Na+, K+ -ATPase activity compared to control samples (7.4 +/- 1.48 and 29.8 +/- 2.30 micromol Pi/h/mg protein, respectively, P < 0.001). Substrate kinetics studies with ATP, Na+ and K+ revealed that there were generalised decreases in Vmax. For ATP, Na+ and K+, activities resolved into two kinetic components in the control group. In hypothyroid animals, the low-affinity component for ATP was absent. The opposite pattern (i.e. an absence of the high-affinity component) was noted for Na+. For K+, although both kinetic components were discernible in neonatal hypothyroid brain microsomes, the Km of the high-affinity component was significantly higher (P < 0.001) compared to control samples. In the control group, the enzyme displayed allosteric behaviour at high concentrations of Mg2+; in hypothyroid animals, the pattern was completely allosteric. The Na+, K+ -ATPase enzyme from the hypothyroid brain microsomes bound two molecules of ATP rather than one, unlike in the control animals. Our results thus indicate that neonatal hypothyroidism results in an impairment of microsomal Na+, K+ -ATPase activity in the rat brain, together with subtle alterations in the kinetic properties of the enzyme.     

Characteristics of fast Na(+) current of hypoglossal motoneurons in a rat brainstem slice preparation

Whole-cell patch clamp recordings were performed on hypoglossal motoneurons in a brainstem slice preparation from the neonatal rat brain to study the characteristics of the fast Na(+) current (I(Na)) which has not been hitherto investigated in these cells. To aid voltage clamping of I(Na), cells were bathed in low Na(+) solution, loaded intracellularly with Na(+) (to reverse the Na(+) gradient) or treated with a small dose (20 nM) of tetrodotoxin. In low extracellular Na(+) solution (Na(+) was replaced by choline or N-methyl-D-glucamine) I(Na) activated at membrane potentials positive to -45 mV and was half-maximally activated at -30 mV. Similar data were obtained when the Na(+) gradient was reversed or tetrodotoxin was applied. I(Na) rapidly activated (1--3.5 ms time constant) and inactivated (1.6 ms time constant at 0 mV) during membrane depolarization. Inactivation was strongly voltage-dependent (half inactivation at -44 mV) and developed mono-exponentially. Recovery from inactivation was bi-exponential with fast and slow time constants of 14 and 160 ms, respectively, at -58 mV. The rapid turning on of I(Na) was presumably responsible for the upstroke of the fast action potential generated by these cells while the slow phase of recovery from inactivation might modulate the ability to fire repetitively at high rate.     

Sources of axonal calcium loading during in vitro ischemia of rat dorsal roots

A detailed understanding of injury mechanisms in peripheral nerve fibers will help guide successful design of therapies for peripheral neuropathies. This study was therefore undertaken to examine the ionic mechanisms of Ca2+ overload in peripheral myelinated fibers subjected to chemical inhibition of energy metabolism. Myelinated axons from rat dorsal roots were co-loaded with Ca2+-sensitive (Oregon Green BAPTA-1) and Ca2+-insensitive (Alexa Fluor 594) dextran-conjugated fluorophores and imaged using confocal laser scanning microscopy. Axoplasmic regions were clearly outlined by the Ca2+-insensitive dye, from which axonal Ca2+-dependent fluorescence changes (FCa.ax) were measured. Block of Na+-K+ ATPase (ouabain), opening of Na+ channels (veratridine), and inhibiting energy metabolism (iodoacetate + NaN3) caused a rapid rise in FCa.ax to 96% above control after 30 min. Chemical ischemia (iodoacetate + NaN3) caused a more gradual increase in FCa.ax (54%), which was almost completely dependent on bath Ca2+, indicating that most of the Ca2+ accumulation occurred via influx across the axolemma. Na+ channel block (tetrodotoxin) reduced ischemic FCa.ax rise (14%); however, inhibition of L-type Ca2+ channels (nimodipine) had no effect (60%). In contrast, Na+-Ca2+ exchange inhibition (KB-R7943) significantly reduced ischemic FCa.ax rise (18%). Together our results indicate that the bulk of Ca2+ overload in injured peripheral myelinated axons occurs via reverse Na+-Ca2+ exchange, driven by axonal Na+ accumulation through voltage-gated tetrodotoxin-sensitive Na+ channels. This mechanism may represent a viable therapeutic target for peripheral neuropathies.     

Energetic demands of the Na+/K+ ATPase in mammalian astrocytes

Cultured astrocytes and cell lines derived therefrom maintain a high energy level ([ATP]/[ADP]) through operation of oxidative phosphorylation and glycolysis. The contribution from the latter to total ATP production is 25–32%. A powerful Na⁺/K⁺ pump maintains potassium, sodium, and calcium gradients out of equilibrium. [Na⁺]_i is about 20 mM, [K⁺]_i is 130 mM and [Ca²⁺]_i is less than 100 nM. Under non-stimulated conditions, the Na⁺/K⁺ ATPase consumes 20% of astrocytic ATP production. Inhibition of the pump by ouabain decreases energy expenditure, raises [creatine phosphate]/[creatine], and leads to a leakage of sodium, potassium, and calcium ions. Decrease in the pump function via a fall in [ATP] also collapses ion gradients; the rate and extent of the fall correlates positively with cellular energy state. Under “normal” conditions (i.e., when ATP production pathways are not inhibited), there appears to be no preferential utilization of energy produced by either glycolysis or oxidative phosphorylation for the support of pump function. GLIA 21:35–45, 1997. © 1997 Wiley-Liss, Inc.     

A quantitative analysis of L-glutamate-regulated Na+ dynamics in mouse cortical astrocytes: implications for cellular bioenergetics

The mode of Na+ entry and the dynamics of intracellular Na+ concentration ([Na+]i) changes consecutive to the application of the neurotransmitter glutamate were investigated in mouse cortical astrocytes in primary culture by video fluorescence microscopy. An elevation of [Na+]i was evoked by glutamate, whose amplitude and initial rate were concentration dependent. The glutamate-evoked Na+ increase was primarily due to Na+-glutamate cotransport, as inhibition of non-NMDA ionotropic receptors by 6-cyano-7-nitroquinoxiline-2,3-dione (CNQX) only weakly diminished the response and D-aspartate, a substrate of the glutamate transporter, produced [Na+]i elevations similar to those evoked by glutamate. Non-NMDA receptor activation could nevertheless be demonstrated by preventing receptor desensitization using cyclothiazide. Thus, in normal conditions non-NMDA receptors do not contribute significantly to the glutamate-evoked Na+ response. The rate of Na+ influx decreased during glutamate application, with kinetics that correlate well with the increase in [Na+]i and which depend on the extracellular concentration of glutamate. A tight coupling between Na+ entry and Na+/K+ ATPase activity was revealed by the massive [Na+]i increase evoked by glutamate when pump activity was inhibited by ouabain. During prolonged glutamate application, [Na+]i remains elevated at a new steady-state where Na+ influx through the transporter matches Na+ extrusion through the Na+/K+ ATPase. A mathematical model of the dynamics of [Na+]i homeostasis is presented which precisely defines the critical role of Na+ influx kinetics in the establishment of the elevated steady state and its consequences on the cellular bioenergetics. Indeed, extracellular glutamate concentrations of 10 microM already markedly increase the energetic demands of the astrocytes.     

The role of Na+‐K+‐ATPase in the epileptic brain

Na+‐K+‐ATPase, a P‐type ATP‐powered ion transporter on cell membrane, plays a vital role in cellular excitability. Cellular hyperexcitability, accompanied by hypersynchronous firing, is an important basis for seizures/epilepsy. An increasing number of studies point to a significant contribution of Na+‐K+‐ATPase to epilepsy, although discordant results exist. In this review, we comprehensively summarize the structure and physiological function of Na+‐K+‐ATPase in the central nervous system and critically evaluate the role of Na+‐K+‐ATPase in the epileptic brain. Importantly, we further provide perspectives on some possible research directions and discuss its potential as a therapeutic target for the treatment of epilepsy.     

Carbamazepine and topiramate modulation of transient and persistent sodium currents studied in HEK293 cells expressing the Na(v)1.3 alpha-subunit

PURPOSE: The transient and the persistent Na(+) current play a distinct role in neuronal excitability. Several antiepileptic drugs (AEDs) modulate the transient Na(+) current and block the persistent Na(+) current; both effects contribute to their antiepileptic properties. The interactions of the AEDs carbamazepine (CBZ) and topiramate (TPM) with the persistent and transient Na(+) current were investigated. METHODS: HEK293 cells stably expressing the alpha-subunit of the Na(+) channel Na(V)1.3 were used to record Na(+) currents under voltage-clamp by using the patch-clamp technique in whole-cell configuration and to investigate the effects of CBZ and TPM. RESULTS: The persistent Na(+) current was present in all cells and constituted 10.3 +/- 3.8% of the total current. CBZ partially blocked the persistent Na(+) current in a concentration-dependent manner [median effective concentration (EC(50)), 16 +/- 4 microM]. CBZ also shifted the steady-state inactivation of the transient Na(+) current to negative potentials (EC(50), 14 +/- 11 microM). TPM partially blocked the persistent Na(+) current with a much higher affinity (EC(50), 61 +/- 37 nM) than it affected the steady-state inactivation of the transient Na(+) current (EC(50), 3.2 +/- 1.8 microM). For the latter effect, TPM was at most half as effective as CBZ. CONCLUSIONS: The persistent Na(+) current flowing through the alpha-subunit of the Na(V)1.3 channel is partially blocked by CBZ at about the same therapeutic concentrations at which it modulates the transient Na(+) current, adding a distinct aspect to its anticonvulsant profile. The TPM-induced partial block of the persistent Na(+) current, already effective at low concentrations, could be the dominant action of this drug on the Na(+) current.     

Nitric oxide induces an increased Na conductance in identified neurons of Aplysia

The ionic mechanism of the effects of micropressure ejections of hydroxylamine (HOA) and sodium nitroprusside (SNP), nitric oxide (NO) generators, on the membrane of identified neurons (R9–R12) of Aplysia kurodai was investigated with conventional voltage-clamp, micropressure ejection, and ion-substitution techniques. Micropressure ejection of HOA and SNP onto the neurons caused a marked depolarization in the unclamped neurons. Clamping the same neurons at their resting potential level (−60 mV) and reejecting HOA and SNP with the same dose produced a slow inward current (I_i(HOA) and I_i(SNP), 3–7 nA in amplitude, 15–60 s in duration) associated with an increase in input membrane conductance. Bath-applied hemoglobin (50 μM), a nitric oxide scavenger, almost completely blocked I_i(HOA) and I_i(SNP), and 3-isobutyl-1-methylxanthine (IBMX, 50 μM) prolonged and enhanced both I_i(HOA) and I_i(SNP). An intracellular injection of cyclic guanosine 3′,5′-monophosphate (cGMP) into the same neurons produced a slow inward current (I_i(cGMP)) which resembled the responses to HOA and SNP, and this current was enhanced in IBMX. Bath-applied methylene blue (10 μM), an inhibitor of guanylate cyclase, significantly reduced I_i(HOA) and I_i(SNP). The inward currents induced by HOA, SNP and cGMP were sensitive to changes in the external Na⁺ concentration. These results suggest that extracellular NO can induce a slow inward current associated with an increase in Na⁺ conductance, mediated by an increase in intracellular cGMP.     

Endogenous adenosine mediates the sustained inhibition of excitatory synaptic transmission during moderate hypoxia

The role of adenosine in suppressing synaptic responses during prolonged moderate hypoxia was examined in rat hippocampal slices. The intrahypoxic loss of evoked synaptic responses could be reversed partially by an antagonist of the A₁ type adenosine receptor during an entire hour of hypoxia. These findings indicate that the capacity to express synaptic transmission exists during prolonged moderate hypoxia, and that endogenous adenosine actively suppresses transmission via an action at A₁ type receptors.