海马神经细胞胆固醇含量降低对其电压依赖钾电流的上调作用

胆固醇普遍存在于细胞膜中,其含量在细胞增殖、生长及各种疾病条件下会发生改变,这暗示胆固醇对细胞功能的调节起着重要的作用。运用全细胞膜片钳技术研究了胆固醇含量变化对海马神经细胞电压依赖钾电流的影响。实验观察到神经细胞经胆固醇去除剂β-甲基环化糊精(MβCD)处理后,胆固醇含量的减少促进了延迟整流钾电流IK的增加,且延缓了瞬间失活钾电流IA的失活。更进一步,延迟整流钾电流IK和瞬间失活钾电流IA分别经TEA和4-AP阻断后,MβCD对两种电流成分的影响显著降低。这一结果进一步表明胆固醇去除剂对电压依赖钾电流的上调是通过作用于IK和IA电流而共同实现的。基于电压依赖钾通道在神经细胞功能中的重要作用,实验结果暗示神经细胞胆固醇含量变化可对神经细胞的兴奋性起调节作用。     

Neural Stem/Progenitor Cells Derived from the Embryonic Dorsal Telencephalon of D6/GFP Mice Differentiate Primarily into Neurons After Transplantation into a Cortical Lesion

D6 is a promoter/enhancer of the mDach1 gene that is involved in the development of the neocortex and hippocampus. It is expressed by proliferating neural stem/progenitor cells (NSPCs) of the cortex at early stages of neurogenesis. The differentiation potential of NSPCs isolated from embryonic day 12 mouse embryos, in which the expression of green fluorescent protein (GFP) is driven by the D6 promoter/enhancer, has been studied in vitro and after transplantation into the intact adult rat brain as well as into the site of a photochemical lesion. The electrophysiological properties of D6/GFP-derived cells were studied using the whole-cell patch-clamp technique, and immunohistochemical analyses were carried out. D6/GFP-derived neurospheres expressed markers of radial glia and gave rise predominantly to immature neurons and GFAP-positive cells during in vitro differentiation. One week after transplantation into the intact brain or into the site of a photochemical lesion, transplanted cells expressed only neuronal markers. D6/GFP-derived neurons were characterised by the expression of tetrodotoxin-sensitive Na⁺-currents and K _A- and K _DR currents sensitive to 4-aminopyridine. They were able to fire repetitive action potentials and responded to the application of GABA. Our results indicate that after transplantation into the site of a photochemical lesion, D6/GFP-derived NSPCs survive and differentiate into neurons, and their membrane properties are comparable to those transplanted into the non-injured cortex. Therefore, region-specific D6/GFP-derived NSPCs represent a promising tool for studying neurogenesis and cell replacement in a damaged cellular environment.     

Vitamins C and E Modulate Neuronal Potassium Currents

We investigated the effects of vitamins C and E on the delayed-rectifier potassium current (IK_DR), which is important in repolarizing the membrane potential, and on the transient A-type potassium current (IK_A), which regulates neuronal firing frequency. The whole-cell patch-clamp technique was used to measure the currents from cultured Drosophila neurons derived from embryonic neuroblasts. The membrane potential was stepped to different voltages between −40 and +60 mV from a holding potential of −80 mV. IK_DR and IK_A measured in the vitamin C-containing solution (IK_DR 305 ± 16 pA, IK_A 11 ± 2 pA) were smaller than those measured in the control solution (488 ± 21 pA, IK_A 28 ± 3 pA). By contrast, IK_DR and IK_A measured in the vitamin E-containing solution (IK_DR 561 ± 21 pA, IK_A 31 ± 3 pA) were greater than those measured in the control solution (422 ± 15 pA, 17 ± 2 pA). These results indicate that vitamins C and E can modulate potassium current amplitudes and possibly lead to altered neuronal excitability.     

Transplantation of Predifferentiated Adipose-Derived Stromal Cells for the Treatment of Spinal Cord Injury

Adipose-derived stromal cells (ASCs) are an alternative source of stem cells for cell-based therapies of neurological disorders such as spinal cord injury (SCI). In the present study, we predifferentiated ASCs (pASCs) and compared their behavior with naïve ASCs in vitro and after transplantation into rats with a balloon-induced compression lesion. ASCs were predifferentiated into spheres before transplantation, then pASCs or ASCs were injected intraspinally 1 week after SCI. The cells’ fate and the rats’ functional outcome were assessed using behavioral, histological, and electrophysiological methods. Immunohistological analysis of pASCs in vitro revealed the expression of NCAM, NG2, S100, and p75. Quantitative RT-PCR at different intervals after neural induction showed the up-regulated expression of the glial markers NG2 and p75 and the neural precursor markers NCAM and Nestin. Patch clamp analysis of pASCs revealed three different types of membrane currents; however, none were fast activating Na⁺ currents indicating a mature neuronal phenotype. Significant improvement in both the pASC and ASC transplanted groups was observed in the BBB motor test. In vivo, pASCs survived better than ASCs did and interacted closely with the host tissue, wrapping host axons and oligodendrocytes. Some transplanted cells were NG2- or CD31-positive, but no neuronal markers were detected. The predifferentiation of ASCs plays a beneficial role in SCI repair by promoting the protection of denuded axons; however, functional improvements were comparable in both the groups, indicating that repair was induced mainly through paracrine mechanisms.     

TEA-insensitive K-channels in the crab giant axon

TTX and TEA-insensitive permeabilities were studied in the crab giant axon under voltage-clamp. Membrane currents in the presence of internal TEA (40 mmol/l) and external TTX (300 nmol/l) may be analyzed as the sum of two components: a linear component, identified as the so-called leakage current, and a non-linear component, identified as a TEA-insensitive potassium channel. Ion permeability ratio of the TTX and TEA insensitive cation channel calculated from reversal potential shows the following sequence pK+:pNa+:pCs+:pRb+:pNH+4 = 1.00:0.16:0.16:0.09:0.06. TEA-insensitive outward currents, carried mainly by Cs+, may be recorded in the presence of different external solutions. Voltage-dependence and equilibrium potential of this channel in physiological conditions allows to postulate its contribution to maintain the cell depolarized during repetitive firing.     

Involvement of a novel fast inward sodium current in the invasion capacity of a breast cancer cell line

This work reports the finding of a unique fast inward sodium current (I_Na) in MDA-MB-231 cells which is missing in MDA-MB-468 cells and in MCF-7 cells. This current is high-voltage-activated and displays a window current at the membrane potential of MDA-MB-231 cells. This current is blocked by high concentrations of tetrodotoxin (TTX). In MDA-MB-231 cells, which are the most invasive cells among the three cell lines tested, proliferation and migration were not sensitive to TTX while invasion was reduced by approximately 30%. These experiments suggest that I_Na is involved in the invasion process, probably through its participation to the regulation of the intracellular sodium homeostasis.     

Sodium currents in toad cardiac pacemaker cells

Cells in the pacemaker region of toad (Bufo marinus) sinus venosus had spontaneous rhythmic action potentials. The rate of firing of action potentials, the rate of diastolic depolarization and the maximum rate of rise of action potentials were reduced by TTX (10 nm to 1 m). Currents were recorded with the whole cell, tight seal technique from cells enzymatically dissociated from this region. Cells studied were identified as pacemaker cells by their characteristic morphology, spontaneous rhythmic action potential activity that could be blocked by cobalt but not by TTX and lack of inward rectification. When calcium, potassium and nonselective cation currents (I_f) activated by hyperpolarization were blocked, depolarization was seen to generate transient and persistent inward currents. Both were sodium currents: they were abolished by tetrodotoxin (10 to 100 nm), their reversal potential was close to the sodium equilibrium potential and their amplitude and reversal potential were influenced as expected for sodium currents when extracellular sodium ions were replaced with choline ions. The transient sodium current was activated at potentials more positive than –40 mV while the persistent sodium current was obvious at more negative potentials. It was concluded that, in toad pacemaker cells, TTX-sensitive sodium currents contributing both to the upstroke of action potentials and to diastolic depolarization may play an important role in setting heart rate.We thank the Australian National Heart Foundation for their support. D.A.S. is an NHMRC Senior Research Officer.     

Enhancement of Sodium Current in NG108-15 Cells during Neural Differentiation is Mainly due to an Increase in NaV1.7 Expression

It is well known that morphological and functional changes during neural differentiation sometimes accompany the expression of various voltage-gated ion channels. In this work, we investigated whether the enhancement of sodium current in differentiated neuroblastoma × glioma NG108-15 cells treated with dibutyryl cAMP is related to the expression of voltage-gated sodium channels. The results were as follows. (1) Sodium current density on peak voltage in differentiated cells was significantly enhanced compared with that in undifferentiated cells, as detected by the whole-cell patch clamp method. The steady-state inactivation curve in differentiated cells was similar to that for undifferentiated cells, but a hyperpolarized shift in the activation curve for differentiated cells was observed. The sodium currents of differentiated and undifferentiated cells were completely inhibited by 10⁻⁷ M tetrodotoxin (TTX). (2) The only Na_V mRNA with an increased expression level during neuronal differentiation was that for Na_V1.7, as observed by real-time PCR analysis. (3) The increase in the level of Na_V1.7 α subunit expression during neuronal differentiation was also observed by immunocytochemistry; in particular, the localization of Na_V1.7 α subunits on the soma, varicosities and growth cone was significant. These results suggest that the enhancement of TTX-sensitive sodium current density in differentiated NG108-15 cells is mainly due to the increase in the expression of the TTX-sensitive voltage-gated Na⁺ channel, Na_V1.7.     

Ginsenoside Rg<Subscript>3</Subscript> enhances large conductance Ca<Superscript>2+</Superscript>-activated potassium channel currents: A role of Tyr360 residue

Ginsenosides, active ingredients of Panax ginseng, are known to exhibit neuroprotective effects. Large-conductance Ca²⁺-activated K⁺ (BK_Ca) channels are key modulators of cellular excitability of neurons and vascular smooth muscle cells. In the present study, we examined the effects of ginsenosides on rat brain BK_Ca (rSlo) channel activity heterologously expressed in Xenopus oocytes to elucidate the molecular mechanisms how ginsenoside regulates the BK_Ca channel activity. Ginsenoside Rg₃ (Rg₃) enhanced outward BK_Ca channel currents. The Rg₃-enhancement of outward BK_Ca channel currents was concentration-dependent, voltage-dependent, and reversible. The EC₅₀ was 15.1 ± 3.1 μM. Rg₃ actions were not desensitized by repeated treatment. Tetraetylammonium (TEA), a K⁺ channel blocker, inhibited BK_Ca channel currents. We examined whether extracellular TEA treatment could alter the Rg₃ action and vice versa. TEA caused a rightward shift of the Rg₃ concentration-response curve (i.e., much higher concentration of Rg₃ is required for the activation of BK_Ca channel compared to the absence of TEA), while Rg₃ caused a rightward shift of the TEA concentration-response curve in wild-type channels. Mutation of the extracellular TEA binding site Y360 to Y360I caused a rightward shift of the TEA concentration-response curve and almost abolished both the Rg₃ action and Rg₃-induced rightward shift of TEA concentration-response curve. These results indicate that Tyr360 residue of BK_Ca channel plays an important role in the Rg₃-enhancement of BK_Ca channel currents.     

Involvement of cationic channels in proliferation and migration of human mesenchymal stem cells

Human mesenchymal stem cells (HMSCs) have been applied in various clinic settings. Ion channels play an important role in cellular physiology. However, the potential role of cationic channels in regulating the proliferation and migration properties of hMSCs remains to be determined. In the present study, the functional expression of ion channels in hMSCs was investigated by patch clamp. MTT assay and BrdU stainings were used to assess the proliferation of hMSCs. hMSC migration was evaluated by Transwell migration assays. The results show that sodium-, L-type calcium, potassium currents have been identified in hMSCs. TEA (K⁺ channel blocker), nifedipine (Ca²⁺ channel blocker) can inhibit both proliferation and migration of hMSCs. The increase of extracellular Ca²⁺ concentration promoted both proliferation and migration of hMSCs. TTX, a Na⁺ channel blocker, promoted cell proliferation but inhibited cell migration. Our data suggest that cationic channels (sodium, L-type calcium, potassium channels) play important roles in regulating proliferation and migration of hMSCs.     

Sodium and potassium currents recorded during an action potential

A simple method was used to measure directly sodium and potassium currents underlying the action potential in single nerve fibres of Xenopus laevis. A short rectangular stimulus under current-clamp conditions elicited an action potential which was digitally stored and later used as command when voltageclamping the same fibre. The currents thus obtained nearly reproduced the original rectangular stimulus. Adding first 100 nM TTX and subsequently 100 nM TTX plus 10 mM TEA to the extracellular Ringer solution revealed the sodium and the potassium currents during an action potential. They were converted to permeabilities by use of the constant-field equation and are in good agreement with the curves which had been calculated from conventional voltage-clamp data. Thus experimentally determined currents and permeabilities are shown as they are changing during an action potential.     

Calmodulin and calcium differentially regulate the neuronal Nav1.1 voltage-dependent sodium channel

Mutations in the neuronal Nav1.1 voltage-gated sodium channel are responsible for mild to severe epileptic syndromes. The ubiquitous calcium sensor calmodulin (CaM) bound to rat brain Nav1.1 and to the human Nav1.1 channel expressed by a stably transfected HEK-293 cell line. The C-terminal region of the channel, as a fusion protein or in the yeast two-hybrid system, interacted with CaM via a consensus C-terminal motif, the IQ domain. Patch clamp experiments on HEK1.1 cells showed that CaM overexpression increased peak current in a calcium-dependent way. CaM had no effect on the voltage-dependence of fast inactivation, and accelerated the inactivation kinetics. Elevating Ca⁺⁺ depolarized the voltage-dependence of fast inactivation and slowed down the fast inactivation kinetics, and for high concentrations this effect competed with the acceleration induced by CaM alone. Similarly, the depolarizing action of calcium antagonized the hyperpolarizing shift of the voltage-dependence of activation due to CaM overexpression. Fluorescence spectroscopy measurements suggested that Ca⁺⁺ could bind the Nav1.1 C-terminal region with micromolar affinity.     

Presumptive neurons derived by differentiation of a human embryonal carcinoma cell line exhibit tetrodotoxin-sensitive sodium currents and the capacity for regenerative responses

Cloned human embryonal carcinoma cells (NTERA-2 cl.D1) differentiate into neuron-like cells upon exposure to retinoic acid. Using whole-cell patch-clamp techniques, these putative neurons exhibited rapidly activating and inactivating inward currents upon depolarization as well as outward currents. The electrical characteristics and tetrodotoxin (TTX) sensitivity of the inward currents suggest that they were sodium currents. By contrast, only outward potassium currents were seen in the undifferentiated stem cells. Under current clamp conditions, the neuron-like cells showed regenerative responses. The peaks of these responses never exceeded the O-mV level, perhaps due to the low mean inward current density of 93.8 +/- 17.8 (SEM) microA/cm2:n = 9. The electrophysiological characteristics of these human teratocarcinoma-derived neuron-like cells were consistent with our previous identification of these cells as neurons, but suggest that they may resemble immature embryonic, rather than adult, neurons.     

Identification of electrophysiologically distinct subpopulations of rat taste cells

Summary The gustatory sensory system provides animals with a rapid chemical analysis of a potential food substance providing information necessary to facilitate ingestion or rejection of the food. The process of gustatory transduction is initiated in the taste cells in the lingual epithelium. However, due to the small size, scarcity of the cells and their location, embedded in a keratinized squamous epithelium, it has been difficult to study the primary events in the transduction process. Recently, we have developed a preparation of dissociated rat taste cells that permits studies of the taste transduction process in single isolated cells. We have now investigated the electrophysiological properties of the rat taste cells using the patch-clamp technique. We have identified two populations of cells within the taste bud: one expressing a voltage-dependent potassium current and the second containing both voltage-dependent sodium and potassium currents. The potassium current in both cell groups is blocked by external TEA, Ba²⁺, and quinine. Two types of K⁺ channels have been identified: a 90-pS delayed rectifier K⁺ channel and a maxi calcium-activated K⁺ channel. The sodium current is blocked by TTX, but not by amiloride.     

Neuronal sodium channels in ventricular heart cells are localized near T-tubules openings

Cardiac voltage-dependent sodium channels (VDSC) are known to be tetrodotoxin (TTX)-resistant. However, recent immunochemical studies suggest the presence of TTX-sensitive neuronal-type VDSC in the heart. Scanning ion conductance microscopy (SICM) coupled to electrophysiology was used to obtain more direct functional evidence. TTX sensitivities of whole-cell sodium currents (I(Na)) in control and detubulated cells were compared. Addition of 200 nM TTX decreased I(Na) of control cells by 20%, whereas detubulated cells were hardly effected. The remaining current peaked slightly earlier and inactivation decay was faster (as in neuronal VDSC) than in detubulated cells. Single-channel activity was first assayed at random on the plasmalemma, and after topography had been revealed by SICM, at patched T-tubules openings. In the latter case, a single-channel conductance of 11-12pS was observed with a higher rate of success. This study provides independent evidence for neuronal VDSC in cardiomyocytes where they could rapidly and synchronously couple T-tubule and cell surface depolarizations.     

Differentiation and migration of long term expanded human neural progenitors in a partial lesion model of Parkinson's disease

Human neural progenitor cells (HNPCs) can be expanded in large numbers for significant periods of time to provide a reliable source of neural cells for transplantation in neurodegenerative disorders such as Parkinson's disease (PD). In the present study, HNPCs isolated from embryonic cortex were expanded as neurospheres in cell culture for 10 months. Just prior to transplantation, a proportion of the HNPCs were treated in a "predifferentiation" protocol in combination with the neurotropic factor NT4, in order to yield significant numbers of neurons. For transplantation, either undifferentiated HNPCs, or predifferentiated HNPCs were transplanted into the substantia nigra of a rat model of Parkinson's disease. At 12 weeks, there was good survival with proliferation of transplanted HNPCs occurring after transplantation but ceasing before the animals were sacrificed. Transplants of predifferentiated cells contained a higher proportion of neurons. The presence of a lesion in the striatum had a significant influence on the migration of transplanted cells from the substantia nigra into the striatum. There was no significant behavioural recovery or effect of transplanted HNPCs on the loss of dopaminergic cells from the host brain. In conclusion, HNPCs may provide a source of cells for use in the treatment of Parkinson's disease.     

Temperature sensitivity of acid-sensitive outwardly rectifying (ASOR) anion channels in cortical neurons is involved in hypothermic neuroprotection against acidotoxic necrosis

The acid-sensitive outwardly rectifying (ASOR) anion channel has been found in non-neuronal cell types and was shown to be involved in acidotoxic death of epithelial cells. We have recently shown that the ASOR channel is sensitive to temperature. Here, we extend those results to show that temperature-sensitive ASOR anion channels are expressed in cortical neurons and involved in acidotoxic neuronal cell death. In cultured mouse cortical neurons, reduction of extracellular pH activated anionic currents exhibiting phenotypic properties of the ASOR anion channel. The neuronal ASOR currents recorded at pH 5.25 were augmented by warm temperature, with a threshold temperature of 26 °C and the Q₁₀ value of 5.6. After 1 h exposure to acidic solution at 37 °C, a large population of neurons suffered from necrotic cell death which was largely protected not only by ASOR channel blockers but also by reduction of temperature to 25 °C. Thus, it is suggested that high temperature sensitivity of the neuronal ASOR anion channel provides, at least in part, a basis for hypothermic neuroprotection under acidotoxic situations associated with a number of pathological brain states.     

Temperature sensitivity of acid-sensitive outwardly rectifying (ASOR) anion channels in cortical neurons is involved in hypothermic neuroprotection against acidotoxic necrosis

The acid-sensitive outwardly rectifying (ASOR) anion channel has been found in non-neuronal cell types and was shown to be involved in acidotoxic death of epithelial cells. We have recently shown that the ASOR channel is sensitive to temperature. Here, we extend those results to show that temperature-sensitive ASOR anion channels are expressed in cortical neurons and involved in acidotoxic neuronal cell death. In cultured mouse cortical neurons, reduction of extracellular pH activated anionic currents exhibiting phenotypic properties of the ASOR anion channel. The neuronal ASOR currents recorded at pH 5.25 were augmented by warm temperature, with a threshold temperature of 26 °C and the Q₁₀ value of 5.6. After 1 h exposure to acidic solution at 37 °C, a large population of neurons suffered from necrotic cell death which was largely protected not only by ASOR channel blockers but also by reduction of temperature to 25 °C. Thus, it is suggested that high temperature sensitivity of the neuronal ASOR anion channel provides, at least in part, a basis for hypothermic neuroprotection under acidotoxic situations associated with a number of pathological brain states.