Cell-attached Patch Configuration Research Articles

Studies on Membrane Potential and Ca2+ Oscillations in Rat Carotid Body Type I Cells

Carotid body (CB) glomus cells sense changes in arterial O2 pressure (PO2) and pH, and adjust the secretory and carotid sinus nerve activity and ventilation to help maintain normal levels of blood PO2 and pH. Our recent studies showed that isolated CB cell clusters perfused with physiological buffer solution generate spontaneous Ca2+ oscillations at low frequency in normoxia. Mild and moderate levels of hypoxia (2-5%O2) and acidosis (pHo7.2-7.3) increased the frequency and amplitude of Ca2+ oscillations. Inhibitors of voltage-dependent Ca2+ channels and removal of external Ca2+ abolished Ca2+ oscillations, indicating that Ca2+ influx was critical for generating Ca2+ oscillations. To better understand the phenomenon of Ca2+oscillations in glomus cells, we examined the potential role of oscillations in cell membrane potential (Em) in CB cells in triggering Ca2+ influx and Ca2+ oscillations. Using the cell-attached patch configuration, we assessed cell Em by recording TASK single channels, because a linear relationship exists between TASK amplitude and cell Em. Recording of TASK in CB cells in normoxia showed that many CB cells exhibit oscillations in TASK amplitude, indicating the presence of spontaneous oscillations in cell Em. The oscillation frequency of cell Em was similar to that of Ca2+ oscillations. Oscillations in TASK single channel amplitude were blocked by nifedipine (Ca2+ channel antagonist), by removal of extracellular Ca2+, and by 2-APB (an inhibitor of ER Ca2+ channel and store-operated Ca2+ entry). Mild hypoxia increased the frequency of oscillations of TASK amplitude, indicating that mild hypoxia increased the frequency of cell Em oscillations. These findings suggest that cell Em oscillations (that open voltage-dependent Ca2+ channels and increase Ca2+ influx) are an integral component of the cellular signaling mechanism by which Ca2+ oscillations are produced in CB cells. This work was funded by National Institutes of Health (NIH) grants to D.K. (HL111497) and C.W. (HL142906), and an award from Rosalind Franklin University of Medicine and Science. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Functional modulation of sarcolemmal KATP channels by atrial natriuretic peptide-elicited intracellular signaling in adult rabbit ventricular cardiomyocytes.

ATP-sensitive potassium (KATP) channels couple cell metabolic status to membrane excitability and are crucial for stress adaptation and cytoprotection in the heart. Atrial natriuretic peptide (ANP), a cardiac peptide important for cardiovascular homeostasis, also exhibits cytoprotective features including protection against myocardial ischemia-reperfusion injuries. However, how ANP modulates cardiac KATP channels is largely unknown. In the present study we sought to address this issue by investigating the role of ANP signaling in functional modulation of sarcolemmal KATP (sarcKATP) channels in ventricular myocytes freshly isolated from adult rabbit hearts. Single-channel recordings were performed in combination with pharmacological approaches in the cell-attached patch configuration. Bath application of ANP markedly potentiated sarcKATP channel activities induced by metabolic inhibition with sodium azide, whereas the KATP-stimulating effect of ANP was abrogated by selective inhibition of the natriuretic peptide receptor type A (NPR-A), cGMP-dependent protein kinase (PKG), reactive oxygen species (ROS), extracellular signal-regulated protein kinase (ERK)1/2, Ca2+/calmodulin-dependent protein kinase II (CaMKII), or the ryanodine receptor (RyR). Blockade of RyRs also nullified hydrogen peroxide (H2O2)-induced stimulation of sarcKATP channels in intact cells. Furthermore, single-channel kinetic analyses revealed that ANP enhanced the function of ventricular sarcKATP channels through destabilizing the long closures and facilitating the opening transitions, without affecting the single-channel conductance. In conclusion, here we report that ANP positively modulates the activity of ventricular sarcKATP channels via an intracellular signaling mechanism consisting of NPR-A, PKG, ROS, ERK1/2, CaMKII, and RyR2. This novel mechanism may regulate cardiac excitability and contribute to cytoprotection, in part, by opening myocardial KATP channels.

Leptin directly regulate intrinsic neuronal excitability in hypothalamic POMC neurons but not in AgRP neurons in food restricted mice

Leptin plays a pivotal role in the central control of energy balance through leptin receptors expressed on specific hypothalamic nuclei. Leptin suppresses food intake and body weight and ameliorates hyperglycemia by acting on the AgRP and POMC neurons of the arcuate nucleus. Leptin action on POMC neurons are essential for control of body weight and blood glucose levels and are known to be mediated by JAK-STAT3 and PI3K signalling pathway thus increase POMC mRNA and intrinsic excitability. The effects of leptin on AgRP neurons are not as clear although it has been reported to hyperpolarize AgRP neurons through change of K+ conductance.Using cell-attached patch and whole cell patch configuration, we directly assessed neuronal response to leptin in GFP labelled AgRP or POMC neurons in mice after 18 h of food deprivation. We found leptin has a direct effect on POMC neuron through increased intrinsic excitability and decreased inhibitory synaptic inputs. However, leptin does not have any effect on intrinsic excitability of AgRP neurons in fasted condition although food deprivation induced increase of firing frequency of AgRP neurons. In conclusion, leptin probably has a direct and acute effect on POMC neurons but not on AgRP neurons to control their excitability within feeding-regulatory neuronal circuitry.

Functional coupling between sodium-activated potassium channels and voltage-dependent persistent sodium currents in cricket Kenyon cells

In this study, we examined the functional coupling between Na(+)-activated potassium (KNa) channels and Na(+) influx through voltage-dependent Na(+) channels in Kenyon cells isolated from the mushroom body of the cricket Gryllus bimaculatus. Single-channel activity of KNa channels was recorded with the cell-attached patch configuration. The open probability (Po) of KNa channels increased with increasing Na(+) concentration in a bath solution, whereas it decreased by the substitution of Na(+) with an equimolar concentration of Li(+). The Po of KNa channels was also found to be reduced by bath application of a high concentration of TTX (1 μM) and riluzole (100 μM), which inhibits both fast (INaf) and persistent (INaP) Na(+) currents, whereas it was unaffected by a low concentration of TTX (10 nM), which selectively blocks INaf. Bath application of Cd(2+) at a low concentration (50 μM), as an inhibitor of INaP, also decreased the Po of KNa channels. Conversely, bath application of the inorganic Ca(2+)-channel blockers Co(2+) and Ni(2+) at high concentrations (500 μM) had little effect on the Po of KNa channels, although Cd(2+) (500 μM) reduced the Po of KNa channels. Perforated whole cell clamp analysis further indicated the presence of sustained outward currents for which amplitude was dependent on the amount of Na(+) influx. Taken together, these results indicate that KNa channels could be activated by Na(+) influx passing through voltage-dependent persistent Na(+) channels. The functional significance of this coupling mechanism was discussed in relation to the membrane excitability of Kenyon cells and its possible role in the formation of long-term memory.

A novel GABAergic action mediated by functional coupling between GABAB-like receptor and two different high-conductance K+channels in cricket Kenyon cells

The γ-aminobutyric acid type B (GABA(B)) receptor has been shown to attenuate high-voltage-activated Ca(2+) currents and enhance voltage-dependent or inwardly rectifying K(+) currents in a variety of neurons. In this study, we report a novel coupling of GABA(B)-like receptor with two different high-conductance K(+) channels, Na(+)-activated K(+) (K(Na)) channel and Ca(2+)-activated K(+) (K(Ca)) channel, in Kenyon cells isolated from the mushroom body of the cricket brain. Single-channel activities of K(Na) and K(Ca) channels in response to bath applications of GABA and the GABA(B)-specific agonist SKF97541 were recorded with the cell-attached patch configuration. The open probability (P(o)) of both K(Na) and K(Ca) channels was found to be increased by bath application of GABA, and this increase in Po was antagonized by coapplication of the GABAB antagonist CGP54626, suggesting that GABA(B)-like receptors mediate these actions. Similarly, GABA(B)-specific agonist SKF97541 increased the Po of both K(Na) and K(Ca) channels. Perforated-patch recordings using β-escin further revealed that SKF97541 increased the amplitude of the outward currents elicited by step depolarizations. Under current-clamp conditions, SKF97541 decreased the firing frequency of spontaneous action potential (AP) and changed the AP waveform. The amplitude and duration of AP were decreased, whereas the afterhyperpolarization of AP was increased. Resting membrane potential, however, was not significantly altered by SKF97541. Taken together, these results suggest that GABA(B)-like receptor is functionally coupled with both K(Na) and K(Ca) channels and this coupling mechanism may serve to prevent AP formation and limit excitatory synaptic input.

Activation of cGMP-Dependent Protein Kinase Stimulates Cardiac ATP-Sensitive Potassium Channels via a ROS/Calmodulin/CaMKII Signaling Cascade

BackgroundCyclic GMP (cGMP)-dependent protein kinase (PKG) is recognized as an important signaling component in diverse cell types. PKG may influence the function of cardiac ATP-sensitive potassium (KATP) channels, an ion channel critical for stress adaptation in the heart; however, the underlying mechanism remains largely unknown. The present study was designed to address this issue.Methods and FindingsSingle-channel recordings of cardiac KATP channels were performed in both cell-attached and inside-out patch configurations using transfected human embryonic kidney (HEK)293 cells and rabbit ventricular cardiomyocytes. We found that Kir6.2/SUR2A (the cardiac-type KATP) channels were activated by cGMP-selective phosphodiesterase inhibitor zaprinast in a concentration-dependent manner in cell-attached patches obtained from HEK293 cells, an effect mimicked by the membrane-permeable cGMP analog 8-bromo-cGMP whereas abolished by selective PKG inhibitors. Intriguingly, direct application of PKG moderately reduced rather than augmented Kir6.2/SUR2A single-channel currents in excised, inside-out patches. Moreover, PKG stimulation of Kir6.2/SUR2A channels in intact cells was abrogated by ROS/H2O2 scavenging, antagonism of calmodulin, and blockade of calcium/calmodulin-dependent protein kinase II (CaMKII), respectively. Exogenous H2O2 also concentration-dependently stimulated Kir6.2/SUR2A channels in intact cells, and its effect was prevented by inhibition of calmodulin or CaMKII. PKG stimulation of KATP channels was confirmed in intact ventricular cardiomyocytes, which was ROS- and CaMKII-dependent. Kinetically, PKG appeared to stimulate these channels by destabilizing the longest closed state while stabilizing the long open state and facilitating opening transitions.ConclusionThe present study provides novel evidence that PKG exerts dual regulation of cardiac KATP channels, including marked stimulation resulting from intracellular signaling mediated by ROS (H2O2 in particular), calmodulin and CaMKII, alongside of moderate channel suppression likely mediated by direct PKG phosphorylation of the channel or some closely associated proteins. The novel cGMP/PKG/ROS/calmodulin/CaMKII signaling pathway may regulate cardiomyocyte excitability by opening KATP channels and contribute to cardiac protection against ischemia-reperfusion injury.

Cell membrane stretch activates intermediate-conductance Ca2+-activated K+ channels in arterial smooth muscle cells

The aim of this study is to determine the signal transduction of membrane stretch on intermediate-conductance Ca(2+)-activated K(+) (IKca) channels in rat aorta smooth muscle cells using the patch-clamp technique. To stretch the cell membrane, both suction to the rear end of patch pipette and hypotonic shock were used. In cell-attached and inside-out patch configurations, the open probability of IKca channels increased when 20- to 45-mmHg suction was applied. Hyposmotic swelling efficiently increased IKca channel current. When the Ca(2+)-free solution was superfused, the activation of IKca current by the hyposmotic swelling was reduced. Furthermore, gadolinium (Gd(3+)) attenuated the activation of IKca channels induced by hyposmotic swelling, whereas nicardipine did not. In the experiments with Ca(2+)-free bath solution, pretreatment with GF109203X, a protein kinase C (PKC) inhibitor, completely abolished the stretch-induced activation of IKca currents. The stretch-induced activation of IKca channels was strongly inhibited by cytochalasin D, indicating a role for the F-actin in modulation of IKca channels by changes in cell stretching. These data suggest that cell membrane stretch activates IKca channels. In addition, the activation is associated with extracellular Ca(2+) influx through stretch-activated nonselective cation channels, and is also modulated by the F-actin cytoskeleton and the activation of PKC.

Aromatic Residues ∈Trp-55 and δTrp-57 and the Activation of Acetylcholine Receptor Channels

The two transmitter binding sites of the neuromuscular acetylcholine (ACh) receptor channel contain several aromatic residues, including a tryptophan located on the complementary, negative face of each binding pocket. These two residues, Trp-55 in the epsilon subunit and Trp-57 in the delta subunit, were mutated (AEFHILRVY), and for most constructs the rate constants for acetylcholine binding and channel gating were estimated by using single channel kinetic analyses. The rate constants for unliganded channel opening and closing were also estimated for some mutants. From these measurements we calculated all of the equilibrium constants of the "allosteric" cycle as follows: diliganded gating, unliganded gating, dissociation from the C(losed) conformation, and dissociation from the O(pen) conformation. The results indicate the following. (i) These aromatic side chains play a relatively minor role in ACh receptor channel activation. (ii) The main consequence of mutations is to reduce the affinity of the O conformation of the binding site for ACh, with the effect being greater at the epsilon subunit. (iii) In epsilon (but not delta) the aromatic nature of the side chain is important in determining affinity, to a slightly greater degree in the O conformation. Phi value analyses (of both tryptophan residues) show Phi approximately 1 for both the ACh binding and diliganded gating reactions. (iv) This suggests that the structural boundaries of the dynamic elements of the gating conformational change may not be subunit-delimited, and (v) the mutated tryptophan residues experience energy changes that occur relatively early in both the ligand-binding and channel-gating reactions.

Effects of µ-Opioid Agonist on ATP-sensitive Potassium Channel Activity in Isolated Ventricular Cardiomyocytes

It is well known that opioid agonists are released from the myocardium during hypoxia or ischemia, and that ATP-sensitive potassium channels (KATP channels) exist in the cardiac cell membrane and function as a cardioprotector preventing the myocardium from ischemic damage. In the present study, therefore, to determine whether opioid agonists are involved in the regulation of ATP-sensitive potassium channel activities, effects of the μ-opioid agonist DAMGO were examined on KATP channel activities by using excised inside-out and cell-attached patch clamp techniques in enzymatically (collagenase and protease) isolated mouse ventricular cardiac myocytes. In the excised inside-out patches, DAMGO (1∼300 μmol/L) inhibited KATP channel activities in a dose-dependent manner. KATP channel activity, which had been attenuated by the addition of ATP (100 μmol/L) to the internal solution, was not reactivated by DAMGO. The fashion of the single-channel inhibition by DAMGO was that both channel opening frequency and mean open-time were decreased, but the amplitudes of single channel currents and channel conductances were not altered. The half-maximal inhibition concentration (IC50) for DAMGO was 18 μmol/L. In the cellattached patch configuration, however, DAMGO (1∼300 μmol/L) increased dinitrophenol (50 μmol/L)induced KATP channel activities. It was inferred that the μ-opioid agonist is involved in the regulation of ATP-sensitive potassium channel activity in cardiac myocardium, agonizing (through internal target) or antagonizing (through external target) the inhibitory action of ATP in a competitive manner, thereby attenuating or enhancing the channel openings.

An Ion Selectivity Filter in the Extracellular Domain of Cys-loop Receptors Reveals Determinants for Ion Conductance

Neurotransmitter binding to Cys-loop receptors promotes a prodigious transmembrane flux of several million ions/s, but to date, structural determinants of ion flux have been identified flanking the membrane-spanning region. Using x-ray crystallography, sequence analysis, and single-channel recording, we identified a novel determinant of ion conductance near the point of entry of permeant ions. Co-crystallization of acetylcholine-binding protein with sulfate anions revealed coordination of SO4(2-) with a ring of lysines at a position equivalent to 24 A above the lipid membrane in homologous Cys-loop receptors. Analysis of multiple sequence alignments revealed that residues equivalent to the ring of lysines are negatively charged in cation-selective receptors but are positively charged in anion-selective receptors. Charge reversal of side chains at homologous positions in the nicotinic receptor from the motor end plate decreases unitary conductance up to 80%. Selectivity filters stemming from transmembrane alpha-helices have similar pore diameters and compositions of amino acids. These findings establish that when the channel opens under a physiological electrochemical gradient, permeant ions are initially stabilized within the extracellular vestibule of Cys-loop receptors, and this stabilization is a major determinant of ion conductance.

Microfluidic Chip to Produce Temperature Jumps for Electrophysiology

We developed a microfluidic chip that provides rapid temperature changes and accurate temperature control of the perfusing solution to facilitate patch-clamp studies. The device consists of a fluid channel connected to an accessible reservoir for cell culture and patch-clamp measurements. A thin-film platinum heater was placed in the flow channel to generate rapid temperature change, and the temperature was monitored using a thin-film resistor. We constructed the thermal chip using SU-8 on a glass wafer to minimize the heat loss. The chip is capable of increasing the solution temperature from bath temperature (20 degrees C) to 80 degrees C at an optimum heating rate of 0.5 degrees C/ms. To demonstrate the ability of the thermal chip, we have conducted on-chip patch-clamp recordings of temperature-sensitive ion channels (TRPV1) transfected HEK293 cells. The heat-stimulated currents were observed using whole-cell and cell-attached patch configurations. The results demonstrated that the chip can provide rapid temperature jumps at the resolution of single-ion channels.

Emergence of a spermine-sensitive, non-inactivating conductance in mature hippocampal CA1 pyramidal neurons upon reduction of extracellular Ca 2+: Dependence on intracellular Mg 2+ and ATP

Large and protracted elevations of intracellular [Ca 2+] and [Na +] play a crucial role in neuronal injury in ischemic conditions. In addition to excessive glutamate receptor activation, other ion channels may contribute to disruption of intracellular ionic homeostasis. During episodes of ischemia, extracellular [Ca 2+] falls significantly. Here we report the emergence of an inward current in hippocampal CA1 pyramidal neurons in acute brain slices from adult mice upon reduction/removal of [Ca 2+] e. The magnitude of the current was 100–300 pA at −65 mV holding potential, depending on intracellular constituents. The current was accompanied by intense neuronal discharge, observed in both whole-cell and cell-attached patch configurations. Sustained currents and increased neuronal firing rates were both reversed by restoration of physiological levels of [Ca 2+] e, or by application of spermine (1 mM). The amplitudes of the sustained currents were strongly reduced by raising intracellular [Mg 2+], but not by extracellular [Mg 2+] increases. Elevated intracellular ATP also reduced the current. This conductance is similar in several respects to the “calcium-sensing, non-selective cation current” (csNSC), previously described in cultured mouse hippocampal neurons of embryonic origin. The dependence on intracellular [ATP] and [Mg 2+] shown here, suggests a possible role for this current in disruption of ionic homeostasis during metabolic stress that accompanies excessive neuronal stimulation.

Electrophysiological characterization of native Na+–HCO3– cotransporter current in bovine parotid acinar cells

Using patch-clamp and molecular biological techniques, we identified and characterized membrane currents most likely generated by an electrogenic Na+-HCO3- cotransporter (NBCe) in acutely dissociated bovine parotid acinar (BPA) cells. When BPA cells were dialysed with a N-methyl-D-glucamine (NMDG)-glutamate-rich pipette solution, switching a Na-glutamate-rich, nominally HCO3--free bath solution to the one containing 25 mM HCO3-, but not Cl-, elicited a whole-cell current with a linear current-voltage relation. The HCO3- evoked current was abolished by total replacement of extracellular Na+ (Na+o) with NMDG or by 0.5 mM 4,4'-diisothiocyanato-stilbene-2,2'-disulfonic acid (DIDS), and was only partially supported by Li+o, but not by K+o, Cs+o, and cholineo. The reversal potential shift of DIDS (0.5 mM)-sensitive current induced by a change of [Na+]o corresponded to an apparent coupling ratio of HCO3- to Na+ of 2. RT-PCR analysis showed the presence of transcripts of NBCe1-B, but not NBCe1-A in BPA cells. Electrophysiological and pharmacological properties of whole-cell currents recorded from HEK293 cells transfected with the NBCe1-B, which was cloned from BPA cells resembled those of the native currents. Non-invasive measurements of membrane potential changes in the cell-attached patch configuration indicated that an NBCe activity is present in intact unstimulated BPA cells bathed in a 25 mM HCO3--containing solution. Collectively, these results not only suggest that an NBCe is present, functional and may be mediated, at least in part, by NBCe1-B in BPA cells, but also provide the first electrophysiological characterization of transport properties of NBCe expressed in native exocrine glands.

Isoflurane-induced facilitation of the cardiac sarcolemmal K(ATP) channel.

Volatile anesthetics have cardioprotective effects that mimic ischemic preconditioning, including the involvement of adenosine triphosphate-sensitive potassium (K(ATP)) channels. However, evidence for a direct effect of volatile anesthetic on the K(ATP) channel is limited. In this study, the effects of isoflurane on the cardiac sarcolemmal K(ATP) channel were investigated. Single ventricular myocytes were enzymatically isolated from guinea pig hearts. Whole cell and single-channel configurations, specifically the cell-attached and inside-out patch mode, of the patch clamp technique were used to monitor sarcolemmal K(ATP) channel current. In the cell-attached patch configuration, 2,4-dinitrophenol (150 microm) opened the sarcolemmal K(ATP) channel. Isoflurane (0.5 mm) further increased channel open probability and the number of active channels in the patch. In contrast, in the inside-out patch experiments, isoflurane had no significant effect on the K(ATP) channel activated by low ATP (0.2-0.5 mm). In addition, isoflurane had no effect on the K(ATP) channel when activated by adenosine diphosphate, adenosine + guanosine triphosphate, bimakalim, and 2,4-dinitrophenol under inside-out patch configurations. When K(ATP) current was monitored in the whole cell mode, isoflurane alone was unable to elicit channel opening. However, during sustained protein kinase C activation by 12,13-dibutyrate, isoflurane activated the K(ATP) current that was sensitive to glibenclamide. In contrast, isoflurane had no effect on the K(ATP) channel activated by 12,13-dibutyrate in a cell-free environment. Isoflurane facilitated the opening of the sarcolemmal K(ATP) channel in the intact cell, but not in an excised, inside-out patch. The isoflurane effect was not due to a direct interaction with the K(ATP) channel protein, but required an intracellular component, likely including the translocation of specific protein kinase C isoforms. This suggests that the sarcolemmal K(ATP) channel may have a significant role in anesthetic-induced preconditioning.

Mechanisms of modulation of neuronal nicotinic receptors by substance P and OAG.

Substance P is known to modulate neuronal nicotinic acetylcholine receptors (nAChRs) in the sympathetic nervous system. There are two conflicting proposals for the mechanism of this effect, an indirect action mediated by protein kinase C (PKC) and a direct interaction with receptor subunits. We studied the mechanisms of this effect in PC-12 cells. Substance P enhanced the decay of the nicotine-induced whole cell current. This effect was fast in its onset and was not antagonized by guanosine 5'-O-(2-thiodiphosphate), a G protein blocker, or staurosporine, a nonselective PKC blocker. Staurosporine failed to reverse the inhibition by 1-oleoyl-2-acetyl-sn-glycerol (OAG), a synthetic diacylglycerol analog known to activate PKC. The inhibitory effects of the peptide and OAG were preserved in excised patches, but substance P applied to the extra patch membrane was ineffective in the cell-attached patch configuration. We conclude that substance P modulates neuronal nAChRs most likely by direct interactions with the receptors but independently from activation of PKC or G proteins and that PKC does not participate in modulation by OAG.

Epidermal growth factor activates store-operated calcium channels in human glomerular mesangial cells.

Acellular influx of Ca2+ is critical for initiating and maintaining growth in a variety of cell types. Experiments were performed to determine whether epidermal growth factor (EGF), which is known to initiate a proliferative response in mesangial cells, could regulate by intracellular signal transduction the store-operated Ca2+ channels (SOC) of human mesangial cells (HMC) in culture. The cell-attached patch configuration was used to monitor the activity of SOC, with 90 mM Ba2+ in the pipette and physiologic saline solution in the bath. Under control conditions, the mean NP(o) value was 1.06 at a holding potential of -80 mV. When 100 nM EGF was added to the bath, SOC were activated by 53%. The EGF-evoked response was dose-dependent, with a half-maximal activation concentration of 4.8 nM. An inhibitor of tyrosine kinase, i.e., tyrphostin A23 (100 microM), completely abolished EGF-evoked channel activation. EGF combined with the inactive control compound tyrphostin A1 (100 microM) elicited significant (85%) activation of SOC. Calphostin C, an inhibitor of protein kinase C (PKC), did not affect the baseline activity of SOC but abolished the EGF-evoked enhancement of SOC activity. The PKC activator phorbol-12-myristate-13-acetate (PMA) significantly activated SOC. However, the effects of PMA were duplicative rather than additive or potentiating with maximal concentrations (100 nM) of EGF, suggesting that PMA and EGF activate SOC through a common PKC pathway. In addition, downregulation of PKC via incubation of HMC with PMA for 1 to 20 h depressed both basal activity and EGF-induced activation of SOC. It is concluded that EGF stimulates SOC in HMC through an intracellular signaling mechanism involving tyrosine kinase and PKC.

Lysophospholipids Open the Two-pore Domain Mechano-gated K+ Channels TREK-1 and TRAAK

The two-pore (2P) domain K(+) channels TREK-1 and TRAAK are opened by membrane stretch as well as arachidonic acid (AA) (Patel, A. J., Honoré, E., Maingret, F., Lesage, F., Fink, M., Duprat, F., and Lazdunski, M. (1998) EMBO J. 17, 4283-4290; Maingret, F., Patel, A. J., Lesage, F., Lazdunski, M., and Honoré, E. (1999) J. Biol. Chem. 274, 26691-26696; Maingret, F., Fosset, M., Lesage, F., Lazdunski, M. , and Honoré, E. (1999) J. Biol. Chem. 274, 1381-1387. We demonstrate that lysophospholipids (LPs) and platelet-activating factor also produce large specific and reversible activations of TREK-1 and TRAAK. LPs activation is a function of the size of the polar head and length of the acyl chain but is independent of the charge of the molecule. Bath application of lysophosphatidylcholine (LPC) immediately opens TREK-1 and TRAAK in the cell-attached patch configuration. In excised patches, LPC activation is lost, whereas AA still produces maximal opening. The carboxyl-terminal region of TREK-1, but not the amino terminus and the extracellular loop M1P1, is critically required for LPC activation. LPC activation is indirect and may possibly involve a cytosolic factor, whereas AA directly interacts with either the channel proteins or the bilayer and mimics stretch. Opening of TREK-1 and TRAAK by fatty acids and LPs may be an important switch in the regulation of synaptic function and may also play a protective role during ischemia and inflammation.

Lactate stimulates insulin secretion without blocking the K+ channels in HIT-T15 insulinoma cells.

To clarify the mechanism by which lactate affects insulin secretion, we investigated the effect of lactate on insulin secretion, cytosolic free Ca2+ ([Ca2+](i), the ATP sensitive K+ channel (K(ATP)) and the Ca2+-activated K+ channel (K(Ca)) in HIT-T15 cells, and the results were compared with those of glucose and glibenclamide. All three agents caused insulin secretion and increased [Ca2+](i), but the effects on the K+ channels were different. In cell-attached patch configurations, 10 mmol/l glucose blocked both the K(ATP) and KCa channels, while 100 nmol/l glibenclamide had no effect on KCa channels, but blocked K(ATP) channels. Lactate at a concentration of 10 mmol/l activated both the K(ATP) and KCa channels, not only in cell-attached, but also in inside-out patch configurations, indicating that the increase in [Ca2+](i) and secretion of insulin by lactate cannot be explained by the blocking of the K+ channels. Lactate, at concentrations of 10 mmol/l and 50 mmol/l decreased 45Ca2+ efflux, while glibenclamide increased the efflux. These results suggest that the lactate-induced Ca2+ increase is not due to the closing of K+ channels, but at least in part, to the suppression of Ca2+ efflux from HIT cells.

Two types of external Cl(-)-dependent Cl(-) channels and one type of stretch receptor cation channel contribute to the formation of isotonic blastocoel fluid in early medaka fish embryo.

Ionic channels in blastoderm cells dissociated from medaka fish embryos at the late blastula stage were studied by the patch-clamp technique in whole-cell, inside-out and cell-attached patch configurations. These cells were mechanically dissociated without using proteo-lytic enzymes. I have reported previously an external anion-dependent type I Cl(-) channel, which was observed at the early blastula stage, and its voltage dependency shifted toward the positive direction with a reduction in [Cl(-)](o). The type I Cl(-) channel was observed in about half of the blastoderm cells at the late blastula stage. I also observed another external anion-dependent Cl(-) channel (type II) whose voltage dependency shifted toward the negative direction with a reduction in [Cl(-)](o) and a cation selective stretchactivated channel. The$coexistence of the type II Cl(-) channel and stretch-activated cation channel would produce the efflux of both cations and anions in response to low ionic strength fluid. Further, the initial rise of blastocoel [Cl(-)] by this mechanism would trigger positive feedback between the type I Cl(-) channel conductance and blastocoel [Cl(-)]. At the early blastula stage, the blastocoel cavity fluid has a low ionic strength similar to that of pond water. I proposed that the cooperation of three types of ion channels at the late blastula stage generates isotonic blastocoel cavity fluid.

Dendritic Hyperpolarization-Activated Currents Modify the Integrative Properties of Hippocampal CA1 Pyramidal Neurons

Step hyperpolarizations evoked slowly activating, noninactivating, and slowly deactivating inward currents from membrane patches recorded in the cell-attached patch configuration from the soma and apical dendrites of hippocampal CA1 pyramidal neurons. The density of these hyperpolarization-activated currents (Ih) increased over sixfold from soma to distal dendrites. Activation curves demonstrate that a significant fraction of Ih channels is active near rest and that the range is hyperpolarized relatively more in the distal dendrites. Ih activation and deactivation kinetics are voltage-and temperature-dependent, with time constants of activation and deactivation decreasing with hyperpolarization and depolarization, respectively. Ih demonstrated a mixed Na+-K+ conductance and was sensitive to low concentrations of external CsCl. Dual whole-cell recordings revealed regional differences in input resistance (Rin) and membrane polarization rates (taumem) across the somatodendritic axis that are attributable to the spatial gradient of Ih channels. As a result of these membrane effects the propagation of subthreshold voltage transients is directionally specific. The elevated dendritic Ih density decreases EPSP amplitude and duration and reduces the time window over which temporal summation takes place. The backpropagation of action potentials into the dendritic arborization was impacted only slightly by dendritic Ih, with the most consistent effect being a decrease in dendritic action potential duration and an increase in afterhyperpolarization. Overall, Ih acts to dampen dendritic excitability, but its largest impact is on the subthreshold range of membrane potentials where the integration of inhibitory and excitatory synaptic inputs takes place.