Calcium-dependent transient potassium outward current in the marine ciliate Euplotes vannus

In the marine hypotrichous ciliate Euplotes vannus, the transient K+ outward current, IK fast, was studied by use of a single-microelectrode voltage-clamp equipment. Activation and inactivation kinetics, and steady-state inactivation are comparable to the properties of A-currents. Not typical for this type of current is its insensitivity to either 4-AP or 3,4-AP and its Ca2+ dependence which was derived from its inhibition by either extracellular Cd2+, La3+, D-600, or by intracellular BAPTA. Actual amplitudes of IK fast were obtained from a composite current, by subtraction of early parts of a slowly activating K+ current, IK slow, and of the early, transient Ca2+ inward current, ICa fast, that is typical for ciliates. IK fast counteracts ICa fast during the first milliseconds after onset of depolarization such that the composite current is purely outward directed.     

Properties of barnacle photoreceptor cells in culture

1. Properties of median photoreceptor cells in cultured ocelli from the giant barnacle (Balanus nubilus) were compared in isolated ocelli, ocelli maintained with the supraesophageal ganglion, and fresh ocelli. 2. Cultured photoreceptor cells exhibited slight deterioration after 2-4 weeks. Cell bodies maintained their structure but apparently lost some dendrites. Electron micrographs revealed fewer rhabdomeres. Axons did not degenerate. 3. Intracellularly recorded responses to light in both cultured preparations were qualitatively normal with a small decrease in sensitivity and increase in input resistance. The waveforms of the light responses were normal. 4. The characteristic shadow reflex was maintained after 6 weeks.     

Adaptation and facilitation in the barnacle photoreceptor

The barnacle photoreceptor sensitivity may either decrease (light adaptation) or increase (facilitation) after exposure to a conditioning light. The balance between adaptation and facilitation is influenced by at least three factors: initial sensitivity state of the cell, external calcium concentration, and conditioning intensity. Cells of very high sensitivity show mainly adaptation, which appears only for higher conditioning intensities and is suppressed in low-calcium media. Less sensitive cells, or those whose sensitivity is reduced by injury or metabolic decay, exhibit facilitation, expecially in low-calcium media and at intermediate conditioning intensities. Both phenomena show recovery time-courses of seconds-to-minutes. Models are proposed which relate light adaptation, as previously suggested, to increased internal calcium concentration, and facilitation either to decreased internal calcium concentration or to decreased activation "affinity" of ion-channel-blocking sites.     

Calcium-dependent assembly of centrin-G-protein complex in photoreceptor cells

Photoexcitation of rhodopsin activates a heterotrimeric G-protein cascade leading to cyclic GMP hydrolysis in vertebrate photoreceptors. Light-induced exchanges of the visual G-protein transducin between the outer and inner segment of rod photoreceptors occur through the narrow connecting cilium. Here we demonstrate that transducin colocalizes with the Ca(2+)-binding protein centrin 1 in a specific domain of this cilium. Coimmunoprecipitation, centrifugation, centrin overlay, size exclusion chromatography, and kinetic light-scattering experiments indicate that Ca(2+)-activated centrin 1 binds with high affinity and specificity to transducin. The assembly of centrin-G-protein complex is mediated by the betagamma-complex. The Ca(2+)-dependent assembly of a G protein with centrin is a novel aspect of the supply of signaling proteins in sensory cells and a potential link between molecular translocations and signal transduction in general.     

Calcium activates and inactivates a photoreceptor soma potassium current.

Light-induced currents were measured with a two-microelectrode voltage clamp of type B photoreceptor somata, which had been isolated by axotomy from all synaptic interactions as well as from all membranes capable of generating impulse activity. In artificial seawater (ASW), light elicited a transient early inward current, INa+, which depended on Na+o and had a linear current-voltage relation and an extrapolated reversal potential of 30-40 mV (absolute). In 0-Na+ ASW, light elicited a transient short-latency outward current that dependent on K+o, increased exponentially with more positive voltages (greater than or equal to -40 mV), and reversed at -70 to -75 mV. This outward current was not blocked by Ca++ channel blockers (e.g., Cd++, Co++) or substitution of Ba++o, for Ca++o, but was reduced by iontophoretic injection of EGTA. In both ASW and 0-Na+ ASW, light also elicited a delayed, apparently inward current, which was associated with a decreased conductance, depended on K+o, increased exponentially with more positive voltages (greater than or equal to -40 mV), reversed at the equilibrium potential for K+ flux in elevated K+o was eliminated by substitution of Ba++o for Ca++o, and was greatly reduced by Cd++o or Co++o. Thus, light elicited an early Ca++-dependent K+ current, IC, and a prolonged decrease of IC. Iontophoretic injection of Ca++ through a third microelectrode caused prolonged reduction of both IC and the light-induced decrease of IC, but did not alter ICa++ or the current-voltage relation of IC. Ruthenium red (1 microM) in the external medium caused a prolongation of the light-induced decrease of IC. Iontophoretic injection of EGTA often eliminated the light-induced IC decrease while decreasing peak IC (during depolarizing steps to -5 or 0 mV) by less than one-half. EGTA injection, on the average, did not affect steady state IC but reduced the light-induced decrease of steady state IC to approximately one-third of its original magnitude. The prolonged IC decrease, elicited by dim light in the absence of light-induced IC or INa+, was more completely eliminated by EGTA injection. It was concluded that light, in addition to inducing a transient inward Na+ current, causes both a transient increase and a prolonged decrease of IC via elevation of Ca++i.     

Hyperpolarization of a barnacle photoreceptor membrane following illumination

Membrane potential changes following illumination of a photoreceptor cell in the lateral ocellus of a barnacle (Balanus eburneus) were studied by means of intracellular recording and polarization techniques. Illumination produces a depolarizing response. When the illumination is terminated, the membrane potential temporarily becomes more negative than the resting potential prior to illumination. Although the amplitude of this postillumination hyperpolarization depends upon the intensity as well as the duration of the light pulse, the time course is fairly constant. The hyperpolarization is not associated with any significant membrane conductance increase and is abolished by 10^-5 M ouabain. It diminishes when the external Na or K ions are removed. An intracellular injection of Na ions produces a hyperpolarization similar to that following illumination. It is suggested that the postillumination hyperpolarization is produced by an electrogenic Na pump which is activated by the Na influx during illumination.     

The lateral photoreceptor of the barnacle,Balanus eburneus

Summary The lateral eye of the barnacle, Balanus eburneus, fixed in highly concentrated osmium is a lens-shaped body of approximately 250 m in diameter and about 75 m thick. It contains three photoreceptor cells which occupy about 42% of its volume. The photoreceptor cells are irregularly shaped and extend countless dendritic processes which bear rhabdomeres at their ends. Individual rhabdomeres come into contact with rhabdomeres originating from dendrites of the same or of one of the other visual cells. Thirteen per cent of the volume of the photoreceptor cells is taken up by the rhabdomeres. The membranes of the rhabdomeric microvilli contain globular subunits which suggest a 70 Å spacing of rhodopsin molecules. There are two kinds of glial cells. One kind, type A glial cells, makes contact with the fibrous capsule of the photoreceptor. The other kind, type B glial cells, is associated with the photoreceptor cells and extends countless tiny cytoplasmic extensions which interdigitate with similar extensions of the receptor cells. There are approximately 95 type B glial cells and 130 type A glial cells in the receptor. The cytoplasm of the photoreceptor cells contains countless small Golgi fields, mitochondria, microtubules, multivesicular and multilamellar bodies. The extracellular space of the photoreceptor is less than 0.1% of its total volume.The authors wish to thank Mrs. G. Theisen and Miss D. Hupp for expert technical assistance and Drs. M. Behrens, C. Helrich, and C.C. Krischer for many inspiring discussions. This study was partly supported by the SFB 160 of the Deutsche Forschungsgemeinschaft     

Calcium-dependent slow potassium conductance in rat skeletal myotubes

A prolonged hyperpolarizing afterpotential (amplitude 5–20 mV, half decay time about 400 msec at 25°C) follows the action potential in myotubes and myosacs cultured from rat skeletal muscle. This slow hyperpolarizing afterpotential (hap) is mediated by an increase in membrane K conductance, because its reversal potential follows the Nernst potential for K and is not affected by other ions. The conductance increase measured during the hap (up to four times the resting input conductance) correctly predicts the time course of the slow hap. The slow hap is Ca dependent. Its amplitude decreases when bath [Ca] is lowered, and both amplitude and duration increase when bath [Ca] is raised. The slow hap is blocked by intracellular injection of the calcium chelator, EGTA. It is inhibited by solutions containing 2–4 mM manganese or 1–5 mM barium, but is not blocked by 5–20 mM tetraethylammonium. Myotubes bathed in zero [Na], high [Ca] solutions show calcium action potentials, which are inhibited by 2–10 mM manganese, nickel or cobalt. Myotubes bathed in isotonic Ca salts (or in 2 mM Ca plus 5 mM caffeine) show long-lasting (up to 10 sec) spontaneous hyperpolarizations accompanied by prolonged contractions. These hyperpolarizations are associated with a large increase in input conductance, and they reverse in sign near the K equilibrium potential. They appear to reflect activation of the Ca-sensitive K conductance by Ca released from intracellular stores. The observation that spontaneous hyperpolarizations usually occur with no prior depolarization argues that at least a portion of the slow, Ca-sensitive K conductance system can be activated by internal Ca alone, with no requirement for plasma membrane depolarization. Cultured myotubes also have a faster K conductance system, which is inhibited by 5–20 mM tetraethylammonium or 1–5 mM barium, and is not dependent on Ca for its activation.     

Properties of the on-transient of the intracellular response in the barnacle photoreceptor

We have studied the on-transient of the receptor potential of the barnacle photoreceptor. Its amplitude has previously been shown to depend on light intensity and state of light-dark adaptation. We have examined its dependence on 1) the presence of a prolonged depolarizing afterpotential (PDA), 2) a background light, 3) added alcohol, or 4) decreased K⁺ concentration in the bath. We find that the relative on-transient amplitude tends to increase initially with increasing depolarization arising from 1)–4) and then to decrease again at higher depolarization. This behavior is qualitatively explainable by the cell's currentvoltage characteristics and by the adapting effect of the stimulus on the conductances arising from the PDA, the background light and the alcohol.Based on material presented at the European Neurosciences Meeting, Florence, September 1978     

Calcium-dependent sodium current in the marine ciliateEuplotes vannus

Summary Ca and Na inward currents were recorded upon depolarizations inEuplotes after the blockage of K outward currents with intracellular Cs ions. The Na current was analyzed under voltage clamp and had the following properties: it activated to a maximum within 150 msec and partly inactivated during sustained voltage steps. It had a positive equilibrium potential between 25 and 30 mV and could be carried by Na or Li ions but not by K, choline or Tris ions. The current revealed a prominent associated inward tail current which deactivated with a single-exponential time constant of 118 msec. Both the current and its tail were strongly reduced after reduction of the extracellular Na concentration. Externally applied K channel blocker tetraethylammonium chloride did not block the current. Either EGTA injection into the cell or nonlethal deciliation with ethanol eliminated the current and its tail. These results indicate the existence of a Na conductance within the membrane ofEuplotes which is activated by the intracellular level of free Ca²⁺.     

Sodium and potassium fluxes in isolated barnacle muscle fibers

Sodium and potassium influxes and outfluxes have been studied in single isolated muscle fibers from the giant barnacle both by microinjection and by external loading. The sodium influxes and outfluxes were 49 and 39 pmoles /cm²-sec (temperature = 15–16°C) respectively. The potassium influxes and outfluxes were 28 and 60 pmoles/cm²-sec (temperature = 13–16°C) respectively. Replacement of external sodium by lithium reduced sodium outflux by 67% but had no effect on potassium outflux. Removal of external potassum reduced the sodium outflux by 51% but had no effect on potassium outflux. External strophanthidin (10–30 µM) reduced sodium outflux by 80–90% and increased potassium outflux by 40% in normal fibers. The time constant for sodium exchange increased linearly with internal sodium concentration, as did the fraction of sodium outflux insensitive to a maximally inhibitory concentration of external strophanthidin in the range of 10 tO 80 mM internal sodium. The strophanthidin-sensitive component of sodium outflux could be related to the internal sodium concentration by the following empirical formula: See PDF for Equation     

Calcium-dependent potassium channel inParamecium studied under patch clamp

Summary We have studied a class of Ca _i ²⁺ -dependent K channels in inside-out excised membrane patches fromParamecium under patch clamp. Single channels had a conductance of 72 ±9.0 pS in a solution containing 100mM K⁺. The channels were selective for K⁺ over Rb⁺ with the permeability ratio of 1 0.56. and over Na⁺, Cs⁺ or NH ₄ ⁺ with a ratio 1<0.1. The channel activity was dependent on Ca _i ²⁺ , which was applied to the cytoplasmic side; the Ca _i ²⁺ concentration for the half maximal activation was 2 m. The Hill coefficient for the Ca _i ²⁺ dependence of the channel activity was 2.58, indicating that more than two Ca _i ²⁺ bindings are necessary for full activation. Unlike most Ca _i ²⁺ -dependent K channels in other organisms, the channels inParamecium were slightly more active upon hyperpolarization than upon depolarization. The voltage dependence was fitted to a Boltzmann curve with 41.2 mV pere-fold change in channel activity. While a high Ca _i ²⁺ concentration activated the channels, it also irreversibly reduced the channel activity over time. The decay of channel activity occurred faster at higher Ca _i ²⁺ concentrations. Quaternary ammonium ions suppressed ion passage through the channel; more highly alkylated quaternary ammonium ions were more efficient in blocking. Ba _i ²⁺ and Ca _i ²⁺ were relatively ineffective in blockage. It was concluded that these Ca _i ²⁺ -dependent K channels inParamecium are different from the previously described Ca _i ²⁺ -dependent K channels, and are perhaps of a novel class.     

Calcium-dependent potassium conductance in the photoresponse of a nudibranch mollusk

• 1.1. The response to light of Hermissenda photoreceptors when recorded intracellularly without interference from synaptic and action potentials consisted of three phases: an early depolarization (ED) followed by hyperpolarization (dip) and subsequent depolarization (tail).
• 2.2. The ED and the dip were associated with increased membrane conductance while decreased membrane conductance was involved with the tail.
• 3.3. The dip reversal potential was − 82.1 ± 5.3 mV and its amplitude varied inversely with the log of [K⁺].
• 4.4. Perfusing with agents which block K⁺ current like 4AP, Quinine, Quinidine or injection of TEA eliminated the dip and its associated increased membrane conductance, thus further supporting the role of K⁺ conductance in producing the dip.
• 5.5. The dip was enhanced by increased [Ca²⁺]_o, reduced by decreased [Ca²⁺]_o and abolished together with its associated increased membrane conductance when perfused with either D600, Cd²⁺, Mg²⁺, Mn²⁺, or Co²⁺, which block transmembrane Ca²⁺ current.
• 6.6. The dip and its associated increased membrane conductance were abolished by intracellular injection of EGTA and enhanced by perfusion with Ruthenium red.
• 7.7. Intracellular injection of Ca²⁺ mimicked the dip: membrane conductance was increased and the cell hyperpolarized.
• 8.8. These results indicate that the increase in intracellular [Ca²⁺] is primarily responsible for the light-induced increase of K⁺ conductance during the dip. The possible source of the Ca²⁺ is, at least in part, extracellular due to activation of an inward Ca²⁺ current.

     

Calcium-dependent chloride current in rat cerebellar Purkinje cell membranes

The presence of calcium-dependent potential-activated chloride currents in the membranes of freshly isolated rat cerebellar Purkinje cells (12–15 days) was shown by the whole-cell patch clamp technique. Chloride currents appeared in a sodium-free external solution and reversibly disappeared in the absence of external chloride and calcium ions.     

Calcium-dependent gating of MthK, a prokaryotic potassium channel

MthK is a calcium-gated, inwardly rectifying, prokaryotic potassium channel. Although little functional information is available for MthK, its high-resolution structure is used as a model for eukaryotic Ca(2+)-dependent potassium channels. Here we characterize in detail the main gating characteristics of MthK at the single-channel level with special focus on the mechanism of Ca(2+) activation. MthK has two distinct gating modes: slow gating affected mainly by Ca(2+) and fast gating affected by voltage. Millimolar Ca(2+) increases MthK open probability over 100-fold by mainly increasing the frequency of channel opening while leaving the opening durations unchanged. The Ca(2+) dose-response curve displays an unusually high Hill coefficient (n = approximately 8), suggesting strong coupling between Ca(2+) binding and channel opening. Depolarization affects both the fast gate by dramatically reducing the fast flickers, and to a lesser extent, the slow gate, by increasing MthK open probability. We were able to capture the mechanistic features of MthK with a modified MWC model.     

Diurnal modulation of photoreceptor potassium conductance in the locust

Single electrode clamp techniques demonstrated diurnal changes in photoreceptor membrane conductance, recorded intracellularly in the intact, dark-adapted retina of the locust Schistocerca gregaria. In the day, locust photoreceptors exhibited the membrane properties of fast cells, as previously defined in rapidly moving diurnal Diptera. Depolarization activated a powerful potassium conductance with two kinetic components, one rapidly activating close to resting potential and the other activating more slowly when further depolarized, giving a pronounced delayed rectification. There was little inactivation. At night, locust photoreceptors resembled slow cells, as defined in weakly flying crepuscular and nocturnal Diptera. Depolarization rapidly activated an outward current which then inactivated over 100 ms to reduce rectification. The change from day to night state was mimicked by applying 10 mM serotonin extracellularly to the retina. We conclude that the potassium conductances of locust photoreceptor membranes are modulated according to a diurnal rhythm, possibly by serotonin. This neuromodulation is used to match photoreceptor membrane properties to photic habitat. Our findings suggest a definite and potentially widespread function for serotonin as a mediator of diurnal changes in the insect visual system.     

Properties of tetraethylammonium ion-resistant K+ channels in the photoreceptor membrane of the giant barnacle

After the offset of illumination, barnacle photoreceptors undergo a large hyperpolarization that lasts seconds or minutes. We studied the mechanisms that generate this afterpotential by recording afterpotentials intracellularly from the medial photoreceptors of the giant barnacle Balanus nubilus. The afterpotential has two components with different time-courses: (a) an earlier component due to an increase in conductance to K+ that is not blocked by extracellular tetraethylammonium ion (TEA+) or 3-aminopyridine (3-AP) and (b) a later component that is sensitive to cardiac glycosides and that requires extracellular K+, suggesting that it is due to an electrogenic Na+ pump. The K+ conductance component increases in amplitude with increasing CA++ concentration and is inhibited by extracellular Co++; the Co++ inhibition can be overcome by increasing the Ca++ concentration. Thus, the K+ conductance component is Ca++ dependent. An afterpotential similar to that evoked by a brief flash of light is generated by depolarization with current in the dark and by eliciting Ca++ action potentials in the presence of TEA+ in the soma, axon, or terminal regions of the photoreceptor. The action potential undershoot is generated by an increase in conductance to K+ that is resistant to TEA+ and 3-AP and inhibited by Co++. The similarity in time-course and pharmacology of the hyperpolarization afterpotentials elicited by (a) a brief flash of light, (b) depolarization with current, and (c) an action potential indicates that Ca++-dependent K+ channels throughout the photoreceptor membrane are responsible for all three hyperpolarizing events.     

Stimulation by high external potassium of the sodium efflux in barnacle muscle fibers

Summary Single barnacle muscle fibers fromBalanus nubilus were used to study the effect of elevated external potassium concentration, [K] _o , on Na efflux, membrane potential, and cyclic nucleotide levels. Elevation of [K] _o causes a prompt, transient stimulation of the ouabain-insensitive Na efflux. The minimal effective concentrations is 20mm. The membrane potential of ouabain-treated fibers bathed in 10mm Ca²⁺ artificial seawater (ASW) or in Ca²⁺-free ASW decreases approximately linearly with increasing logarithm of [K] _o . The slope of the plot is slightly steeper for fibers bathed in Ca²⁺-free ASW. The magnitude of the stimulatory response of the ouabain-insensitive Na efflux to 100mmK _o depends on the external Na⁺ and Ca²⁺ concentrations, as well as on external pH, but is independent of external Mg²⁺ concentration. External application of 10^–4 m verapamil virtually abolishes the response of the Na efflux to subsequent K-depolarization. Stabilization of myoplasmic-free Ca²⁺ by injection of 250mm EGTA before exposure of the fiber to 100mm K _o leads to 60% reduction in the magnitude of the stimulation. Pre-injection of a pure inhibitor of cyclic AMP-dependent protein kinase reduces the response of the Na efflux to 100mm K _o by 50%. Increasing intracellular ATP, by injection of 0.5m ATP-Na₂ before elevation of [K] _o , fails to prolong the duration of the stimulation of the Na efflux. Exposure of ouabain-treated, cannulated fibers to 100mm K _o for time periods ranging from 30 sec to 10 min causes a small (60%), but significant, increase in the intracellular content of cyclic AMP with little change in the cyclic GMP level. These results are compatible with the view that the stimulatory response of the ouabain-insensitive Na efflux to high K _o is largely due to a fall in myoplasmicpCa resulting from activation of voltage-dependent Ca²⁺ channels and that an accompanying rise in internal cAMP accounts for a portion of this response.     

Calcium-dependent chloride current activated by hyposmotic stress in rat lacrimal acinar cells

We have identified a whole-cell Cl^– current activated by hyposmotic stress in rat lacrimal acinar cells using the patch-clamp technique. Superfusion of isolated single cells with hyposmotic solution (80% of control osmolarity) caused a gradual increase of the current, which was reversed on return to the control solution. The current-voltage relationship showed outward rectification, and the current showed time and voltage dependence: slowly activated by depolarizing voltages and rapidly inactivated by hyperpolarizing voltages. The increase in current was not observed when intracellular Ca²⁺ was chelated with EGTA. It was also inhibited by the absence of extracellular Ca²⁺, or the presence of gadolinium ions (20 m Gd³⁺). We conclude that in rat lacrimal acinar cells hyposmotic stress activates Ca²⁺-dependent Cl^– channels as a result of Ca²⁺ influx through a Gd³⁺-sensitive pathway. The Cl^– channels involved appear to be indistinguishable from those activated by muscarinic stimulation. The inhibitory effect of Gd³⁺ suggests that stretch-activated nonselective cation channels may be responsible for the Ca²⁺ influx.The authors are grateful to Prof. R.M. Case, Dr. A.C. Elliott and Dr. K.R. Lau for helpful discussion. This work was supported by the US Cystic Fibrosis Foundation, Wellcome Trust and Medical Research Council.