Current-voltage relationships of a sodium-sensitive potassium channel in the tonoplast ofChara corallina

Summary The membrane of mechanically prepared vesicles ofChara corallina has been investigated by patch-clamp techniques. This membrane consists of tonoplast as demonstrated by the measurement of ATP-driven currents directed into the vesicles as well as by the ATP-dependent accumulation of neutral red. Addition of 1mm ATP to the bath medium induced a membrane current of about 3.2 mA·m^–2 creating a voltage across the tonoplast of about –7 mV (cytoplasmic side negative). On excised tonoplast patches, currents through single K⁺-selective channels have been investigated under various ionic conditions. The open-channel currents saturate at large voltage displacements from the equilibrium voltage for K⁺ with limiting currents of about +15 and –30 pA, respectively, as measured in symmetric 250mm KCl solutions. The channel is virtually impermeable to Na⁺ and Cl^–. However, addition of Na⁺ decreases the K⁺ currents. TheI–V relationships of the open channel as measured at various K⁺ concentrations with or without Na⁺ added are described by a 6-state model, the 12 parameters of which are determined to fit the experimental data.     

Permeance of Cs+ and Rb+ through the inwardly rectifying K+ channel in guinea pig ventricular myocytes

Summary Inward currents carried by external Cs, Rb, NH₄ and K through theI _K1 channel were studied using a whole-cell voltage clamp technique. Cs, NH₄, and Rb currents could be recorded negative to –40 mV following depolarizing prepulses (0 mV and 200–1000 msec in duration). The current activation displayed an instantaneous component followed by a monoexponential increase () to a peak amplitude. Subsequent inactivation was fit by a single exponential, _i. With hyperpolarization, and _i decreasede-fold per 36 and 25 mV, respectively. In Ca-free external solutions (pipette [Mg]0.3mm), inactivation was absent, consistent with the hypothesis that inactivation represents time- and voltage-dependent block of Cs, NH₄, and Rb currents by external Ca. The inactivation and degree of steady-state block was greatest when Cs was the charge carrier, followed by NH₄, and then Rb. K currents, however, did not inactivate in the presence of Ca. Na and Li did not carry any significant current within the resolution of our recordings. Comparison ofpeak inward current ratios (I _x/I_K) as an index of permeability revealed a higher permeance of Cs (0.15), NH₄ (0.30), and Rb (0.51) relative to K (1.0) than that obtained by comparing thesteady-state current ratios (CsNH₄RbK0.010.060.211.0). At any given potential, was smaller the more permeant the cation. In the absence of depolarizing prepulses, the amplitude of was reduced. Divalent-free solutions did not significantly affect activatio in the presence of 0.3mm pipette [Mg]. When pipette [Mg] was buffered to 50 m, however, removal of external Ca and Mg lead to a four- to fivefold increase in Cs currents and loss of both time-dependent activation and inactivation (reversible upon repletion of external Ca).These results suggest that (i) permeability ratios forI _K1 should account for differences in the degree to which monovalent currents are blocked by extracellular Ca and (ii) extracellular or intracellular divalent cations contribute to the slow phase of activation which may represent either (a) the actual rate of Mg or Ca extrusion from the channel into the cell, a process which may be enhanced by repulsive interaction with the incoming permeant monovalent cation or (b) an intrinsic gating process that is strongly modulated by the permeant monovalent ion and divalent cations.     

Steady-state voltage-dependent gating and conduction kinetics of single K+ channels in the membrane of cytoplasmic drops ofChara australis

Summary Cytoplasmic drops, covered by a membrane derived from the tonoplast, were obtained from the internodal cells ofChara australis. Patch-clamp measurements were made on this membrane using the droplet-attached configuration with the membrane patch voltage clamped at values from –250 to 50 mV. Single-channel records, filtered at 5 kHz, were analyzed to elucidate the kinetics of the ion gating reaction of the K⁺-selective channel. The current-voltage characteristics for single channels exhibit saturation and are shown to be consistent with Läuger's theory of diffusion-limited ion flow through pores (P. Läuger,Biochim. Biophys. Acta 455:493–509, 1976). The time-averaged behavior of the K⁺ conductance has a maximum at –100 to –150 mV which is produced by the combination of two distinct mechanisms: (1) The channel spending more time in long-lived closed states at positive voltages and (2) a large decrease in the mean open lifetime at more negative voltages. The channel activity shows bursting behavior with opening and closing rates that are voltage-dependent. The mean open time is the kinetic parameter most sensitive to membrane potential, showing a maximum between –100 to –150 mV. The distribution of open times is dominated by one exponential component (time constant 0.3 to 10 msec). In some cases an additional rapidly decaying exponential component was detectable (time constant=0.1 msec). The closed distributions contained were observed to obtain up to four exponential components with time constants over the range 0.1 to 200 msec. However, the voltage dependence of the closed-time distributions suggests an eight-state model for this channel.     

Ion permeation in a K+ channel inChara australis: Direct evidence for diffusion limitation of ion flow in a maxi-K channel

Summary We report a study of a potassium-selective channel in the membrane delineating cytoplasmic drops fromChara australis. The relatively large conductance (170 pS in 150 mol/m³ (mm) KCl), high ion selectivity (P _Cl/P _K=0.015±0.01) and voltagedependent kinetics of this channel indicate that it is a type of maxi-K channel commonly found in animal cells but not previously detected in any plant cell.The current-voltage (I/V) characteristic of these channels was examined in drop-attached and in excised outside-out patches using the patch-clamp technique, over the unusually large voltage range of –250 to 200 mV. TheI/V characteristic is nonlinear and shows saturation at extreme voltages; the current also saturates at high [K⁺]. In solutions with symmetrical KCl concentrations the saturation behavior of the current is asymmetrical. The permeability of the channel depends on whether it is observed in excised or in drop-attached membrane patches.Here we investigate the main factors affecting the permeation of K⁺ ions through this maxi-K channel. We present the first direct evidence for the importance of diffusion external to the pore in limiting ion flow through maxi-K channels. The data are consistent with an ion translocation mechanism whose current is limited (i) at high voltages by ion diffusion external to the pore and (ii) at high [K⁺] by the maximum transport rate of the channel. We fit the data to a diffusion-limited pore model in which the pore exhibits saturation described by Michaelis-Menten kinetics with aK _m=50±25 mol/m³ andG _max=300±20 pS.     

Microtubule orientation in globular leaflet cells of <Emphasis Type="Italic">Chara inflata</Emphasis>

Chara inflata has globular leaflet cells and cylindrical internodal cells. The morphology of the leaflet cells is different from that of other Characeae. The orientation of cortical microtubules (MTs) in young leaflet and internodal cells of this species was analyzed by immunofluorescence microscopy. MTs with random orientation were observed in leaflet cells, while those relatively transverse to the cell axis were observed in cylindrical internodal cells. In cylindrical leaflet cells in Chara corallina, transverse MTs were observed. These results imply that C. inflata is a morphological mutant lacking a mechanism for orienting cortical MTs transverse in leaflet cells.     

Factors controlling the K+ conductance inChara

Summary Previous current/voltage (I/V) investigations of theChara K⁺ state have been extended by increasing the voltage range (up to +200 mV) through blocking the action potential with La³⁺. A region of negative slope was found in theI/V characteristics at positive PD's, similar to that already observed at PD's more negative than the resting level. These decreases in membrane currents at PD's more negative than –150 mV and at PD's close to 0 or positive are thought to arise from the K⁺ channel closure. Both the negative slope regions could be reversibly abolished by 0.1mm K⁺, 20mm Na⁺, more than 10mm Ca²⁺ or 5mm tetraethylammonium (TEA). The K⁺ channels are therefore blocked by TEA, closed by low [K⁺] _o or high [Ca²⁺] _o and are highly selective to K⁺ over Na⁺. With the K⁺ channels closed, the remainingI/V profile was approximately linear over the interval of 400 mV (suggesting a leakage current), but large rectifying currents were observed at PD's more positive than +50 mV. These currents showed a substantial decrease in high [Ca²⁺] _o , sometimes displayed a slight shift to more positive PD's with increasing [K⁺] _o and were unaffected by TEA or changes in [Na⁺] _o . The slope of the linear part of theI/V profile was steeper in low [K⁺] _o than in TEA or high [Na⁺] _o (indicating participation of K⁺, but not Na⁺, in the leak current). Diethylstilbestrol (DES) was employed to inhibit the proton pump, but it was found that the leakage current and later the K⁺ channels were also strongly affected.     

Noise analysis of the K+ current through the apical membrane ofNecturus gallbladder

Summary Current noise power spectra of the voltage-clamped (V=0)Necturus gallbladder, exposed to NaCl-Ringer's on both sides contained a relaxation noise component, which overlapped with a 1/f noise component, with being about 2. Substitution of all Na⁺ by K⁺ on either the serosal or mucosal side increased the relaxation as well as the 1/f noise component considerably. InNecturus gallbladder both noise components are reduced by addition of 10mm 2,4,6-triaminopyrimidine (TAP) or 5mm of tetraethylammonium (TEA⁺) added to ification of the mucosal solution to pH 5 and lower. Fivemm of tetraethylammonium (TEA⁺) added to the mucosal solution, abolished K⁺ relaxation noise and decreased the 1/f noise component. Applying a Cs⁺ concentration gradient across the epithelium did not yield relaxation noise. However, if Rb⁺ was substituted for all Na⁺ on one side, a Lorentzian noise component appeared in the spectrum. Its plateau was smaller than with KCl-Ringer's on the respective side. These data confirm the existence of fluctuating K⁺ channels in the apical membrane of theNecturus gallbladder. Furthermore it can be concluded that these channels have the permeability sequence K⁺>Rb⁺>Sc⁺. The inhibition of the fluctuations by mucosal acidification indicates the existence of acidic sites in the channel. The single-channel conductance was estimated to be between 6.5 and 40 pS.     

Ca2+-Activated K+ channel from human erythrocyte membranes: Single channel recification and selectivity

Summary The Ca²⁺-activated K⁺ channel of the human red cell membranes was characterized with respect to rectification and selectivity using the patch-clamp technique. In inside-out patches exposed to symmetric solutions of K⁺, Rb⁺, and NH ₄ ⁺ , respectively, inward rectifyingi-V curves were obtained. The zero current conductances were: K⁺ (23.5 pS±3.2)>NH ₄ ⁺ (14.2 pS±1.2)>Rb⁺ (11.4 pS±1.8). With low extracellular K⁺ concentrations (substitution with Na⁺) the current fluctuations reversed close to the Nernst potential for the K ion and the rectification as well as thei-V slopes decreased. With mixed intracellular solutions of K⁺ and Na⁺ enhanced rectification were observed due to a Na⁺ block of outward currents. From bi-ionic reversal potentials the following permeability sequence (P _K/P _X) was calculated: K⁺ (1.0)>Rb⁺ (1.4±0.1)>NH ₄ ⁺ (8.5±1.3)>Li⁺(>50); Na⁺ (>110); Cs⁺ (5). Li⁺, Na⁺, and Cs⁺ were not found to carry any current, and only minimum values of the permeability ratios were estimated. Tl⁺ was permeant, but the permeability and conductance were difficult to quantify, since with this ion the single channel activity was extremely low and the channels seemed to inactivate. The inward rectification in symmetric solutions indicate an asymmetric open channel structure, and the different selectivity sequences based on conductances and permeabilities reflect interionic interactions in the permeation process.     

Alcohol dehydrogenase polymorphism inDrosophila: Enzyme kinetics of product inhibition

Summary Because natural populations ofDrosophila melanogaster are polymorphic for different allozymes of alcohol dehydrogenase (ADH) and becauseD. melanogaster is more tolerant to the toxic effects of ethanol than its sibling speciesD. simulans, information regarding the sensitivities of the different forms of ADH to the products of ethanol degradation are of ecological importance. ADH-F, ADH-S, ADH-71k ofD. melanogaster and the ADH ofD. simulans were inhibited by NADH, but the inhibition was relieved by NAD⁺. The order of sensitivity of NADH was ADH-F<ADH-71k, ADH-S<ADH-simulans with ADH-F being about four times less sensitive than theD. melanogaster enzymes and 12 times less sensitive than theD. simulans enzyme. Acetaldehyde inhibited the ethanolto-acetaldehyde activity of the ADHs, but at low acetaldehyde concentrations ethanol and NAD⁺ reduced the inhibition. ADH-71k and ADH-F were more subject to the inhibitory action of acetaldehyde than ADH-S and ADH-simulans, with ADH-71k being seven times more sensitive than ADH-S. The pattern of product inhibition of ADH-71k suggests a rapid equilibrium random mechanism for ethanol oxidation. Thus, although the ADH variants only differ by a few amino acids, these differences exert a far larger impact on their intrinsic properties than previously thought. How differences in product inhibition may be of significance in the evolution of the ADHs is discussed.     

FT-IR study of the Chara corallina cell wall under deformation

Fourier-transform infrared (FT-IR) microspectroscopy was used to investigate both the chemical composition of, and the effects of an applied strain on, the structure of the Chara corallina cell wall. The inner layers of the cell wall are known to have a transverse cellulose orientation with a gradient through the thickness to longitudinal orientation in the older layers. In both the native state and following the removal of various biopolymers by a sequential extraction infrared dichroism was used to examine the orientation of different biopolymers in cell-wall samples subjected to longitudinal strain. In the Chara system, cellulose microfibrils were found to be aligned predominantly transverse to the long axis of the cell and became orientated increasingly transversely as longitudinal strain increased. Simultaneously, the pectic polysaccharide matrix underwent molecular orientation parallel to the direction of strain. Following extraction in CDTA, microfibrils were orientated transversely to the strain direction, and again the degree of transverse orientation increased with increasing strain. However, the pectic polysaccharides of the matrix were not detected in the dichroic difference spectra. After a full sequential extraction, the cellulose microfibrils, now with greatly reduced crystallinity, were detected in a longitudinal direction and they became orientated increasingly parallel to the direction of strain as it increased.     

The distribution of cell wall polymers during antheridium development and spermatogenesis in the Charophycean green alga, Chara corallina

Background and Aims

The production of multicellular gametangia in green plants represents an early evolutionary development that is found today in all land plants and advanced clades of the Charophycean green algae. The processing of cell walls is an integral part of this morphogenesis yet very little is known about cell wall dynamics in early-divergent green plants such as the Charophycean green algae. This study represents a comprehensive analysis of antheridium development and spermatogenesis in the green alga, Chara corallina.

Methods

Microarrays of cell wall components and immunocytochemical methods were employed in order to analyse cell wall macromolecules during antheridium development.

Key Results

Cellulose and pectic homogalacturonan epitopes were detected throughout all cell types of the developing antheridium including the unique cell wall protuberances of the shield cells and the cell walls of sperm cell initials. Arabinogalactan protein epitopes were distributed only in the epidermal shield cell layers and anti-xyloglucan antibody binding was only observed in the capitulum region that initially yields the sperm filaments. During the terminal stage of sperm development, no cell wall polymers recognized by the probes employed were found on the scale-covered sperm cells.

Conclusions

Antheridium development in C. corallina is a rapid event that includes the production of cell walls that contain polymers similar to those found in land plants. While pectic and cellulosic epitopes are ubiquitous in the antheridium, the distribution of arabinogalactan protein and xyloglucan epitopes is restricted to specific zones. Spermatogenesis also includes a major switch in the production of extracellular matrix macromolecules from cell walls to scales, the latter being a primitive extracellular matrix characteristic of green plants.     

The enantiomer pair of 24S- and 24R-hydroxycholesterol differentially alter activity of large-conductance Ca2+-dependent K+ (slo1 BK) channel

24S-hydroxycholesterol (HC) is most abundant oxysterols in the brain, passes through blood brain barrier, and is therefore regarded as an intermediary for brain cholesterol elimination. We reported that large-conductance Ca²⁺- and voltage-activated K⁺ (slo1 BK) channels are suppressed by this oxysterol, which is presumably intercalated into cell membrane to access the outer surface of the channel. Such an outer approach would make it difficult to interact with the inner, ion-conducting part of the channel. The present findings showed that 24R-HC, the racemic counterpart of 24S-HC, also suppressed slo1 BK channel but in a different voltage-dependent manner. There was a difference between the effects of the two enantiomers on activation kinetics but not on deactivation kinetics. It is suggested that the chirality contributes to the efficacy of channel blockers that act from outer lipophilic parts of channels, as with those which act on the inner, ion-permeable surface.     

Surface potentials near the mouth of the large-conductance K+ channel from Chara australis: A new method of testing for diffusion-limited ion flow

The kinetics of single K⁺ channels were derived for patch-clamp recordings of membrane patches excised from cytoplasmic drops from the plant, Chara australis R. Br. Specifically, the tilt effect model of MacKinnon, Latorre and Miller (1989. Biochemistry 28:8092–8099) has been used to measure the electrostatic potential (surface PD) and fixed charge at the entrances of the channel. The surface PD is derived from the difference between the trans-pore potential difference (PD) and that between the two bulk phases. The trans-pore PD is probed using three voltage-dependent properties of the channel. These are (1) the association and dissociation rates of Ca²⁺ binding to the channel, from both the cytoplasmic and vacuolar solutions. These were determined from the mean blocked and unblocked durations of the channel in the presence of either 20 mmol liter^–1 vacuolar or 1 mmol liter^–1 cytoplasmic Ca²⁺; (2) the closing rate of the channel's intrinsic gating process. This was determined from the mean channel open time in the absence of vacuolar Ca²⁺ at membrane PDs more negative than –100 mV; and (3) the effect of Mg²⁺ on channel conductance when added to solutions initially containing 3 mmol liter^–1 KCl.The voltage dependence of properties 1 and 2 shifts along the voltage axis according to the ionic strength of the bathing media, consistent with the presence of negative charge in the channel vestibules. Furthermore, the magnitude of this shift depends on the current in a manner consistent with diffusion-limited ion flow in the channel (i.e., the rate of ion diffusion in the external electrolyte limits the channel conductance). Mg²⁺ on either side of the membrane alters channel conductance in a voltage-dependent way. A novel feature of the Mg²⁺ effect is that it reverses, from a block to an enhancement, when the membrane PD is more negative than –70 mV. This reversal only appears in solutions of low ionic strength. The attenuating effect is due to voltage-dependent binding of Mg²⁺ within the pore, which presumably plugs the channel. The enhancing effect is due to screening by Mg²⁺ of surface potentials arising from diffusion-limited flow of K⁺.     

Studies on Electrogenesis under High K+ Concentrations in Internodal Cells of Chara corallina

+ concentration ([K⁺]_o) on the membrane potential (E_m) of Chara corallina was studied. E_m more negative than -100 mV was maintained even at 100 mM [K⁺]_o. Addition of Ca²⁺ to the external medium further increased this tendency. However, E_m responded sensitively to the increase in [K⁺]_o, when the electrogenic proton pump of the plasma membrane was inhibited by treating cells with dicyclohexylcarbodiimide, an inhibitor of proton pump. Analysis using equivalent circuit model of the plasma membrane suggested that the electrogenic proton pump was activated by the increase in [K⁺]_o. In the presence of 100 mM K⁺, action potentials were generated by electric stimuli. The ionic mechanism of generation of action potentials in the presence of K⁺ at high concentration was discussed. Received 3 October 2000/ Accepted in revised form 6 January 2001     

Reduced transmitter release conferred by mutations in theslowpoke-encoded Ca2+-activated K+ channel gene ofDrosophila

Potassium channels control the repolarization of nerve terminals and thus play important roles in the control of synaptic transmission. Here we describe the effects of mutations in theslowpoke gene, which is the structural gene for a calcium activated potassium channel, on transmitter release at the neuromuscular junction inDrosophila melanogaster. Surprisingly, we find that theslowpoke mutant exhibits reduced transmitter release compared to normal. Similarly, theslowpoke mutation significantly suppresses the increased transmitter release conferred either by a mutation inShaker or by application of 4-aminopyridine, which blocks theShaker-encoded potassium channel at theDrosophila nerve terminal. Furthermore, theslowpoke mutation suppresses the striking increase in transmitter release that occurs following application of 4-aminopyridine to theether a go-go mutant. This suppression is most likely the result of a reduction of Ca²⁺ influx into the nerve terminal in theslowpoke mutant. We hypothesize that the effects of theslowpoke mutation are indirect, perhaps resulting from increased Ca²⁺ channel inactivation, decreased Na⁺ or Ca²⁺ channel localization or gene expression, or by increases in the expression or activity of potassium channels distinct fromslowpoke.     

ATP-regulated K+ channel in mitochondria: Pharmacology and function

Mitochondria from several tissues contain a potassium-specific channel similar to the ATP-regulated K⁺ (K_ATP) channel of the plasma membrane. The mitochondrial channel shares with the plasma membrane K_ATP channel the sensitivity to sulfonylurea derivatives and some other blockers as well as to channel openers of diverse chemical character. In contrast to the plasma membrane channel, which is blocked by free ATP, the mitochondrial K_ATP channel reconstituted into liposomes requires the ATP-Mg complex for inhibition. The mitochondrial K_ATP channel, possibly in a concerted action with other K⁺ permeability pathways, plays an important role in mitochondrial volume control. Its function in the regulation of the components of the protonmotive force is also suggested.     

Coupling between voltage sensor activation,Ca2+ binding and channel opening in large conductance (BK) potassium channels

To determine how intracellular Ca(2+) and membrane voltage regulate the gating of large conductance Ca(2+)-activated K(+) (BK) channels, we examined the steady-state and kinetic properties of mSlo1 ionic and gating currents in the presence and absence of Ca(2+) over a wide range of voltage. The activation of unliganded mSlo1 channels can be accounted for by allosteric coupling between voltage sensor activation and the closed (C) to open (O) conformational change (Horrigan, F.T., and R.W. Aldrich. 1999. J. Gen. Physiol. 114:305-336; Horrigan, F.T., J. Cui, and R.W. Aldrich. 1999. J. Gen. Physiol. 114:277-304). In 0 Ca(2+), the steady-state gating charge-voltage (Q(SS)-V) relationship is shallower and shifted to more negative voltages than the conductance-voltage (G(K)-V) relationship. Calcium alters the relationship between Q-V and G-V, shifting both to more negative voltages such that they almost superimpose in 70 microM Ca(2+). This change reflects a differential effect of Ca(2+) on voltage sensor activation and channel opening. Ca(2+) has only a small effect on the fast component of ON gating current, indicating that Ca(2+) binding has little effect on voltage sensor activation when channels are closed. In contrast, open probability measured at very negative voltages (less than -80 mV) increases more than 1,000-fold in 70 microM Ca(2+), demonstrating that Ca(2+) increases the C-O equilibrium constant under conditions where voltage sensors are not activated. Thus, Ca(2+) binding and voltage sensor activation act almost independently, to enhance channel opening. This dual-allosteric mechanism can reproduce the steady-state behavior of mSlo1 over a wide range of conditions, with the assumption that activation of individual Ca(2+) sensors or voltage sensors additively affect the energy of the C-O transition and that a weak interaction between Ca(2+) sensors and voltage sensors occurs independent of channel opening. By contrast, macroscopic I(K) kinetics indicate that Ca(2+) and voltage dependencies of C-O transition rates are complex, leading us to propose that the C-O conformational change may be described by a complex energy landscape.     

Kinetics of voltage- and Ca2+ activation and Ba2+ blockade of a large-conductance K+ channel fromNecturus enterocytes

Summary Potassium channels in membranes of isolatedNecturus enterocytes were studied using the patch-clamp technique. The most frequent channel observed had a conductance of 170 pS and reversal potential of 0 mV in symmetrical potassium-rich solutions. Channels were highly K⁺ selective. Channel activity was modulated by membrane potential and cytosolic Ca²⁺ concentration. Channel openings occurred in characteristic bursts separated by long closures. During bursts openings were interrupted by brief closures. Two gating modes controlled channel opening. The primary gate's sensitivity to intracellular Ca²⁺ concentration and membrane potential crucially determined long duration closures and bursting. In comparison, the second gate determining brief closures was largely insensitive to voltage and intracellular Ca²⁺ concentration. The channel was reversibly blocked by cytosolic barium exposure in a voltage-sensitive manner. Blockade reduced open-state probability without altering single-channel conductance and could be described, at relatively high Ca²⁺ concentration, by a three-state model where Ba²⁺ interacted with the open channel with a dissociation constant of about 10^–4 m at 0 mV.