Large plasma-membrane depolarization precedes rapid blue-light-induced growth inhibition in cucumber

Blue-light (BL)-induced suppression of elongation of etiolated Cucumis sativus L. hypocotyls began after a 30-s lag time, which was halved by increasing the fluence rate from 10 to 100 mol·m^-2·s^-1. Prior to the growth suppression, the plasma-membrane of the irradiated cells depolarized by as much as 100 mV, then returned within 2–3 min to near its initial value. The potential difference measured with surface electrodes changed with an identical time course but opposite polarity. The lag time for the change in surface potential showed an inverse dependence on fluence rate, similar to the lag for the growth inhibition. Green light and red light caused neither the electrical response nor the rapid inhibition of growth. The depolarization by BL did not propagate to nonirradiated regions and exhibited a refractory period of about 10 min following a BL pulse. Fluenceresponse relationships for the electrical and growth responses provide correlational evidence that the plasma-membrane depolarization reflects an event in the transduction chain of this light-growth response.Abbreviations and symbols BL blue light - V _m membrane potential - V ₈ surface potential     

The electrical changes accompanying fertilization and cortical vesicle secretion in the medaka egg

The electrical properties of the egg of the medaka, Oryzias latipes, were studied before, during, and after fertilization. The resting potential of the unfertilized egg averaged ?39 ± 9 mV in Yamamoto's Ringers (Y. Ringers), but 20% of the values were between ?50 and ?60 mV. Fertilization triggers a small depolarization of 4 ± 3 mV in 10% Y. Ringers with an average duration of 20 ± 10 sec. The amplitude of this depolarization is independent of [Na⁺]_o, [Ca²⁺]_o, and [Cl^?]_o, so it appears to be due to a nonspecific leak triggered by sperm-egg fusion. The depolarization is followed by a longer hyperpolarizing phase with an average amplitude of 31 ± 12 mV. Recovery from this hyperpolarization has a fast phase lasting 155 ± 18 sec, followed by a slower phase which reaches a steady average membrane potential of ?19 ± 1 mV by 9 min after fertilization. The membrane resistance falls 10-fold during the first 2 min after fertilization, from 40 (1520 kΩ-cm²) to 3 MΩ. This is largely due to an increase in the K⁺ conductance. At the peak of the hyperpolarization, the membrane potential exhibits a 28 mV/decade [K⁺]_o dependence and a 6 mV/decade [Na⁺]_o dependence. The membrane resistance slowly recovers over the next 8 min to a value about 30% larger than before fertilization. The relation of current vs voltage was linear before, during, and after fertilization and indicated a reversal potential of ?98 ± 20 mV for the hyperpolarization peak. The egg's capacitance averaged 0.04 ± 0.01 μF (0.9 μF/cm²) before fertilization and approximately doubles within 90 sec after fertilization. It then decreases over a 9-min period, reaching a value 25% smaller than before fertilization.     

Effects of Light on the Membrane Potential of Protoplasts from Samanea saman Pulvini : Involvement of K Channels and the H -ATPase

Rhythmic light-sensitive movements of the leaflets of Samanea saman depend upon ion fluxes across the plasma membrane of extensor and flexor cells in opposing regions of the leaf-movement organ (pulvinus). We have isolated protoplasts from the extensor and flexor regions of S. saman pulvini and have examined the effects of brief 30-second exposures to white, blue, or red light on the relative membrane potential using the fluorescent dye, 3,3′-dipropylthiadicarbocyanine iodide. White and blue light induced transient membrane hyperpolarization of both extensor and flexor protoplasts; red light had no effect. Following white or blue light-induced hyperpolarization, the addition of 200 millimolar K⁺ resulted in a rapid depolarization of extensor, but not of flexor protoplasts. In contrast, addition of K⁺ following red light or in darkness resulted in a rapid depolarization of flexor, but not of extensor protoplasts. In both flexor and extensor protoplasts, depolarization was completely inhibited by tetraethylammonium, implicating channel-mediated movement of K⁺ ions. These results suggest that K⁺ channels are closed in extensor plasma membranes and open in flexor plasma membranes in darkness and that white and blue light, but not red light, close the channels in flexor plasma membranes and open them in extensor plasma membranes. Vanadate treatment inhibited hyperpolarization in response to blue or white light, but did not affect K⁺ -induced depolarization. This suggests that white or blue light-induced hyperpolarization results from activation of the H⁺ -ATPase, but this hyperpolarization is not the sole factor controlling the opening of K⁺ channels.     

Nonsynaptic membrane of retinal horizontal cells as a slow potential amplifier

A simplified model of the membrane of horizontal cells of the L-type is designed to reflect two principal features of these cells previously studied experimentally: 1) their hyperpolarization response to light is the result of a decrease in the EPSP that is kept constant in darkness; 2) the resistance of their nonsynaptic membrane is reduced during hyperpolarization within physiological limits (from 0 to−70 mV). The model also reproduces properties of the horizontal cells such as the low membrane potential in darkness, reversal of the response to light during depolarization beyond the zero level, mutual amplification of color signals, saturation of the response to bright light, steady-state volt-ampere characteristics in darkness and light, and the amplitude characteristic curve which often has a steep part within a certain range of membrane potentials. The presence of hysteresis loops of the volt-ampere and amplitude characteristic curves of the horizontal cells predicted by the model was confirmed experimentally on the fish retina. Analysis of the model and results obtained with it show that the nonsynaptic membrane of the horizontal cells can actively amplify slow graded potentials.     

Electrical characteristics of the apical and basal-lateral membranes in the turtle bladder epithelial cell layer

(1) The active transport of Na⁺ across the turtle bladder epithelial cell layer consists of a passive entry step through a Na⁺-selective path in the apical membrane and an active extrusion step through Na⁺ pump-containing path in the basal-lateral membrane together with some back-leakage through the paracellular spaces and tight junctions between the epithelial cells. This hypothesis has now been verified qualitatively and to some extent, quantitatively by the use of an intracellularly-located microelectrode in conjunction with a conventional assembly of extracellularly-located macroelectrodes mainly in short-circuited bladders bathed by Na⁺-rich Ringer media. Under these conditions, the intracellular potential (V_sc) averaged 38.4 mV with the cell electronegative; the fractional resistance of the apical membrane ($\text{?R}{}_{\mathrm{<mtext>a</mtext>}}$) averaged 0.55; while the concomitant transepithelial parameters, short circuiting current (I_sc) and electrical conductance (G_t), average 68.6 μA/cm² and 0.98 mS/cm², respectively. (2) The relation between these parameters and the transepithelial flow of Na⁺ (orI_sc) is evoked by blocking Na⁺ entry into the cell (by the mucosal addition of amiloride or removal of mucosal Na⁺). Amiloride-induced blockade of the Na⁺ entry step results in a rapid hyperpolarization of the cell interior during which V_sc = —79.1 mV and $\text{?R}{}_{\mathrm{<mtext>a</mtext>}}\text{= 0.92}$. I_sc and G_t (equivalent to the shunt conductance under these conditions) averaged 5 μA/cm² and 0.35 mS/cm², respectively. The entire process is reversible on re-admission of Na⁺ entry into the cell. (3) A slow depolarization of the cell interior in the period of blocked transapical Na⁺ entry is opposite to that expected from an electroneutral Na⁺-K⁺ exchanging pump; but instead is the predictable response of an electrogenic Na⁺ pump in parallel with a passive K⁺-selective conductance in the basal-lateral membrane. (4) The electrogenicity concept is substantiated after pretreatment of the bladder with serosal ouabain, which changes the response of V_sc to amiloride (from the aforementioned biphasic response) to a step-function response, attributable mainly to the development of a slowly dissipating K⁺ diffusion potential across the basallateral membrane. (5) Under open-circuit conditions, the electronegativity of cell to mucosa (V_a) is a linear inverse function of the electropositivity of serosa to mucosa (V_t). For V_t ? 100 mV, V_a is positive; and for V_t between ?30 and 90 mV, V_a is negative.     

The influence of cellular amino acids and the Na+: K+ pump on the membrane potential of the Ehrlich ascites tumor cell

The membrane potential of the Ehrlich ascites tumor cell was shown to be influenced by its amino acid content and the activity of the Na⁺: K⁺ pump. The membrane potential (monitored by the fluorescent dye, 3,3′-dipropylthiodicarbocyanine iodide) varied with the size of the endogenous amino acid pool and with the concentration of accumulated 2-aminoisobutyrate. When cellular amino acid content was high, the cells were hyperpolarized; as the pool declined in size, the cells were depolarized. The hyperpolarization seen with cellular amino acid required cellular Na⁺ but not cellular ATP. Na⁺ efflux was more rapid from cells containing 2-aminoisobutyrate than from cells low in internal amino acids. These observations indicate that the hyperpolarization recorded in cells with high cellular amino acid content resulted from the electrogenic co-efflux of Na⁺ and amino acids.Cellular ATP levels were found to decline rapidly in the presence of the dye and hence the influence of the pump was seen only if glucose was added to the cells. When the cells contained normal Na⁺ (approx. 30 mM), the Na⁺: K⁺ pump was shown to have little effect on the membrane potential (the addition of ouabain had little effect on the potential). When cellular Na⁺ was raised to 60 mM, the activity of the pump changed the membrane potential from the range ?25 to ?30 mV to ?44 to ?63 mV. This hyperpolarization required external K⁺ and was inhibited by ouabain.     

Modulation of the membrane potential of endothelial cells from the guinea pig aorta by intracellular alkalinization

Endothelium-dependent vasoactive substances are known to evoke complex changes in the endothelial membrane potential (MP) and to increase intracellular pH in endothelial cells (EC). In our present study, we investigated the effect of agents able to increase intracellular pH on the MP of intact guinea pig aortic EC, and also the effect of blocking of Na⁺−H⁺ exchanger on ATP-induced electrical responses. Intracellular alkalinization was induced either by addition of ammonium chloride (NH₄Cl) to the superfusate, or by changing the bath solution saturated with 10% CO₂+90% O₂ to a solution saturated with 100% O₂. Both approaches evoked hyperpolarization of EC. After intracellular Ca²⁺ chelation by pretreatment of aortic preparations with 20 μM BAPTA-AM, the amplitude of NH₄Cl-induced hyperpolarization dropped from 3.9±0.6 to 0.7±0.3 mV. After pretreatment with ATP, NH₄Cl-induced hyperpolarization was not abolished, whereas after caffeine pretreatment this hyperpolarization was not observed. In the Na⁺-free solution and in the presence of furosemide, ATP-evoked hyperpolarization became longer. The same effect was also observed in the presence of sodium acetate, which directly acidifies the cytosol. In the Ca²⁺-free solution, furosemide did not induce prolongation of ATP-evoked hyperpolarization. Taking into account the results, it could be proposed that, first, hyperpolarization of EC after intracellular alkalinization is a result of Ca²⁺ release from the intracellular stores sensitive both to an increase in intracellular pH and to caffeine application. Second, intracellular alkalinization, being a result of activation of Na⁺−H⁺-antiporter, inhibits influx of extracellular Ca²⁺ into EC under ATP stimulation.     

The voltage-dependent potassium-uptake channel of corn coleoptiles has permeation properties different from other K+ channels

The initial response of coleoptile cells to growth hormones and light is a rapid change in plasma-membrane polarization. We have isolated protoplasts from the cortex of maize (Zea mays L.) coleoptiles to study the electrical properties of their plasma membrane by the patch-clamp techniqueUsing the whole-cell configuration and cell-free membrane patches we could identify an H⁺-ATPase, hyperpolarizing the membrane potential often more negative than -150 mV, and a voltage-dependent, inward-rectifying K⁺ channel (unit conductance 5–7 pS) as the major membrane conductan-ces Potassium currents through this channel named CKC1_in (for Coleoptile K ⁺ Channel inward rectifier) were elicited upon voltage steps negative to -80 mV, characterized by a half-activation potential of -112 mV. The kinetics of activation, well described by a double-exponential process, were strongly dependent on the degree of hyperpolarization and the cytoplasmic Ca²⁺ level. Whereas at nanomolar Ca²⁺ concentrations K⁺ currents increased with a t_1/2=16 ms (at -180 mV), higher calcium levels slowed the activation process about fourto fivefoldUpon changes in the extracellular K⁺ concentration the reversal potential of the K⁺ channel followed the Nernst potential for potassium with a 56-mV shift for a tenfold increaseThe absence of a measurable conductance for Na⁺, Rb⁺, Cs⁺ and a permeability ratio P_{NH 4} ⁺ /P_K+ around 0.25 underlines the high selectivity of CKC1_in for K⁺In contrast to Cs⁺, which at submillimolar concentration blocks the channel in a voltage-dependent manner, Rb⁺, often used as a tracer for K+, does not permeate this type of K⁺ channelThe lack of Rb⁺ permeability is unique with respect to other K⁺ transporters. Therefore, future molecular analysis of CKC1_in, considered as a unique variation of plant inward rectifiers, might help to understand the permeation properties of K⁺ channels in general.Abbreviations CKC1_in Coleoptile K ⁺ Channel inward rectifier - U membrane voltage - I_ss steady-state currents - I_tail tail currents Experiments were conducted in the laboratory of F.G. during the stay of RHas a guest professor sponsored by Special Project RAISA, subproject N2.1, paper N2155.     

Persistent inward currents in cultured Retzius cells of the medicinal leech

Current-clamp studies of cultured leech Retzius cells revealed inward rectification in the form of slow voltage sags in response to membrane hyperpolarization. Sag responses were eliminated in Na⁺-free saline and blocked by Cs⁺, but not Ba²⁺. Voltage clamp experiments revealed a Cs⁺-sensitive inward current activated by hyperpolarization negative to −70 mV. Cs⁺ decreased the frequency of spontaneous impulses in Retzius cells of intact ganglia. Plateau potentials were evoked in Retzius cells following block of Ca²⁺ influx with Ni²⁺ and suppression of K⁺ currents with internal tetraethylammonium. Plateau potentials continued to be expressed with Li⁺ as the charge carrier, but were eliminated when Na⁺ was replaced with N-methyl-d-glucamine. A persistent Na⁺ current with similar pharmacology that activated positive to −40 mV and reached its peak amplitude near −5 mV was identified in voltage-clamp experiments. Inactivation of the persistent Na⁺ current was slow and incomplete. The current was revealed by slow voltage ramps and persisted for the duration of 5-s voltage steps. Persistent Na⁺ current may underlie Na⁺-dependent bursting recorded in neurons of intact ganglia exposed to Ca²⁺-channel blockers. Accepted: 22 September 1998     

Action potentials in primary osteoblasts and in the MG-63 osteoblast-like cell line

Whole-cell patch-clamp analysis revealed a resting membrane potential of −60 mV in primary osteoblasts and in the MG-63 osteoblast-like cells. Depolarization-induced action potentials were characterized by duration of 60 ms, a minimal peak-to-peak distance of 180 ms, a threshold value of −20 mV and a repolarization between the spikes to −45 mV. Expressed channels were characterized by application of voltage pulses between −150 mV and 90 mV in 10 mV steps, from a holding potential of −40 mV. Voltages below −60 mV induced an inward current. Depolarizing voltages above −30 mV evoked two currents: (a) a fast activated and inactivated inward current at voltages between −30 and 30 mV, and (b) a delayed-activated outward current that was induced by voltages above −30 mV. Electrophysiological and pharmacological parameters indicated that hyperpolarization activated strongly rectifying K⁺ (K_ir) channels, whereas depolarization activated tetrodotoxin sensitive voltage gated Na⁺ (Na_v) channels as well as delayed, slowly activated, non-inactivating, and tetraethylammonium sensitive voltage gated K⁺ (K_v) channels. In addition, RT-PCR showed expression of Na_v1.3, Na_v1.4, Na_v1.5, Na_v1.6, Na_v1.7, and K_ir2.1, K_ir2.3, and K_ir2.4 as well as K_v2.1. We conclude that osteoblasts express channels that allow firing of action potentials.     

The Ionic Permeability Changes during Acetylcholine-Induced Responses of Aplysia Ganglion Cells

ACh-induced depolarization (D response) in D cells markedly decreases as the external Na⁺ is reduced. However, when Na⁺ is completely replaced with Mg⁺⁺, the D response remains unchanged. When Na⁺ is replaced with Tris(hydroxymethyl)aminomethane, the D response completely disappears, except for a slight decrease in membrane resistance. ACh-induced hyperpolarization (H response) in H cells is markedly depressed as the external Cl^- is reduced. Frequently, the reversal of the H response; i.e., depolarization, is observed during perfusion with Cl^--free media. In cells which show both D and H responses superimposed, it was possible to separate these responses from each other by perfusing the cells with either Na⁺-free or Cl^--free Ringer's solution. High [K⁺]₀ often caused a marked hyperpolarization in either D or H cells. This is due to the primary effect of high [K⁺]₀ on the presynaptic inhibitory fibers. The removal of this inhibitory afferent interference by applying Nembutal readily disclosed the predicted K⁺ depolarization. In perfusates containing normal [Na⁺]₀, the effects of Ca⁺⁺ and Mg⁺⁺ on the activities of postsynaptic membrane were minimal, supporting the current theory that the effects of these ions on the synaptic transmission are mainly presynaptic. The possible mechanism of the hyperpolarization produced by simultaneous perfusion with both high [K⁺]₀ and ACh in certain H cells is explained quantitatively under the assumption that ACh induces exclusively an increase in Cl^- permeability of the H membrane.     

Voltage-gated ion conductances corresponding to regenerative positive and negative spikes in the dinoflagellateNoctiluca miliaris

Depolarization-activated and hyperpolarization-activated ion conductances in the membrane of a marine dinoflagellateNoctiluca miliaris were examined under voltage-clamp conditions.Noctiluca exhibited a transient inward current in response to a step depolarization from a holding potential level of –80 mV to a potential level more positive than –50 mV. The I–V relationship for the current exhibited typical N-shaped characteristics similar to those of most excitable membranes. The current was inactivated by a membrane depolarization. The reversal potential of the current shifted in hyperpolarizing direction when the external Na⁺ concentration was lowered. The transient inward current is assumed to be responsible for the Na⁺-dependent positive spike in non-clamped specimens ofNoctiluca.Noctiluca exhibited a transient outward current in response to a step hyperpolarization from a holding potential level of –20 mV to a potential level more negative than –30 mV. The I–V relationship for the current was a typical N-shape as if it was turned 180° around its origin. The outward current showed a two-step exponential time-decay. The outward current was inactivated by a membrane hyperpolarization. The reversal potential shifted in the depolarizing direction when the external Cl^– concentration was lowered. The transient outward current is responsible for the Cl^–-dependent negative spike in non-clamped specimens ofNoctiluca.Abbreviations ASW artificial seawater - TRP tentacle regulating potentials - TTX tetrodotoxin     

Photocontrol of growth pattern in a tissue isolated from the gametophytes of bracken fern

A tissue isolated from the gametophytes of bracken fern, Pteridiumaquilinum grew as unbranched filaments in red or green light,or in complete darkness. Irradiation with blue or white lightled to a shift from filamentous to two-dimensional pattern ofgrowth in the tissue. (Received February 13, 1969; )     

L-type Ca<Superscript>2+</Superscript> channel and Ca<Superscript>2+</Superscript>-permeable nonselective cation channel as a Ca<Superscript>2+</Superscript> conducting pathway in myocytes isolated from the cricket lateral oviduct

The Ca²⁺-conducting pathway of myocytes isolated from the cricket lateral oviduct was investigated by means of the whole-cell patch clamp technique. In voltage-clamp configuration, two types of whole cell inward currents were identified. One was voltage-dependent, initially activated at –40 mV and reaching a maximum at 10 mV with the use of 140 mM Cs²⁺-aspartate in the patch pipette and normal saline in the bath solution. Replacement of the external Ca²⁺ with Ba²⁺ slowed the current decay. Increasing the external Ca²⁺ or Ba²⁺ concentration increased the amplitude of the inward current and the current–voltage (I–V) relationship was shifted as expected from a screening effect on negative surface charges. The inward current could be carried by Na⁺ in the absence of extracellular Ca²⁺. Current carried by Na⁺ (I _Na) was almost completely blocked by the dihydropyridine Ca²⁺ channel antagonist, nifedipine, suggesting that the I _Na is through voltage-dependent L-type Ca²⁺ channels. The other inward current is voltage-independent and its I–V relationship was linear between –100 mV to 0 mV with a slight inward rectification at more hyperpolarizing membrane potentials when 140 mM Cs⁺-aspartate and 140 mM Na⁺-gluconate were used in the patch pipette and in the bath solution, respectively. A similar current was observed even when the external Na⁺ was replaced with an equimolar amount of K⁺ or Cs⁺, or 50 mM Ca²⁺ or Ba²⁺. When the osmolarity of the bath solution was reduced by removing mannitol from the bath solution, the inward current became larger at negative potentials. The I–V relationship for the current evoked by the hypotonic solution also showed a linear relationship between –100 mV to 0 mV. Bath application of Gd³⁺ (10 M) decreased the inward current activated by membrane hyperpolarization. These results clearly indicate that the majority of current activated by a membrane hyperpolarization is through a stretch-activated Ca²⁺-permeable nonselective cation channel (NSCC). Here, for the first time, we have identified voltage-dependent L-type Ca²⁺ channel and stretch-activated Ca²⁺-permeable NSCCs from enzymatically isolated muscle cells of the cricket using the whole-cell patch clamp recording technique.Abbreviations I _Ca Ca²⁺ current - I _Na Na⁺ current - I–V current–voltage - NSCC nonselective cation channel Communicated by G. Heldmaier     

Chlorophyll is not the primary photoreceptor for the stimulation of P-type H+ pump and growth in variegated leaves of Coleus×hybridus

There has been persisting controversy over the role of photosynthesis in the stimulation of the plasma membrane H⁺-ATPase and growth of dicotyledonous leaves by light. To investigate this, we compared the effects of light on growth, H⁺ net efflux and membrane potential (V_m) of strips which contained either only chlorophyll-free (white) mesophyll cells or chlorophyll-containing (green) cells cut from variegated Coleus leaves. White mesophyll cells responded to white, blue and red light with a hyperpolarization of V_m, an acidification of the apoplast and a promotion of growth, all of which began after a lag of 2–7 min. In contrast, green mesophyll cells showed a biphasic light response in which the hyperpolarization and the acidification were preceded by a rapid depolarization of V_m and an alkalinization of the apoplast. Nevertheless, green and white tissues showed comparable growth promotions in response to light. The light response of the leaf mesophyll is a composite of two separate photosystems. The initial depolarization and alkalinization are mediated by photosynthesis and blocked by 3-(3,4-dichlorophenyl)-1,1-dimethylurea. The slower hyperpolarization, acidification and growth response, on the other hand, are clearly in response to light absorption by pigments other than chlorophyll. Received: 11 February 2000 / Accepted: 2 May 2000     

Light Response of a Giant Aplysia Neuron

Illumination of an Aplysia giant neuron evokes a membrane hyperpolarization which is associated with a membrane conductance increase of 15%. The light response is best elicited at 490 nM: the neuron also has an absorption peak at this wavelength. At the resting potential (-50 to -60 mV) illumination evokes an outward current in a voltage-clamped cell. This current reverses sign very close to E_K calculated from direct measurements of internal and external K⁺ activity. Increases in external K⁺ concentration shift the reversal potential of the light-evoked response by the same amount as the change in E_K. Decreases in external Na⁺ or Cl^- do not affect the response. Therefore, the response is attributed to an increase in K⁺ conductance. Pressure injection of Ca²⁺ into this neuron also hyperpolarizes the cell membrane. This effect is also due largely to an increase in K⁺ conductance. The light response after Ca²⁺ injection does not appear to be altered. Pressure injection of EGTA abolished or greatly reduced the light response. The effect was reversible. We suggest that light acts upon a single pigment in this neuron, releasing Ca²⁺ which in turn increases K⁺ conductance, thereby hyperpolarizing the neuronal membrane.     

The electrogenic sodium pump of the frog retinal pigment epithelium

Summary It was previously shown that ouabain decreases the potential difference across anin vitro preparation of bullfrog retinal pigment epithelium (RPE) when applied to the apical, but not the basal, membrane and that the net basal-to-apical Na⁺ transport is also inhibited by apical ouabain. This suggested the presence of a Na⁺–K⁺ pump on the apical membrane of the RPE. In the present experiments, intracellular recordings from RPE cells show that this pump is electrogenic and contributes approximately –10 mV to the apical membrane potential (V _AP). Apical ouabain depolarizedV _AP in two phases. The initial, fast phase was due to the removal of the direct, electrogenic component. In the first one minute of the response to ouabain,V _AP depolarized at an average rate of 4.4±0.42 mV/min (n=10, mean ±sem), andV _AP depolarized an average of 9.6±0.5 mV during the entire fast phase. A slow phase of membrane depolarization, due to ionic gradients running down across both membranes, continued for hours at a much slower rate, 0.4 mV/min. Using a simple diffusion model and K⁺-specific microelectrodes, it was possible to infer that the onset of the ouabain-induced depolarization coincided with the arrival of ouabain molecules at the apical membrane. This result must occur if ouabain affects an electrogenic pump. Other metabolic inhibitors, such as DNP and cold, also produced a fast depolarization of the apical membrane. For a decrease in temperature of 10°C, the average depolarization of the apical membrane was 7.1±3.4 mV (n=5) and the average decrease in transepithelial potential was 3.9±0.3 mV (n=10). These changes in potential were much larger than could be explained by the effect of temperature on anRT/F electrodiffusion factor. Cooling the tissue inhibited the same mechanism as ouabain, since prior exposure to ouabain greatly reduced the magnitude of the cold effect. Bathing the tissue in 0mm [K⁺] solution for 2 hr inhibited the electrogenic pump, and subsequent re-introduction of 2mm [K⁺] solution produced a rapid membrane hyperpolarization. We conclude that the electrogenic nature of this pump is important to retinal function, since its contribution to the apical membrane potential is likely to affect the transport of ions, metabolites, and fluid across the RPE.     

Evidence for coupled transport of bicarbonate and sodium in cultured bovine corneal endothelial cells

Summary Usin gintracellular microelectrode technique, the response of the voltageV across the plasma membrane of cultured bovine corneal endothelial cells to changes in sodium and bicarbonate concentrations was investigated. (1) The electrical response to changes in [HCO ₃ ^– ] _o (depolarization upon lowering and hyperpolarization upon raising [HCO ₃ ^– ] _o ) was dependent on sodium. Lithium could fairly well be substituted for sodium, whereas potassium or choline were much less effective. (2) Removal of external sodium caused a depolarization, while a readdition led to a hyperpolarization, which increased with time of preincubation in the sodium-depleted medium. (3) The response to changes in [Na⁺] _o was dependent on bicarbonate. In a nominally bicarbonate-free medium, its amplitude was decreased or even reversed in sign. (4) Application of SITS or DIDS (10^–3 m) had a similar effect on the response to sodium as bicarbonate-depleted medium. (5) At [Na⁺] _o =151mm and [HCO ₃ ^– ] _o =46mm, the transients ofV depended, with 39.0±9.0 (sd) mV/decade, on bicarbonate and, with 15.3±5.8 (sd) mV/decade, on sodium. (6) After the preincubation of cells with lithium, replacement of Li by choline led to similar effects as the replacement of sodium by choline, though the response ofV was smaller with Li. This response could be reduced or reversed by the removal of bicarbonate or by the application of SITS. (7) Amiloride (10^–3 m) caused a reversible hyperpolarization of the steady-state potential by 8.5±2.6 mV (sd). It did not affect the immediate response to changes in [Na⁺] _o or [HCO ₃ ^– ] _o , but reduced the speed of regaining the steady-state potential after a change in [HCO ₃ ^– ] _o . (8) Ouabain (10^–4 m) caused a fast depolarization of –6.8±1.1 (sd) mV, which was followed by a continuing slower depolarization. The effect was almost identical at 10^–5 m. (9) It is suggested, that corneal endothelial cells possess a cotransport for sodium and bicarbonate, which transports net negative charage with these ions. It is inhibitable by stilbenes, but not directly affected by amiloride or ouabain. Lithium is a good substitute for sodium with respect to bicarbonate transport and is transported itself. In addition, the effect of amiloride provides indirect evidence for the existence of a Na⁺/H⁺-antiport. A model for the transepithelial transport of bicarbonate across the corneal endothelium is proposed.     

Membrane conductances of principal cells in Malpighian tubules of Aedes aegypti

Two-electrode voltage clamp (TEVC) methods were used to explore conductive transport pathways in principal cells, the dominant cell type in Malpighian tubules of the yellow fever mosquito. The basolateral membrane of principal cells had a voltage (V_bl) of -85.1 mV in 49 principal cells under control conditions. Measures of the input resistance R_pc together with membrane fractional resistance yielded estimates of the conductance of the basolateral membrane (g_bl = 1.48 μS) and the apical membrane (g_a = 3.13 μS). K⁺ channels blocked by barium accounted for 0.94 μS of g_bl. Estimates of transference numbers yielded the basolateral membrane Na⁺ conductance of 0.24 μS, leaving 0.30 μS (20%) of g_bl unaccounted. The secretagogue db-cAMP (0.1 mM), a known activator of the basolateral membrane Na⁺ conductance, significantly depolarized V_bl to -65.0 mV and significantly increased g_bl from 1.48 μS to 2.47 μS. The increase was blocked with amiloride (1 mM), a known blocker of epithelial Na⁺ transport. The inhibition of metabolism with di-nitrophenol significantly depolarized V_bl to -9.7 mV and significantly increased R_pc from 391.6 kΩ to 2612.5 kΩ. Similar results were obtained with cyanide, but it remains unclear whether the large increases in R_pc stem from the uncoupling of epithelial cells and/or the shutdown of conductive transport pathways in basolateral and apical membranes. Our results indicate that the apical membrane of principal cells is more than twice as conductive as the basolateral membrane. Partial ionic conductances suggest the rate-limiting step for transepithelial Na⁺ secretion at the basolateral membrane.     

A Nonselective High Conductance Channel in Bovine Pigmented Ciliary Epithelial Cells

An ion channel activated by hyperpolarization was identified in excised patches of bovine pigmented ciliary epithelial cells using the single channel patch clamp technique. In symmetrical NaGluconate, the channel had a maximum conductance of 285 pS. The channel was characterized by frequent flickery transitions between the fully open and closed levels. The channel did not discriminate very clearly between anions and cations; when the cytoplasmic face of excised patches was bathed in a dilute NaCl solution, the channel had a chloride-to-sodium permeability ratio (P _Cl/P _Na) of 1.3. However, the channel showed a small anion selectivity (P _Cl/P _Na= 3.7) when bathed in a concentrated NaCl solution. Gd³⁺ blocked the channel reversibly. Channel kinetics were characterised by slow (≈ min) voltage-dependent activation and inactivation rate constants. The channel was most active in the range −60 to −140 mV and showed a peak at −120 mV. A similar time- and voltage-dependent activation was also observed in cell-attached recordings. In conclusion, hyperpolarization of pigmented ciliary epithelial cell membrane patches activated a large conductance, nonselective ion channel. This combination of nonselectivity and hyperpolarizing activation is consistent with the involvement of this channel in ion loading from the blood into pigmented ciliary epithelial cells—the first phase in the secretion of aqueous humor. Received: 30 June 1995/Revised: 16 November 1995