Reversible inhibition of cytoplasmic streaming by intracellular Ca2+ in tonoplast-free cells ofChara australis

Summary The effect of the intracellular concentration of Ca²⁺ on the cytoplasmic streaming of tonoplast-free cells ofChara australis was studied by intracellular perfusion. The perfusion media contained 1 mM Mg · ATP. Both cell ends were cut and left open. Media of different Ca²⁺ concentrations were perfused through the cell and the rate of the cytoplasmic streaming just after perfusion was measured. The critical concentration of Ca²⁺ for inhibiting the streaming was 5 × 10^–4M, which was substantially higher than that found earlier byWilliamson (1975) andHayama et al. (1979). Recovery from the inhibition occurred, though not completely, by removing Ca²⁺.In tonoplast-free cells the Ca²⁺ sensitivity differed according to the culture conditions. Cells cultured indoors exhibited a higher sensitivity than those cultured outdoors. Theformer cells contained granule-rich endoplasm aggregates after loss of the tonoplast, while the latter cells did no such aggregates. The aggregates were fixed to the cortical gel with a high dosage of Ca²⁺ and freed by removing it.     

A kinetic analysis of the electrogenic pump ofChara corallina: III. Pump activity during action potential

Summary The current-voltage curve (I–V curve) of theChara membrane was obtained by applying a slow ramp hyper- and depolarization by use of voltage clamp. By inhibiting the electrogenic pump with 50m DCCD (dicyclohexylcarbodiimide), theI–V curve approached a steadyI–V curve within two hours, which gave thei _d -V curve of the passive diffusion channel. Thei _p -V curve of the electrogenic pump channel was obtained by subtracting the latter from the former. The sigmoidali _p -V curve could be simulated satisfactorily with a simple reaction kinetic model which assumes a stoichiometric ratio of 2. The emf of the pump (E _p ) is given as the voltage at which the pump current changes its sign. The conductance of the pump (g _p ) can be calculated as the chord conductance from thei _p -V curve, which is highly voltage dependent having a peak at a definite voltage. The changes of emf and conductance during excitation were determined by use of the current clamp (I=0). Since theE _p andg _p (V) are known, the changes, during excitation, of emf (E _d ) and conductance (g _d ) of the passive diffusion channel can be calculated. The marked increase of the membrane conductance and the large depolarization during the action potential are caused by the marked increase of the conductance of the passive diffusion channel and the large depolarization of its emf. The conductance of the electrogenic pump decreases to about half at the peak of action potential, while the pump current increases almost to a saturated level.     

Stretch-induced excitation and action potential changes of single cardiac cells

Mechanoelectric coupling (MEC) has been studied extensively in the heart at the tissue and organ levels, but to only a limited extent in single cells because of the technical challenges. New results are presented in which MEC was studied in 57 single frog ventricular myocytes that were held on both ends by glass holding pipettes. Axial stretch was applied either by displacement of the pipettes, or by a glass fiber around which the cell was wrapped, that was displaced in a pulsatile or sinusoidal fashion. Electrical activity of the cell was monitored either by active contraction, by intracellular action potentials, or by focal extracellular potentials. Of more than 350 stretches applied to 57 cells with amplitudes ranging from 3% to 35%, only 4 cases of mechanically induced stimulation were observed. In 252 stretches applied to 32 cells in which action potential duration (APD) was measured, no change >20% was observed, except in 3 cells in which APD increased by >100%, and in 2 cells with extended triggered activity. Thus, in contrast to studies in intact tissue, single frog ventricular myocytes are generally insensitive to direct axial stretch. However, robust mechanosensitive responses were observed in 7 of 57 (12%) cells. The results of other single cell studies are reviewed, and the significance of differences in tissue-level and single cell results is discussed.     

Sodium and potassium currents recorded during an action potential

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

Control of membrane potential and excitability ofChara cells with ATP and Mg2+

Summmary Electric characteristics of internodalChara australis cells, from which the tonoplast had been removed by vacuolar perfusion with media containing EGTA, were studied in relation to intracellular concentrations of ATP and Mg²⁺ using the ordinary microelectrode method and the open-vacuole method developed by Tazawa, Kikuyama and Nakagawa (1975.Plant Cell Physiol. 16:611). The concentration of ATP was decreased by introducing hexokinase and glucose into the cell and that of Mg²⁺ by introducing EDTA or CyDTA. The membrane potential decrease and the membrane resistance increase were both significant when the ATP or Mg²⁺ concentration was decreased. An ATP-dependent membrane potential was also found in other species of Characeae,Nitella axillaris andN. pulchella. Excitability of the membrane was also completely lost by reducing the ATP or Mg²⁺ concentration. Both membrane potential and excitability were recovered by introducing ATP or Mg²⁺ into ATP- or Mg²⁺-depleted cells.The time course of membrane potential recovery was followed by the open-vacuole method. Recovery began as soon as intracellular perfusion with medium containing ATP and Mg²⁺ was started. Reversible transition of the membrane potential between polarized and pepolarized levels by controlling the intracellular concentration of ATP or Mg²⁺ could be repeated many times by the open-vacuole method, when the excitability was suppressed by addition of Pb²⁺ to the external medium.The ineffectiveness of an ATP analog, AMP-PNP, and the synergism of ATP and Mg²⁺ in maintaining the membrane potential and excitability strongly suggest that ATP act via its hydrolysis by Mg²⁺-activated ATPase. The passive nature of the membrane, as judged from responses of the membrane potential to changes of the external K⁺ concentration, was not altered by lowering the ATP concentration in the cell. The mechanism of membrane potential generation dependent on ATP is discussed on the basic of an electrogenic ion pump. Involvement of the membrane potential generated by the ion pump in the action potential is also discussed.     

Depth-resolved measurement of transient structural changes during action potential propagation

We report noncontact optical measurement of fast transient structural changes in the crustacean nerve during action potential propagation without the need for exogenous chemicals or reflection coatings. The technique, spectral domain optical coherence tomography, provides real-time cross-sectional images of the nerve with micron-scale resolution to select a specific region for functional assessment and interferometric phase sensitivity for subnanometer-scale motion detection. Noncontact optical measurements demonstrate nanometer-scale transient movement on a 1-ms timescale associated with action potential propagation in crayfish and lobster nerves.     

Volume changes during enzyme reactions. The influence of pressure on the action of invertase, dextranase and dextransucrase.

The pressure dependence of the maximum velocities and the Michaelis constants for the enzymes invertase and dextranase was measured up to 1400 bar. The corresponding activation volumes deltaV not equal to c and deltaV not equal to Km proved to be independent of pressure. Together with data from other sources the meaning of deltaV not equal to c and deltaV not equal to Km is established and the volume profiles of the reactions are constructed. These profiles are similar in contour to the volume profile of the dextran formation catalyzed by the enzyme dextransucrase, but the amount of the volume changes is very much larger for dextransucrase. The evaluation of salt effects shows, that for all three enzymes solvent interactions are not important in explaining the results. The reaction mechanisms seem to be governed by conformation changes of the enzymes. The larger effects in dextransucrase are explained by the produced dextran chain remaining tightly bound to the enzyme and being transported relative to the enzymes position in each reaction cycle.     

Recording of single K+ channels in the membrane of cytoplasmic drop ofChara australis

Summary The cytoplasmic drop formed of effused cytoplasm fromChara internodes is enclosed by a membrane. Patch clamp experiments have been carried out on this membrane, revealing a K⁺ channel as the most frequently detected ion translocator. The K⁺ channel is saturated at a level of about 20 pA inward and 10 pA outward current. The channel conductance is dependent on the accessability of K⁺ ions, its maximum value amounts to about 165 pS. The discrimination of Na⁺ and Cl^– is significant, permeability ratios P_Na/P_K and P_Cl/P_K were estimated to be 0.01 either. Binding experiments with the fluorescent probe concanavalin A/FITC suggest that the membrane is derived from the tonoplast.Abbreviations E_K K⁺ equilibrium potential - FITC fluorescein isothiocyanat - V_m membrane voltage - V_pip pipette clamp voltage - V_r reversal voltage     

Volume changes during mitosis in pancreatic acinar cells of the rat

The volume of interphasic and mitotic pancreatic acinar cells of 20-day-old rats was estimated by analysis of drawings from Araldite-embedded serial thick sections. Assuming the average interphase cell volume to be 100%, the volume of prophase cells was 145%, reaching a volume of 180% during anaphase. Postmitotic acinar cell volume was 74%.     

Rate-dependent action potential changes in rat atrium

Experiments in isolated left atria from rat hearts were performed in order to study the effects of stimulation rate on the transmembrane action potential. 1. Two components (fast and slow) of the action potential upstroke could be differentiated by adding MnCl2 to the perfusion solution. 2. With the increase in rate of stimulation over the control cycle length (500 msec), amplitude, Vmax and action potential duration at 80% of repolarization (D80) diminished in normal Krebs. In Mn-containing Krebs, only a slight reduction in amplitude was recorded. Resting potential and action potential duration at 20% (D20) and 50% (D50) of repolarization were only slightly affected in normal Krebs and not at all in Mn-Krebs. 3. Low rates of stimulation in normal Krebs increased D50 only slightly; however, D80 increased significantly while other parameters remained constant. No effects were seen in Mn-Krebs. 4. The results with Mn-Krebs indicate the importance of slow inward current on changes induced by stimulation rates. A possible mechanism relating intracellular calcium concentration and the outward K current, depending on the rate of stimulation, is discussed.     

Rapid changes in the regulatory potential of autologous anti-idiotopic T cells during an antigen-driven primary response

The antibody response of C57BL/6 strain mice to Streptococcus pneumoniae R36a (Pn) is dominated by the T15 idiotype, but the responding cells appear to be idiotypically heterogeneous, in that individual antibody plaque-forming cells (PFC) may express some but not all idiotopes (Id) of the T15 complex. The presence of these distinct Id on the PFC was detected by a plaque-inhibition assay with three different monoclonal anti-Id antibodies, designated AB1-2, MaId5-4, and B36-82. A periodic change in the expression of AB1-2 and MaId5-4 Id was observed during primary (IgM) antibody response to Pn in the spleen. Those two Id were poorly expressed in the log phase of the response between day 2 and day 4 after immunization (few PFC in the spleen bore the Id), but they became detectable on the majority of PFC at the peak of the response, day 5 to day 7. The proportion of the Id-(AB1-2 or MaId5-4) positive PFC declined, again at day 10 after immunization. In contrast, the B36-82 Id was expressed on greater than or equal to 80% PFC throughout the entire primary response. The possibility that the apparent changes in the Pn-reactive cell populations are regulated by autologous anti-Id T cells was tested in vitro. Normal, unimmunized B cells were cultured with Pn, either alone or in the presence of syngeneic T cells isolated from the spleen of mice at the appropriate intervals after immunization: day 2 (T2), day 5 (T5), and days 10 to 14 (T10 to T14); T cells from unimmunized donors (T0) served as a control. The specific response after 4 days in culture was determined in regard to the total PFC as well as the proportion of PFC expressing the Id. Pn-stimulated B cells, alone or with the control T0 cells, produced moderate, variable levels of AB1-2+ and MaId5-4+ PFC. The expression of these two Id in the assay cultures was suppressed by addition of either T2 cells or T10-14 cells, but it was enhanced if T5 cells were added. However, these various T cell populations did not differ in their effect on the total PFC response. Also, the proportion of PFC bearing the third Id, B36-82 was high, and it was not consistently influenced by the added T cells.(ABSTRACT TRUNCATED AT 400 WORDS)     

Radio-frequency rectification in electrogenic and nonelectrogenic cells ofChara andNitella

Summary Electrogenic cells ofChara braunii andNitella flexilis were placed in a pulse-modulated radio-frequency electric field of up to 6000 V/m. Their vacuolar resting potentials were found to experience submillivoltdepolarizing offsets (typically 140 V at 250 kHz) which were relatively indepencent of temperature, increased linearly with resting potential from a zero near –210mV, and had a cutoff (putatively due to ion transit times) near 5 MHz. By contrast, nonelectrogenic cells experiencedhyperpolarizing offsets (typically 1100 V at 250 kHz) which increased in magnitude with increasing temperature, were independent of resting potential, and had a transit time cutoff near 10 MHz.The ionic mobilities inferred from these cutoff frequencies are somewhat higher than would be expected for active transport and presumably reflect passive conductance mechanisms which therefore must be presumed different for the electrogenic and nonelectrogenic states.     

Measurements of calcium transients in ventricular cells during discontinuous action potential conduction

The L-type calcium current (I(Ca)) is important in sustaining propagation during discontinuous conduction. In addition, I(Ca) is altered during discontinuous conduction, which may result in changes in the intracellular calcium transient. To study this, we have combined the ability to monitor intracellular calcium concentration ([Ca(2+)](i)) in an isolated cardiac cell using confocal scanning laser fluorescence microscopy with our "coupling clamp" technique, which allows action potential propagation from the real cell to a real-time simulation of a model cell. Coupling a real cell to a model cell with a value of coupling conductance (G(C) = 8 nS) just above the critical value for action potential propagation results in both an increased amplitude and an increased rate of rise of the calcium transient. Similar but smaller changes in the calcium transient are caused by increasing G(C) to 20 nS. The increase of [Ca(2+)](i) by discontinuous conduction is less than the increase of I(Ca), which may indicate that much of [Ca(2+)](i) is the result of calcium released from the sarcoplasmic reticulum rather than the integration of I(Ca).     

Simultaneous recording of potassium and chloride effluxes during an action potential in Chara corallina

The potassium and chloride effluxes from cells of Chara duringan action potential were recorded simultaneously using a flamephotometer and a perfusion system. Both potassium and chlorideeffluxes increased instantaneously with the action potential.The net potassium and chloride effluxes during an action potentialaveraged 1777 and 1812 picomoles/cm²-impulse, respectively. (Received May 31, 1976; )     

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.     

Reversible changes of extracellular pH during action potential generation in a higher plant Cucurbita pepo

A pH-sensitive electrode was applied to measure activity of H⁺ ions in the medium surrounding excitable cells of pumpkin (Cucurbita pepo L.) seedlings during cooling-induced generation of action potential (AP). Reversible alkalization shifts were found to occur synchronously with AP, which could be due to the influx of H⁺ ions from external medium into excitable cells. Ethacrynic acid (an anion channel blocker) reduced the AP amplitude but had no effect on the transient alkalization of the medium. An inhibitor of plasma membrane H⁺-ATPase, N,N’-dicyclohexylcarbodiimide suppressed both the AP amplitude and the extent of alkalization. In experiments with plasma membrane vesicles, the hydrolytic H⁺-ATPase activity was subjected to inhibition by Ca²⁺ concentrations in the range characteristic of cytosolic changes during AP generation. The addition of a calcium channel blocker verapamil and a chelating agent EGTA to inhibit Ca²⁺ influx from the medium eliminated the AP spike and diminished reversible alkalization of the external solution. An inhibitor of protein kinase, H-7 alleviated the inhibitory effect of Ca²⁺ on hydrolytic H⁺-ATPase activity in plasma membrane vesicles and suppressed the reversible alkalization of the medium during AP generation. The results provide evidence that the depolarization phase of AP is associated not only with activation of chloride channels and Cl^? efflux but also with temporary suppression of plasma membrane H⁺-ATPase manifested as H⁺ influx. The Ca²⁺-induced inhibition of the plasma membrane H⁺-ATPase is supposedly mediated by protein kinases.     

Chloride ion efflux during an action potential in the main pulvinus ofMimosa pudica

The shortening, action potential and Cl⁻-efflux of the excised lower half cortex in the main pulvinus ofMimosa pudica were simultaneously recorded. The mean values±(S.E.) for Cl⁻-efflux and shortening were 183±18 picomoles/mg fresh weight/impulse and 87.0±2.2 μm, respectively.