Intracellular sodium activity and the sodium pump in snail neurones

Properties of a facilitating calcium current in pace-maker neurones of the snail, Helix pomatia

1. Simultaneous measurements of local voltage clamp currents from patches of soma membrane and K activity at the soma surface were used to analyse the time and voltage dependence of the slow inward current in bursting pace-maker neurones of the snail (Helix pomatia). 2. At low levels of depolarization (less than or equal to mV) a net inward current is recorded simultaneously with an efflux of K ions from the cell. 3. With larger depolarizations (20-170 mV from holding potential of -50 mV) the deficit in net outward charge transfer compared with K efflux and the appearance of inward-going tail currents following repolarization, reveal a persistent inward-going current also under these conditions. This inward current is carried primarily by Ca ions, as demonstrated by its voltage dependence (a minimum at about + 115 mV) and its disappearance in Co-Ringer. It is identified with the slow inward Ca current Iin slow (Eckert & Lux, 1976). 4. The inward current predicted from comparisons of current trajectories reaches a maximum at 15-20 msec (for depolarizations from -50 to 0 mV) and gradually declines with sustained depolarization. 5. Partial inactivation is removed by repolarization to -50 mV and the Ca dependent deficit is greater in the sum of repeated voltage clamp pulses than during sustained depolarization. It is largest for pulses of 25-100 msec duration, decreasing as pulse duration increases. 6. Responses to repeated activation with 100 msec pulses with different repolarization intervals reveal a minimum Iin slow at short intervals (e.g. 20 msec) due to failure to remove partial inactivation. At intermediate intervals (e.g. 200-400 msec) Iin slow shows facilitation. This is revealed in calculations of the net charge transfer and current deficits and is also shown in the tail currents following repolarization. The deficit increases progressively with repetitive stimulation. With longer intervals (e.g. 800-1000 msec) defacilitation during repeated stimulation after the first two pulses is revealed in calculations of deficits, current trajectories and in the tail currents. 7. Although facilitation depends on duration of repolarization between pulses, increasing intermediate hyperpolarizations from the holding potential of -50 mV are usually ineffective in increasing Iin slow. Strong preceding hyperpolarization can even decrease the magnitude of Iin slow and prevent its facilitation with repetitive stimulation,whereas preceding depolarizing pulses can increase Iin slow without preventing its facilitation with repetitive stimulation. 8. The properties of Iin slow are contrasted with previously described membrane conductances and compared with properties attributed to Ca fluxes in other systems.

The epidural sieve and MBC (minimal blocking concentration): an hypothesis

Certain painful stimuli-of which those associated with placental abruptio and impending rupture of a uterine scar are examples-can penetrate an apparently well-established lumbar epidural block. As a possible explantation of this anomaly, it is suggested that, when used in the concentrations currently employed, the local anaesthetic reaches nerve axons only slightly above the minimal blocking concentration (MBC) of the drug, and that a more powerful stimulus can provoke an impulse which may be conducted through the "blocked" segment of axon. The beneficial aspects of the "epidural sieve" should be welcomed and no attempt made to eliminate the phenomenon.

Induction of mitosis in mature neurons in central nervous system by sustained depolarization

DNA synthesis and mitosis have been induced in vitro in fully differentiated neurons from the central nervous system by depolarization with a variety of agents that produce a sustained rise in the intracellular sodium ion concentration and a decrease in the potassium ion concentration. Depolarization was followed in less than 1 hour by an increase in RNA synthesis and in 3 hours by initiation of DNA synthesis. Apparently normal nuclear mitosis ensued, but cytokinesis was not completed in most cells; this resulted in the formation of binucleate neurons. The daughter nuclei each contained the same amount of DNA as the diploid preinduction parental neurons; this implies that true mitogenic replication was induced.

Influence of changes in external potassium and chloride ions on membrane potential and intracellular potassium ion activity in rabbit ventricular muscle

1. The membrane responses of rabbit papillary muscles to rapid changes in [K](o) and [Cl](o) were measured with open-tipped micropipettes and with closed micropipettes made from K-selective glass.2. The muscle cells behaved primarily as a K electrode, and responses to changes in [K](o) with constant [Cl](o) or with constant [K](o) x [Cl](o) were substantially the same.3. When [Cl](o) was changed at a constant [K](o) the membrane potentials changed rapidly and symmetrically by a small value and remained constant for 30 min.4. Measurement of potential with K(+)-selective micro-electrodes in these experiments showed no change in intracellular K activity. In addition to permitting calculation of K permeability, these measurements reassured us that the K(+)-selective electrodes were well insulated and not influenced by electrical shunts at the impalement site.5. Although the membrane response to changes in [Cl](o) was small, it was possible to calculate that the permeability ratio (P(Cl)/P(K)), was 0.11. The Cl and K conductances were about 0.015 mmho/cm(2) and 0.09 mmho/cm(2) respectively, resulting in a conductance ratio (g(Cl)/g(K)) of about 0.17.6. The time course of depolarization by increase in [K](o) was rapid (half-time 5 sec), but repolarization on return to lower [K](o) was much slower (half-time 50 sec). The depolarization time course was easily fitted by the potential change calculated by assuming the need for K diffusion into the extracellular spaces and taking account of the logarithmic relation between membrane potential and [K](o). These calculations did not fit the time course of repolarization, which was slowed in the fashion expected from an inward-rectifying membrane.7. The influence of [K](i) on membrane potential was investigated by changes in tonicity of the external solution. Hypotonic solution produced a change in intracellular K activity close to that produced by ideal water movement. However, in hypertonic solution, intracellular K activity did not rise as much as predicted, suggesting a change in intracellular activity coefficient.

Further studies of the potential-dependence of the sodium-induced membrane current in snail neurones

1. The potential-dependence of the membrane current induced by intracellular injections of sodium ions was studied on giant neurones of the snail Helix pomatia. This current decreases with membrane hyperpolarization at room temperature and can be reversed at sufficiently negative holding potentials. The same injections at 7 degrees C, as well as injections of lithium or potassium ions do not induce membrane currents and do not increase membrane conductance. 2. An increase in the amount of injected sodium changes the potential-dependence of the induced membrane currents. Small injections (about 1 muC) induce a current that does not depend upon the membrane potential. Further increase in the injection size not only increases the induced current but also enhances its potential-dependence and often reveals the existence of a reversal potential. The latter reaches -60 to -65 mV with large sodium injections. 3. An increase in extracellular potassium concentration from 4 to 8 mM shifts the reversal potential 17 mV in the depolarizing direction, and a decrease from 4 to 2 mM shifts it 14 mV in the hyperpolarizing direction. Replacement of potassium by rubidium or elimination of sodium ions from the outside solution, does not affect the induced current or its potential-dependence. 4. The coefficient of electrogenicity (the ratio between the amount of charge transferred by the sodium-induced membrane current and the amount brought into the cell during the injection) increases with an increase in the injection size if the membrane potential is clamped near the resting potential level. This relation is reversed when the holding potential is -80 mV. The reversal takes place at holding potentials near -60 mV. 5. 10 mM TEA does not affect the induced current and its potential-dependence. 6. It is suggested that the potential-dependence of the sodium-induced membrane current is a result of a specific increase in the membrane potassium conductance that is coupled with high activity of the sodium pump.

Post-tetanic hyperpolarization, sodium-potassium-activated adenosine triphosphatase and high energy phosphate levels in garfish olfactory nerve

1. While much is now known about the Na-K-ATPase and the posttetanic hyperpolarization of nervous tissue, they have yet to be studied together in the same preparation. 2. The post-tetanic hyperpolarization was studied in desheathed garfish olfactory nerve. The rate constant of decay of the post-tetanic hyperpolarization was determined by monitoring difference potentials after stimulation at 1/sec for 2-3 min. 3. In membrane fractions prepared from these nerves, the ouabain-sensitive ATPase activity (Na-K-ATPase) was determined by spectrophotometric measurements. 4. Both the post-tetanic hyperpolarization and the Na-K-ATPase showed a similar sigmoidal dependence on K+ concentration. The sequence of cation specificities measured at the K-site of the enzyme was the same as that determined by post-tetanic hyperpolarization measurements in whole nerve. 5. The rate constants of the enzyme showed a dependence on Na+ concentration that paralleled the way in which the post-tetanic hyperpolarization rate constants varied as a function of the number of impulses. When Na+ was completely replaced by Li+, neither enzyme activity nor post-tetanic hyperpolarization could be measured. 6. The pH optimum for enzyme activity was between pH 7-0 and 7-8, while the optimal pH for post-tetanic hyperpolarization was above pH 8-0. 7. Metabolite levels in preparations of this nerve studied in vitro correspond to levels found in vivo. 8. High energy phosphate levels were measured fluorometrically in extracts of nerve samples that had been stimulated in air at 1/sec for various intervals. 9. During the first 2 min of stimulation, there was a significant accumulation of inorganic phosphate, and the ATP/ADP.Pi ratio dropped appreciably. 10. The accumulation of ATPase products was commensurate with the approach of post-tetanic hyperpolarization rate constants to their maximum level. This provides direct evidence for an ATPase functioning in active Na+ transport in nerve. 11. The garfish Na-K-ATPase is sensitive to the ATP/ADP ratio of the incubating medium, but is relatively insensitive to orthophosphate, Pi. The fall in post-tetanic hyperpolarization rate constants observed with continued nerve stimulation may have been partially due to the falling ATP/ADP ratio measured in nerve under similar conditions.

The effect of carbon dioxide on the intracellular pH and buffering power of snail neurones

1. Intracellular pH (pHi) was measured using pH-sensitive glass micro-electrodes. The effects on pHi of CO2 applied externally and HCO3-, H+ and NH4+ injected iontophoretically, were investigated. 2. The transport numbers for iontophoretic injection into aqueous micro-droples were found by potentiometric titration to be 0-3 for HCO3- and 0-94 for H+. 3. Exposure to Ringer, pH 7-5, equilibrated with 2-2% CO2 caused a rapid, but only transient, fall in pHi. Within 1 or 2 min pHi began to return exponentially to normal, with a time constant of about 5 min. 4. When external CO2 was removed, pHi rapidly increased, and then slowly returned to normal. The pHi changes with CO2 application or removal gave a calculated intracellular buffer value of about 30 m-equiv H+/pH unit per litre. 5. Injection of HCO3- caused a rise in pHi very similar to that seen on removal of external CO2. 6. The pHi responses to CO2 application, CO2 removal and HCO3- injection were slowed by the carbonic anhydrase inhibitor acetazolamide. 7. H+ injection caused a transient fall in pHi. In CO2 Ringer pHi fell less and recovered faster than in CO2-free Ringer. Calculation of the internal buffer value from the pHi responses to H+ and HCO3- injection gave very similar values. 8. The internal buffer value (measured by H+ injection) was greatly increased by exposure to CO2 Ringer. Acetazolamide reduced this effect of CO2, suggesting that the function of intracellular carbonic anhydrase may be to maximize the internal buffering power in CO2. 9. It was concluded that the internal HCO3- was determined primarily by the CO2 level and pHi, that internal HCO3- made a large contribution to the buffering power, and that after internal acidfication pHi was restored to normal by active transport of H+, OH- or HCO3- across the cell membrane. The active transport was much faster in CO2 than in CO2-free Ringer.

The effects of lithium and sodium on the potassium conductance of snail neurones

1. The iontophoretic injection of lithium into snail neurones reversibly increased the resting relative potassium permeability (PK). 2. Long exposures to snail Ringer containing 25 mM-Li and correspondingly reduced Na also caused an increase in PK. This did not occur with Ringer in which the same reduction of Na was made by replacing it with Tris. 3. Replacement of part of the Ringer Na by either Li or Tris led to proportional decreases in internal Na. 4. Injecting large quantities of Na into ouabain-treated cells caused effects similar to those of Li injection. Without ouabain, Na injection stimulated the electrogenic Na pump. 5. A number of tests failed to produce any clear evidence that intracellular Ca was involved in the response to Li.

Axoplasm chemical composition in Myxicola and solubility properties of its structural proteins

The chemical composition of axoplasm extracted from the giant axon of Myxicola infundibulum has been analysed, and some of the factors which disperse its gel structure have been identified. 2. The axoplasm contains about 3-6% protein, and 0-12% lipid. It is isosmotic with sea water and has a pH near 7-0. 3. Inorganic ions in extracted axoplasm include: Na+, 13m-mole/kg wet wtl; K+, 280; Cl-, 24; Ca2+, 0-3; Mg2+, 3. 4. Free organic ions in axoplasm include: gly, 180 m-mole/kg wet st.; cysteic acid, 120; asp, 75; glu, 10; ala, 7; tau, 5; thr, 2; gln and ser, trace; homarine, 63; isethionate, 0. 5. The gel structure is dispersed by solutions containing 1--10 mM-Ca2+, because this ion activates an endogenous protease. The gel can also be dispersed without proteilysis by solutions containing 0-5 M-KCl, or 0-5 M guanidine hydrochloride, or 3-5 M urea, all of which break down neurofilaments. 6. It is argued that many aspects of the composition and dispersal properties of Myxicola axoplasm are similar to those in other axons.

Intracellular recording of secretory potentials in a "mixed" salivary gland

Secretory potentials evoked by nerve stimulation have been recorded from both types of cell (peripheral and central) present in the acini of cockroach salivary glands.

Contribution of an electrogenic sodium pump to the membrane potential in rabbit sinoatrial node cells

A study has been made of the transient hyperpolarization (K+-induced hyperpolarization) which developed following readmission of potassium after having pre-treated the rabbit sinoatrial node tissue with K+-depleted Tyrode solution for 4--5 min at 35 degrees C. Evidence is presented indicating that the K+-induced hyperpolarization results from the activity of an electrogenic sodium pump: The K+-induced hyperpolarization was inhibited by substituting Li+ for Na+ and by cooling the tissue. The amplitude of the K+-induced hyperpolarization was increased either by increasing K+ concentration in the recovery solution or by decreasing K+ concentration in the pre-treatment K+-depleted solution. By removing Cl- from the perfusates, the amplitude of the K+-induced hyperpolarization increased. In a Cl--depleted solution, the sinoatrial node cell membrane hyperpolarized by approximately 15 mV without a transient depolarization.

Ionic mechanism of a quasi-stable depolarization in barnacle photoreceptor following red light

1. The membrane mechanism of a quasi-stable membrane depolarization (latch-up) that persists in darkness following red light was examined in barnacle photoreceptor with micro-electrode techniques including voltage-clamp and Na+-sensitive micro-electrodes. 2. Current-voltage (I-V) relations of the membrane in darkness following red light (latch-up) and in darkness following termination of latch-up with green light, indicate that latch-up is associated with an increase of membrane conductance. 3. The latch-current (membrane current in darkness following red light minus membrane current in darkness following a gree flash that terminates latch-up) was inward at the resting potential, reversed sign at about +26mV (mean of six cells), and became outward at more positive membrance potentials. 4. Current-voltage relations of the membrane during green light (no latch-up) closely resembled those during latch-up. The light-induced current (LIC) elicited by green ligh (membrane current during the light flash minus membrane current in darkness following the light flash) was inward from the resting potential to +26mV (mean of six cells), then reversed sign and became outward. 5. The latch-current and LIC were both augmented in reduced Ca2+ solutions and decreased as Na-+ was reduced at a fixed Ca2+ concentration. 6. Both LIC and latch-current reversed sign at a more negative membrane potential (increment V equals 14mV) in solutions containing one quarter the normal amount of Na+. 7. The internal Na-+ activity (a-iNa) of a photoreceptor increased from about 10-18 mM upon illumination with long steps of intense red or white illumination. Five minutes in darkness after white light, a-iNa had recovered significantly, whereas a-iNa remained elecated following red illumination. 8. Latch-up seems to be a persistence in darkness of the same membrane mechanism that normally occurs during illumination; i.e. a conductance increase to Na+ ions. Ca2+ ions act primarily to suppress this current. There is evidence for a net Na+ influx during illumination that is sustained in darkness during latch-up.

Voltage-clamp studies of the calcium inward current in an identified snail neurone: comparison with the sodium inward current

1. Membrane currents were recorded under voltage clamp from cell A of the snail Helix aspersa. 2. In sodium-free saline the inward current was reduced to 75% of that in normal saline (containing both sodium and calcium). 3. The inward current in sodium-free saline was dependent on the external calcium concentration. 4. Calcium-free saline reduced the inward current to 30% of that in normal saline. (Na, Ca)-free saline abolished the inward current. 5. Changes in calcium concentration shifted the curve relating calcium conductance to membrane potential along the voltage axis. 6. Inactivation of inward current in both normal saline and sodium-free saline developed exponentially with time. 7. Steady-state inactivation of calcium inward current was similar to that for sodium current and it is concluded that the conductance mechanisms for these two ions bear a close resemblance.

Calcium and sodium ions as charge carriers in the action potential of an identified snail neurone

1. The soma of cell A in Helix aspersa produced action potentials in sodium-free or calcium-free saline, but not in saline with neither sodium nor calcium. 2. The axon had a sodium-dependent action potential. 3. Tetrodotoxin (5 x 10(-6) M) had no effect on the overshoot except at low external divalent ion concentrations. 4. The action potential in sodium-free saline was blocked by cobalt. 5. The slope of action potential overshoot against sodium concentration in the presence of 10 mM calcium was 10.5 mV/tenfold change. That of overshoot against calcium concentration in the presence of 75 mM sodium was 22 mV/tenfold change. 6. In sodium-free saline the slope of overshoot versus calcium concentration was 27 mV/tenfold change. 7. It is concluded that calcium is an important charge carrier in the action potential of cell A.

Activation of electrogenic sodium pump in mammalian skeletal muscle by external cations

The effect of change of the external ionic composition on "Na-loaded" and "K-depleted" soleus muscle fibres of K-deficient rats was investigated by recording resting membrane potentials. The addition of K, Rb, Cs and NH4 ions to K-free Krebs solution bathing "Na-rich" muscles resulted in a rapid hyperpolarization. The hyperpolarization was abolished by removing the above cations, cooling to ca. 4 degrees C, and adding 0.1 mM ouabain. The effectiveness of cations for activating the electrogenic Na pump was Rb greater than or equal to K greater than NH4 greater than Cs, and NH4 ions seemed to be unique in their stimulating action. The resting cell membrane of "Na-rich" muscles is permeable to cations in the order of Rb = K greater than Cs greater than NH4. Reducing Na ions in Krebs solution had no effect on the rate of Na-pumping in "Na-rich" muscle fibres at a given K concentration. It is concluded that the external K ions could be replaced by Rb, Cs and NH4 ions in activating the electrogenic Na pump in "Na-rich" soleus muscle fibres, but that the electrogenic Na pump in this tissue does not require the external Na ions.

The membrane of giant molluscan neurons: electrophysiologic properties and the origin of the resting potential

The molluscan neuron, because of its large size and accessibility, has been an important model for studying the electrophysiology of nerve cells. This review catalogs data about specific molluscan neurons, but the greater importance of this material is in the broad picture of how a neuronal membrane maintains internal potential and is responsive to changes in the environment. Electrical properties of the membrane. The mechanisms which contribute to the resting potential in molluscan neurons can be separated into ionic and metabolic components. When the electrogenic sodium pump is eliminated experimentally, the ionic component of the potential follows the constant field equation quite closely. Many of the "constants" and "parameters" which characterize the membrane of molluscan neurons are actually variables which depend upon temperature, ionic environment, and membrane potential. The evaluation of the electrical parameters is complicated by extensive infoldings of the somatic membrane, and by large axons which drain current from the soma. Most molluscan neurons have a very high specific membrane resistance and a correspondingly low potassium permeability. Membrane capacitance is close to the 1 microF/cm2 value which characterizes biological membranes. The current-voltage relation of molluscan neurons may be complicated by inward-going rectification, but if that is inhibited the I-V curve follows the prediction of either the constant field equation or a simple electrical model. Factors which modify membrane behavior. The resting potential of molluscan neurons is very sensitive to changes in temperature and Ko, through a combination of effects upon the electrogenic sodium pump, inward-going rectification, and the membrane "parameters". Inward-going rectification depends upon a rectifying K conductance, and can be eliminated by cold or the removal of Ko. Strong or prolonged currents have time-dependent effects upon the membrane, and excessive polarization leads to a "high conductance state". The underlying (non-rectifying) K permeability of the membrane is relatively insensitive to temperature and ionic changes, whereas the Na permeability increases with warming. Membrane resistance varies with both temperature and ions (because the I-V curve is sensitive to these conditions) but membrane capacitance is relatively insensitive to external factors. Electrogenic sodium transport. Sodium transport is electrogenic in molluscan neurons. It can be stimulated by warm temperatures and an excess of substrate (e.g. high Nai); it can be inhibited by cold, by an absence of substrate (e.g. low Ko), or by pharmacologic agents such as cyanide or ouabain.(ABSTRACT TRUNCATED AT 400 WORDS)

Ionic mechanisms and receptor properties underlying the responses of molluscan neurones to 5-hydroxytryptamine

1. Molluscan neurones have been found to show six different types of response (three excitatory and three inhibitory) to the iontophoretic application of 5-hydroxytryptamine (5-HT). The pharmacological properties of the receptors and the ionic mechanisms associated with these responses have been analysed.2. Four of the responses to 5-HT (named A, A', B and C) are consequent upon an increase in membrane conductance whereas the other two (named alpha and beta) are caused by a decrease in membrane conductance.3. The A-response to 5-HT consists of a ;fast' depolarization due to an increase mainly in Na(+)-conductance; the A'-response is a ;slow' depolarization also associated with a Na(+)-conductance increase. Receptors mediating the A- and A'-depolarizations have different pharmacological properties and may exist side by side on the same neurone.4. Both the B- and C-responses are inhibitory. The B-response is a ;slow' hyperpolarization due to an increase in K(+)-conductance, the C-response is a fast hyperpolarization associated with an increase in Cl(-)-conductance.5. The alpha-response to 5-HT is a depolarization which becomes reduced in amplitude with cell hyperpolarization and reverses at -75 mV; it is caused by a decrease in K(+)-conductance. The beta-response is an hyperpolarization which increases in amplitude with cell hyperpolarization and reverses at -20/-30 mV. It results from a decrease in conductance to both Na(+) and K(+) ions.6. The receptors involved in the 5-HT responses associated with a conductance increase may be recognized by the action of specific antagonists: 7-methyltryptamine blocks only the A-receptors, 5-methoxygramine only the B-receptors and neostigmine only the C-receptors. Curare blocks the A- and C-receptors and bufotenine, the A-, A'- and B-receptors. No specific antagonists have yet been found for the 5-HT responses caused by a conductance decrease.7. The significance of the multiplicity of receptors is discussed. Their functional significance at synapses is analysed in the following paper.

Intracellular chloride activity and the effects of acetylcholine in snail neurones

1. Cl(-)-sensitive micro-electrodes were used to measure intracellular Cl(-) in snail neurones. The electrodes consisted of a sharpened and chlorided silver wire mounted inside a glass micropipette.2. The electrodes appeared to record changes in internal Cl(-) accurately but in H cells the chloride equilibrium potential (E(Cl)) as measured by the Cl(-)-sensitive electrode was always less negative than E(ACh).3. In some H cells ACh caused a measurable increase in internal Cl(-) when the cell was at its resting potential. In voltage-clamped cells there was a close correlation between the change in internal Cl(-) and the extra clamp current caused by a brief application of ACh. This confirmed that ACh increases the cell's membrane permeability only to Cl(-) ions, and that E(ACh) was equal to E(Cl).4. There was good agreement between the measured change in internal Cl(-) and that calculated from the cell size and clamp charge only when it was assumed that a constant voltage offset was added to the potential of the Cl(-)-sensitive electrode while it was inside the nerve cell.5. Cl(-)-sensitive electrodes with AgCl as the sensitive material appear to be unsuitable for intracellular measurement of Cl(-), although they might be suitable for following changes in E(Cl).6. In certain D cells ACh also caused an increase in internal Cl(-) although it decreased the membrane potential. In the presence of hexamethonium, ACh caused a hyperpolarization and a smaller increase in internal chloride.7. It is concluded that the intracellular Cl(-) in both H and D cells is about 8.3 mM, giving an E(Cl) of about -58 mV.

Intracellular pH of snail neurones measured with a new pH-sensitive glass mirco-electrode

1. The construction and properties of a new design of pH-sensitive micro-electrode are described. The electrodes are very durable, and have a recessed configuration so that only the extreme tip, which can be as small as 1 mum in diameter, needs to enter the cell.2. The average intracellular pH in thirty-two snail neurones was 7.4. This was not in accord with a passive distribution of H(+) ions across the cell membrane.3. Changing membrane potential or external pH had only slow effects on internal pH.4. Removing external K had no effect, and removing external Na had only slow and variable effects on intracellular pH.5. Anoxia, azide and DNP all caused a slow fall in internal pH.6. External CO(2) caused large and rapid decreases in internal pH, which external bicarbonate appeared to offset slowly. Injected bicarbonate increased internal pH.7. The size of the pH changes caused by CO(2) suggested a minimum intracellular buffering power of 25 m-equiv H(+)/unit pH per l., equivalent to that of 150 mM Tris maleate, pH 7.4.8. External ammonia caused a large and rapid increase in internal pH, while the injection of ammonium ions had the opposite effect.

Conductance changes associated with the secretory potential in the cockroach salivary gland

1. Conductance changes in the acini of the cockroach salivary gland have been examined during nerve stimulation by means of two intracellular electrodes placed in the same acinus, the first electrode being used for recording membrane potential and the second for current injection.2. The transient hyperpolarization (secretory potential) in the acinus evoked by nerve stimuli is accompanied by a rise in membrane conductance. The conductance, however, remains high for a longer period than that of the response.3. Applying the analysis of Trautwein & Dudel (1958) to the secretory potentials recorded in the acinus (assumed to behave electrically like a single cell) gives estimates of the ;transmitter equilibrium potential'. The values indicate that the neurotransmitter increases the membrane potassium conductance.4. The hyperpolarization of the acinus evoked by 10(-6)M dopamine in the bathing fluid is also associated with an increase in membrane potassium conductance.

A kinetic description for sodium and potassium effects on (Na+ plus K+)-adenosine triphosphatase: a model for a two-nonequivalent site potassium activation and an analysis of multiequivalent site models for sodium activation

1. Dissociation constants for sodium and potassium of a site that modulates the rate of ouabain-(Na(+)+K(+))-ATPase interaction were applied to models for potassium activation of (Na(+)+K(+))-ATPase. The constants for potassium (0.213 mM) and for sodium (13.7 mM) were defined, respectively, as activation constant, K(a) and inhibitory constant, K(i).2. Tests of the one- and the two-equivalent site models, that describe sodium and potassium competition, revealed that neither model adequately predicts the activation effects of potassium in the presence of 100 or 200 mM sodium.3. The potassium-activation data, obtained at low potassium and high sodium, were explained by a two-nonequivalent site model where the dissociation constants of the first site are 0.213 mM for potassium and 13.7 mM for sodium. The second site was characterized by dissociation constants of 0.091 mM for potassium and 74.1 mM for sodium.4. The two-nonequivalent site model adequately predicted the responses to concentrations of potassium between 0.25 and 5 mM in the presence of 100-500 mM sodium. At lower sodium concentrations the predicted responses formed an upper limit for the function of observed activities. This limit was reached at lower concentrations of potassium and higher concentrations of sodium, which inferred saturation of the sodium-activation sites with sodium.5. Sodium-activation data were corrected for sodium interaction with potassium-activation sites by use of the two-nonequivalent site model for potassium activation. Tests of equivalent site models suggested that the corrected data for sodium activation may be most consistent with a model that has three-equivalent sites. Other multiequivalent site models (n = 2, 4, 5 or 6), however, cannot be statistically eliminated as possibilities. The three-equivalent site activation model was characterized by dissociation constants of 1.39 mM for sodium and 11.7 mM for potassium. The system theoretically would be half-maximally activated by 5.35 mM sodium in the absence of potassium.6. Derivation of the model for sodium activation assumed that the affinities of these sites for sodium and potassium are independent of cation interactions with the potassium-activation sites. Therefore, the kinetic descriptions for sodium and potassium effects form a composite model that is consistent with simultaneous transport of sodium and potassium.7. Predictions of the composite equation are in reasonable agreement with data obtained by variation of sodium (potassium = 10 mM), variation of potassium (sodium = 100 mM) and by simultaneous variation of sodium and potassium (sodium:potassium = 10). Sodium-activation data (2.5-20 mM sodium) also agree with predictions of the model in the presence of potassium concentrations which are thought to be present at the sodium-activation sites in vivo.8. The kinetic description for sodium (three-equivalent sites) and potassium (two-nonequivalent sites) activation of the transport-ATPase is in accord with the probable stoichiometric requirements of the sodium pump. The model is also in general agreement with other studies on intact transporting systems and (Na(+)+K(+))-ATPase in fragmented membrane preparations with respect to potassium activation, although there is a quantitative disagreement. The model for sodium activation, though consistent with data obtained by other studies on fragmented (Na(+)+K(+))-ATPase preparations, is in apparent variance with much of the data obtained for intact transporting systems. The description for potassium activation suggests that the rates of ouabain binding to (Na(+)+K(+))-ATPase are modulated by competition between sodium and potassium for one of the two potassium-activation sites.

Membrane potential measurement in parotid acinar cells

1. Intracellular recording of membrane potential was made from acinar cells of the isolated mouse parotid gland superfused with physiological salt solutions.2. The mean acinar resting membrane potential was - 68.5 mV during superfusion with Krebs-Henseleit solution. Shift of the superfusion solution to one containing ACh or adrenaline (10(-5)M) always caused a transient hyperpolarization (about 10-15 mV).3. The membrane potential was mainly dependent on the extracellular K concentration ([K](o)). Increasing [K](o) tenfold decreased the membrane potential by 50 mV. This depolarization was not mediated by ACh release from depolarized nerve endings, since it was seen in the presence of atropine (1.4 x 10(-6)M) and not caused by the accompanying reduction in [Na](o) to 40 mM caused only a small depolarization (less than 10 mV).4. When the superfusion solution was shifted, during intracellular recording, from a normal Krebs-Henseleit solution ([K] = 4.7 mM) to a K-free solution, a hyperpolarization of about 8 mV was measured. Reintroduction of the normal K-containing solution after a longer period of K deprivation (30-70 min) resulted in a short-lasting pronounced hyperpolarization (about 20 mV) which could be blocked by Strophanthin-G (10(-3)M).5. In contrast to previous reports, the present findings indicate that the membrane potential of salivary acinar cells is similar, with respect to magnitude and K-dependence, to that of cells of more thoroughly investigated tissues, such as muscle and nerve, and that the membrane Na-K pump is electrogenic, at least when the cells have been loaded with Na.

Conductance changes, an electrogenic pump and the hyperpolarization of leech neurones following impulses

Following trains of impulses, sensory neurones in the C.N.S. of the leech show a prolonged hyperpolarization, which lasts for seconds or minutes. In the present investigation the mechanisms that underly this hyperpolarization have been studied by recording intracellularly. Two factors have been found to be responsible. One is the activity of an electrogenic pump (see Baylor & Nicholls, 1969b); the other is a long-lasting change in K conductance.1. Additional evidence that an electrogenic pump contributes to a slow after-hyperpolarization of leech sensory neurones is provided by the effects of injecting Na intracellularly. This leads to an increase in membrane potential that is blocked by the cardiac glycoside strophanthidin. Furthermore, after a train of impulses, reducing the K concentration in the external fluid characteristically reduces the hyperpolarizing action of the pump.2. The hyperpolarization following impulses is associated with a reduction of the cell membrane resistance that can persist for several minutes.3. Several lines of evidence suggest that the reduction in input resistance during the hyperpolarization is mainly due to an increased permeability to K. Thus, when the K concentration in Ringer fluid is reduced, the peak amplitude of the hyperpolarization following a train becomes larger. Furthermore, the conductance dependent part of the after-hyperpolarization has a reversal potential close to the equilibrium potential for K (E(K)). Substitution of Cl by SO(4) has little effect either on the after-hyperpolarization or on the conductance change following a train.4. Increased external Ca concentrations lead to a marked increase in the hyperpolarization that follows impulse activity. The enhanced hyperpolarization in high Ca is associated with a corresponding reduction in input resistance. The amplitude and duration of the hyperpolarization following a brief train of impulses can be increased by a factor of 5 or more in Ringer fluid containing 10 mM-Ca instead of the usual 1.8 mM. The hyperpolarization and resistance changes still occur in solutions containing 20 mM-Mg.5. To augment the hyperpolarization the increased concentration of Ca must be present during the train of impulses.6. The relative contributions of the K conductance increase and of the electrogenic pump for generating the hyperpolarization after impulse activity are different in the three types of sensory cell responding to touch, pressure and noxious stimulation.

Metabolism and the electrical activity of anoxic ventricular muscle

1. The action potential duration of anoxic guinea-pig ventricular muscle was related to ATP generated by glycolysis. In 50 mM glucose medium the action potential duration was maintained; in 5 mM glucose medium the action potential duration shortened, the glycolytic rate declined and the ATP content was reduced.2. The action potential amplitude was related to the metabolic state of the muscle but not to the intracellular sodium concentration.3. It is suggested that changes in the action potential duration and overshoot in anoxic muscle may be due to an influence of metabolism on the slow inward current.4. Anoxic muscle incubated for 8 hr in 5 mM glucose medium had an E(m) of -77.1 mV compared to -81.1 mV in fresh muscle. The calculated E(k) of anoxic muscle was -47.4 mV.5. The resting potential of anoxic muscle was separated into two components, one dependent on potassium distribution and the other on the activity of an electrogenic sodium pump.6. The electrogenic pump component was stimulated upon raising the glucose concentration of the medium or upon raising the external potassium concentration.7. The electrogenic pump component was inhibited by ouabain or by reduction of the temperature from 35 to 8 degrees C.