Intracellular metabolism of adenosine 3',5'-cyclic monophosphate and calcium inward current in perfused neurones of Helix pomatia

Apparent loss of calcium-activated potassium current in internally perfused snail neurons is due to accumulation of free intracellular calcium

Internal perfusion of Helix neurons with a solution containing potassium aspartate, MgCl2, ATP, and HEPES causes the calcium-activated potassium current (IK(Ca)) evoked by depolarizing voltage steps to decrease with time. When internal free Ca++ is strongly buffered to 10(-7) M by including 0.5 mM EGTA and 0.225 mM CaCl2 in the internal solution, IK(Ca) remains constant for up to 3 hours of perfusion. In cells where IK(Ca) is small at the start of perfusion, perfusion with the strongly buffered 10(-7) M free Ca++ solution produces increases in IK(Ca) which ultimately saturate. In cells perfused with solutions buffered to 10(-6) M free Ca++, IK(Ca) is low and does not change with perfusion. These results lead us to conclude that IK(Ca) is stable in perfused Helix neurons and that the apparent loss of IK(Ca) seen initially with perfusion is due to accumulation of cytoplasmic calcium. Since the calcium current (ICa) provides the Ca++ which activates IK(Ca) during a depolarizing pulse, ICa is also stable in perfused cells when free intracellular Ca++ is buffered. Perfusion with 1 microM calmodulin (CaM) produces no effect on IK(Ca) with either 10(-7) or 10(-6) M free internal calcium. Inhibiting endogenous CaM by including 50 microM trifluoperazine (TFP) in both the bath and the internal perfusion solution also produces no effect on IK(Ca) with 10(-7) M free internal calcium. It is concluded that CaM plays no role in IK(Ca) activation.

Intracellular factors for the maintenance of calcium currents in perfused neurones from the snail, Lymnaea stagnalis

Isolated nerve cell bodies from Lymnaea stagnalis were internally perfused and voltage-clamped. The magnitude of the Ca2+ current was monitored while perfusing with various intracellular solutions. When the intracellular perfusate was unenriched (containing only inorganic ions, 100 mM-HEPES and 5 mM-EGTA), the Ca2+ current was found to 'wash out', falling to half of its maximum value approximately 30-40 min from the beginning of perfusion. Stopping the flow of the perfusing solution increased this half-time to more than 50 min. The current-voltage relationship changed only slightly during wash-out. The addition of 2 mM-ATP and 1 mM-Mg2+ to the internal perfusate prevented, and even reversed, wash-out of the Ca2+ current. Both ATP and Mg2+ were necessary for maximal effect. Such current loss as occurred in the presence of ATP and Mg2+ was associated with a decrease in the capacitance of the cell and probably resulted from membrane being pulled into the pipette. The rate of inactivation of the Ca2+ current increased during perfusion with an unenriched internal solution, but decreased to initial values when ATP and Mg2+ were added to the internal perfusate. Although intracellular Mg2+ was necessary for the prevention of wash-out, levels higher than 1 mM had a blocking effect on the Ca2+ current. Certain factors that promote cyclic AMP-dependent protein phosphorylation (internal: cyclic AMP, theophylline and catalytic subunit of cyclic AMP-dependent protein kinase; external: dibutyryl cyclic AMP, 8-bromo cyclic AMP and forskolin) had no effect on the magnitude of the Ca2+ current in cells perfused with ATP and Mg2+. Externally applied theophylline blocked the Ca2+ current. The mechanism through which ATP and Mg2+ act to prevent wash-out of the Ca2+ current may be to enhance the ability of the cell to lower the Ca2+ concentration near the inner surface of the plasma membrane. This would prevent both the reversible block of Ca2+ current by intracellular Ca2+ and an irreversible loss of current due to high levels of intracellular Ca2+.

Phosphorylation of ion channels

The introduction of highly specific reagents such as enzymes and inhibitors directly into living cells has proven to be a powerful tool in studying the modulation of cellular activity by protein phosphorylation. The use of exogenous kinases can be thought of as a pharmacological approach: this demonstrates that phosphorylation can produce modulation, but does not address the question of whether the cell actually uses this mechanism under normal physiological conditions. The complementary approach, the introduction of highly specific inhibitors such as R subunit or PKI, does ask whether endogenous kinase activity is necessary for a given physiological response. Together these two approaches have provided rather compelling evidence that cAMP-dependent and calcium/phospholipid-dependent protein phosphorylations can regulate membrane excitability. In several cases single-channel analysis has allowed the demonstration that an ion channel itself or something very close to the channel is the phosphorylation target, and it seems reasonable to assume that this will also be the case for many if not all of the other systems described above. Have any general principles emerged from the results to date? Certainly it seems clear that protein phosphorylation regulates not one but many classes of ion channels. As summarized in the Table, different channels can be modulated in different cells, some channels are activated while others are inhibited, and in some cells more than one channel is subject to modulation by phosphorylation. The list in the Table is probably not yet complete, and indeed it is not inconceivable that all ion channels can under appropriate conditions be regulated by phosphorylation. What aspect of channel function is altered by phosphorylation? The total membrane current, I, carried by a particular species of ion channel is given by Npi, where N is the number of active channels in the membrane, p is the probability that an individual channel will be open, and i is the single-channel current. In principle a change in I, the quantity measured in whole cell experiments, could be caused by a change in any one (or more) of the parameters, N, p or i (see Fig. 1). In the two cases in which single-channel measurements have allowed this question to be investigated, changes in N (Shuster et al., 1985) and p (Ewald et al., 1985) have been observed. Here again it seems unlikely that any one mechanism operates in all cases, and it would not be surprising to find that phosphorylation of some other channel results in a change in i.(ABSTRACT TRUNCATED AT 400 WORDS)

Fast decrease of the peak current carried by barium ions through calcium channels in the somatic membrane of mollusc neurons

In experiments on nonidentified intracellularly perfused snail neurons the effects of replacing external divalent cations on the function of potential-dependent Ca channels have been studied. Ba substitution for Ca in the external medium caused a rapid decline (with half-times of about 2-3 min) in peak inward current amplitude when the current was activated from holding potential levels close to the resting potential. The decline could be reversed by membrane hyperpolarization. Barium current declined to a steady-state level which resembled in both relative amplitude (10-30% of the initial current amplitude) and insensitivity to intracellular introduction of exogenous cAMP the steady-state Ca current reached during the "wash out" process. It is suggested that two populations of Ca channels exist in snail neuronal membrane, one of which is dependent on cAMP metabolism and is reversibly switched off by the passage of Ba ions.

Modulation of calcium channels by norepinephrine in internally dialyzed avian sensory neurons

Modulation of voltage-dependent Ca channels by norepinephrine (NE) was studied in chick dorsal root ganglion cells using the whole-cell configuration of the patch-clamp technique. Cells dialyzed with K+ and 2-10 mM EGTA exhibited Ca action potentials that were reversibly decreased in duration and amplitude by NE. Ca channel currents were isolated from other channel contributions by using: (a) tetrodotoxin (TTX) to block gNa, (b) internal K channel impermeant ions (Cs or Na/N-methylglucamine mixtures) as K substitutes, (c) external tetraethylammonium (TEA) to block K channels, (d) internal EGTA to reduce possible current contribution from Ca-activated channels. A marked decline (rundown) of Ca conductance was observed during continual dialysis, which obscured reversible NE effects. The addition of 2-5 mM MgATP to the intracellular solutions greatly retarded Ca channel rundown and permitted a clear assessment of modulatory drug effects. The inclusion of an intracellular creatine phosphate/creatine phosphokinase nucleotide regeneration system further stabilized Ca channels, which permitted recording of Ca currents for up to 3 h. NE reversibly decreased both steady state Ca currents and Ca tail currents in Cs/EGTA/MgATP-dialyzed cells. A possible role of several putative intracellular second messengers in NE receptor-Ca channel coupling was investigated. Cyclic AMP or cyclic GMP added to the intracellular solutions at concentrations several orders of magnitude higher than the Kd for activation of cyclic nucleotide-dependent protein kinases did not block or mask the expression of the NE-mediated decrease in gCa. Addition of internal EGTA to a final concentration of 10 mM also did not affect the expression of the NE response. These results suggest that neither cyclic AMP nor cyclic GMP nor Ca is acting as a second messenger coupling the NE receptor to the down-modulated Ca channel population.

Phosphorylation of the calcium antagonist receptor of the voltage-sensitive calcium channel by cAMP-dependent protein kinase

Physiological studies indicate that voltage-sensitive calcium channels are regulated by cAMP and protein phosphorylation. The calcium antagonist receptor of the voltage-sensitive calcium channel from transverse-tubule membranes consists of three subunits, designated alpha, beta, and gamma. The catalytic subunit of cAMP-dependent protein kinase phosphorylates both the alpha and beta subunits of the purified receptor at a rate and extent that suggests they are potential physiological substrates of this enzyme. The phosphorylation of the alpha and beta subunits in transverse-tubule membranes was analyzed by two-dimensional gel electrophoresis. In intact transverse-tubule membranes, the alpha subunit is not significantly phosphorylated. However, the beta subunit, identified by its Mr, pI, and binding to wheat germ agglutinin-Sepharose, was one of the substrates selectively phosphorylated by cAMP-dependent protein kinase in transverse-tubule membranes. These results suggest that cAMP-dependent phosphorylation of the beta subunit of the calcium antagonist receptor may be an important regulatory mechanism for calcium channel function.

Two types of calcium channels in the somatic membrane of new-born rat dorsal root ganglion neurones

Ca2+ inward currents evoked by membrane depolarization have been studied by the intracellular dialysis technique in the somatic membrane of isolated dorsal root ganglion neurones of new-born rats. In about 20% of the investigated cells a hump has been detected on the descending branch of the current-voltage curve, indicating the presence of two populations of Ca2+ channels differing in their potential-dependent characteristics. An initial less regular component of the Ca2+ current was activated at membrane potentials from -75 to -70 mV. Its amplitude reached 0.2-0.9 nA at 14.6 mM-extracellular Ca2+. The activation kinetics of this component could be approximated by the Hodgkin-Huxley equation using the square of the m variable. tau m varied in the range from 8 to 1 ms at potentials between -60 and -25 mV ('fast' Ca2+ current). The second component of the Ca2+ current was activated at membrane depolarizations to between -55 and -50 mV. It could be recorded in all cells investigated and reached a maximum value of 1-7 nA at the same extracellular Ca2+ concentration. This component decreased rapidly during cell dialysis with saline solutions. The decrease could be slowed down by cooling and accelerated by warming the extracellular solution. Intracellular introduction of 3',5'-cAMP together with ATP and Mg2+ not only prevented the decrease but often restored the maximal current amplitude to its initial level. The activation kinetics of this component could also be approximated by a square function, tau m being in the range 16-2.5 ms at membrane potentials between -20 and +3 mV ('slow' Ca2+ current). The fast Ca2+ current inactivated exponentially at sustained depolarizations in a potential-dependent manner, tau h varying from 76 to 35 ms at potentials between -50 and -30 mV. The inactivation of the slow Ca2+ current studied in double-pulse experiments was current-dependent and developed very slowly (time constant of several hundreds of milliseconds). It slowed down even more at low temperature or after substitution of Ba2+ for Ca2+ in the extracellular solution. Both currents could also be carried by Ba2+ and Sr2+, although the ion-selecting properties of the two types of channels showed quantitative differences. Specific blockers of Ca2+ channels (Co2+, Mn2+, Cd2+, Ni2+ or verapamil) exerted similar effects on them. The existence of metabolically dependent and metabolically independent Ca2+ channels in the neuronal membrane and their possible functional role are discussed.

Currents carried by monovalent cations through calcium channels in mouse neoplastic B lymphocytes

Membrane currents through the Ca2+ channel were studied in a hybridoma cell line (MAb-7B) constructed by fusion of S194 myeloma cells and splenic B lymphocytes from the mouse. The whole-cell variation of the patch-electrode voltage-clamp technique was used. When [Ca2+]o = 2.5 mM, [Na+]o = 150 mM and [Na+]i = 155 mM, the current reversed from inward to outward at 20.9 +/- 2.4 mV (mean +/- S.D., n = 62). Both inward and outward currents showed voltage-dependent inactivation with the same membrane potential dependence of steady-state inactivation. The decay time constant of the current decreased from about 27 ms at -44 mV to a saturation value of 16 ms at about -20 mV, and remained at this value even when the current became outward. From the above results both the inward and outward currents were considered to flow through Ca2+ channels. The inward current showed no change when the external Na+ was replaced with Cs+ or tetraethylammonium and increased when [Ca2+]o was increased. Also, the reversal potential became more positive with increasing [Ca2+]o with a slope of 29 mV/decade change of [Ca2+]o. Effects of different divalent cations examined at 10 mM concentration showed the reversal potential to become more positive in the order of Mn2+, Sr2+ approximately equal to Ba2+ and Ca2+ whereas the relative maximum amplitudes of peak inward current were 1.0 for Ca2+, 1.24 for Sr2+, 0.99 for Ba2+ and 0.07 for Mn2+. When [Ca2+]o or [Mg2+]o was reduced by chelators, monovalent cations became capable of carrying inward current through the Ca2+ channel. These monovalent currents share common kinetic properties with the Ca2+ current, as judged from the steady-state inactivation and the decay time constant of the current. The monovalent cation current was blocked by divalent cations in a voltage-dependent manner. The half-blocking concentrations of Ca2+ and Mg2+ at -45 mV were 2.0 X 10(-6) M and 3.0 X 10(-5) M respectively. The same voltage-dependent binding mechanism can explain the outward current carried by monovalent cations at large positive potentials at normal Ca2+ concentrations. The suppression of the monovalent currents by Ca2+ and Mg2+ showed different voltage dependences. The suppression by Ca2+ increased and then decreased as the membrane potential was made negative, whereas the suppression by Mg2+ increased monotonically. This difference can be explained by considering the fact the Ca2+ is permeant and Mg2+ is impermeant through the Ca2+ channel.

The calcium current in inner segments of rods from the salamander (Ambystoma tigrinum) retina

Solitary rod inner segments were isolated from salamander retinae. Their Ca current was studied with the 'whole-cell, gigaseal' technique (Hamill, Marty, Neher, Sakmann & Sigworth, 1981). The soluble constituents of the cytoplasm exchanged with the solution in the pipette. The external solution could be changed during continuous perfusion. Membrane voltage was controlled with a voltage clamp. After permeant ions other than Ca were replaced with impermeant ions (i.e. tetraethylammonium as a cation, and aspartate or methanesulphonate as an anion), an inward current remained. It activated at approximately -40 mV, reached a maximum at approximately 0 mV, and decreased as the membrane was further depolarized. The size of the current increased when Ba was substituted for external Ca. The current was blocked when Ca was replaced with Co. The voltage at which the current was half-maximum shifted from approximately -22 to -31 mV during the initial 3 min of an experiment. The maximum amplitude of the current continuously declined during the entire course of an experiment. The time course for activation of the Ca current following a step of depolarization could be described by the sum of two exponentials. The time constant of the slower exponential was voltage dependent. Deactivation following repolarization could also be described by the sum of two exponentials. Both time constants for deactivation were independent of voltage (between -30 and 0 mV) and faster than the slower time constant for activation. When the internal Ca concentration was buffered by 10 mM-EGTA, the Ca current did not inactivate during several seconds of maintained depolarization. When the concentration of EGTA was reduced to 0.1 mM, the Ca current declined and the membrane conductance decreased during several seconds of maintained depolarization. This inactivation was incomplete and only occurred after a substantial quantity of Ca entered. Following repolarization the Ca conductance recovered from inactivation. In contrast, the continuous decline observed during the course of an experiment (item 3) was not reversible. The difference suggests that inactivation and the decline are distinct processes.

Intracellular calcium ions and calcium currents in perfused neurones of the snail, Lymnaea stagnalis

Neuronal somata of Lymnaea stagnalis were internally perfused and voltage clamped using the suction pipette method. The cells were exposed to internal solutions buffered to various concentrations of Ca2+ while the cytoplasmic Ca2+ activity [( Ca2+]i) was monitored with a Ca2+ -sensitive micro-electrode. [Ca2+]i was usually about 10(-7) M when the cell was perfused with a solution buffered to any level of Ca2+ from 9 X 10(-7) to below 10(-8) M. With internal solutions buffered to 10(-6) M-Ca2+ or greater, [Ca2+]i increased rapidly and overshot the perfusate Ca2+ activity by up to two orders of magnitude. It was thus virtually impossible to hold [Ca2+]i steady at any levels other than about 10(-7) M or 10(-4) M using internal perfusion of simple ionic internal solutions. The excess Ca2+ which caused the overshoot of [Ca2+]i entered the cell from the external solution through Cd2+ -sensitive channels. Cd2+ in the external solution prevented or reversed the overshoot of [Ca2+]i and brought [Ca2+]i to near the perfusate level. ATP added to the internal solution also prevented [Ca2+]i from overshooting the perfusate level during perfusion with high-Ca2+ buffers. By monitoring [Ca2+]i with a Ca2+ -sensitive micro-electrode, we were able to estimate the relationship between [Ca2+]i and the Ca2+ current (ICa) measured under voltage clamp. ICa was completely blocked as [Ca2+]i was raised to 10(-6) M. We believe that the discrepancy between our data and other estimates of the ICa vs. [Ca2+]i relationship using internal perfusion of molluscan nerve cells results from the incorrect assumption that [Ca2+]i is controlled adequately during internal perfusion.

Cyclic AMP-mediated potentiation of muscarinic hyperpolarization in neuroblastoma cells

Adenosine, 2-chloroadenosine and prostaglandin E1 which are known to increase cyclic AMP in neuroblastoma cells potentiated the acetylcholine-induced muscarinic hyperpolarization of the cells without changing the resting membrane potential. The potentiation caused by 2-chloroadenosine was further augmented by Ro 20-1724, a phosphodiesterase inhibitor. A direct intracellular pressure application of cyclic AMP potentiated the muscarinic hyperpolarization without changing the resting membrane potential. Morphine which inhibits adenylate cyclase antagonized 2-chloroadenosine-induced potentiation of the muscarinic hyperpolarization. These results suggest that changes in cyclic AMP level modulate the muscarinic response of neuroblastoma cells.

Intracellular protein kinase and calcium inward currents in perfused neurones of the snail Helix pomatia

Changes in the amplitude of the calcium inward current caused by intracellular administration of tolbutamide (an inhibitor of the cyclic AMP-dependent protein kinase activity) or catalytic subunits of cAMP-dependent protein kinases from rabbit myocardium were studied on internally perfused nerve cells of the snail, Helix pomatia. Intracellular administration of 7 mM tolbutamide caused a rapid decline of the amplitude of the calcium current that had been stabilized by theophylline; the effect was practically completely reversible. In contrast, addition to the perfusing solution of exogenous catalytic subunits of cyclic AMP-dependent protein kinases (about 0.7 microM of protein) together with 2 mM adenosine 5'-triphosphate and 3 mM MgCl2, led to stabilization of the calcium conductance of the cell membrane or restored it if it had declined during the perfusion with basic solution. The effect depended largely on the presence of adenosine 5'-triphosphate. Its time course was very slow (dozens of minutes) due probably to slow diffusion of the protein inside the cell. Heat-inactivated catalytic subunits did not produce such a stabilizing or restoring action on the calcium conductance. The results substantiate the suggestion that the normal functioning of calcium channels depends on phosphorylation catalyzed by cyclic AMP-dependent protein kinases.