Hormonal and Neurotransmitter Regulation of Ca++ Influx Through Voltage-Dependent Slow Channels in Cardiac Muscle Membrane

The voltage-and time-dependent slow channels in the myocardial cell membrane are the major pathway by which Ca⁺⁺ ions enter the cell during excitation for initiation and regulation of the force of contraction of cardiac muscle. These slow channels behave kinetically as if their gates open, close, and recover more slowly than those of the fast Na⁺ channels; in addition, the slow channel gates operate over a less negative (more depolarized) voltage range. Tatrodotoxin does not block the slow channels, whereas the calcium antagonistic drugs, Mn⁺⁺, Co⁺⁺, and La⁺⁺⁺ ions do. The slow channels have some special properties, including their functional dependence on metabolic energy, their selective blockade by acidosis, and their regulation by cyclic AMP level. Because of their regulation by cyclic AMP, it is proposed that either the slow channel protein or an associated regulatory protein must be phosphorylated in order for the channel to be made available for voltage activation during excitation. That is, the dephosphorylated channel would be electrically silent.

The requirement for phosphorylation allows the extrinsic control of the slow channels and Ca⁺⁺ influx by neurotransmitters, hormones, and autacoids that affect the cyclic nucleotide levels.     

Phosphorylation shifts the time-dependence of cardiac Ca++ channel gating currents.

A general mechanism for the physiological regulation of the activity of voltage-dependent Na+, Ca++, K+, and Cl channels by neurotransmitters in a variety of excitable cell types may involve a final common pathway of a cyclic AMP-dependent phosphorylation of the channel protein. The functional correlates of channel phosphorylation are known to involve a change in the probability of opening, and a negative or positive shift in the voltage dependence for activation of the conductance. The voltage dependence for activation appears to be governed by the properties of the charge movement of the voltage-sensing moiety of the channel. This study of the gating charge movement of cardiac Ca++ channels has revealed that isoproterenol or cAMP (via a presumed phosphorylation of the channel) speeds the kinetics of the Ca++ channel gating charge movement. These results suggest that the changes in the kinetics and voltage dependence of the cardiac calcium currents produced by beta-adrenergic stimulation are initiated, in part, by parallel changes in the gating charge movement.     

Transduction persists in rod photoreceptors after depletion of intracellular calcium

We have examined the role of Ca++ in phototransduction by manipulating the intracellular Ca++ concentration in physiologically active suspensions of isolated and purified rod photoreceptors (OS-IS). The results are summarized by the following. Measurement of Ca++ content using arsenazo III spectroscopy demonstrates that incubation of OS-IS in 10 nM Ca++-Ringer's solution containing the Ca++ ionophore A23187 reduces their Ca++ content by 93%, from 1.3 to 0.1 mol Ca++/mol rhodopsin. Virtually the same reduction can be accomplished in 10 nM Ca++-Ringer's without ionophore, presumably via the plasma membrane Na/Ca exchange mechanism. Hundreds of photoresponses can be obtained from the Ca++-depleted OS-IS for at least 1 h in 10 nM Ca++-Ringer's with ionophore. The kinetics and light sensitivity of the photoresponse are essentially the same in the presence or absence of the ionophore in 10 nM Ca++. The addition of A23187 in 1 mM Ca++-Ringer's results in a Ca++ influx that rapidly suppresses the dark current and the photoresponse. This indicates that there is an intracellular site at which Ca++ can modulate the light-regulated conductance. Both the current and photoresponse can be restored if intracellular Ca++ is reduced by lowering the external Ca++ to 10 nM. During the transition from high to low Ca++, the response duration becomes shorter, which suggests that it can be regulated by a Ca++-dependent mechanism. If the dark current and the photoresponse are suppressed by adding A23187 in 1 mM Ca++-Ringer's, the subsequent addition of the cyclic GMP phosphodiesterase inhibitor isobutylmethylxanthine can restore the current and photoresponse. This implies that under conditions where the rod can no longer control its intracellular Ca++, the elevation of cyclic GMP levels can restore light regulation of the channels. The persistence of normal flash responses under conditions where intracellular Ca++ levels are reduced and perturbed suggests that changes in the intracellular Ca++ concentration do not cause the closure of the light-regulated channel.     

Ca++ and Na+ channels involved in neuronal cell death. Protection by flunarizine.

Flunarizine, a class IV Ca++ antagonist non-selective for slow Ca++ channels, has been shown to be beneficial in the prophylactic treatment of migraine, the treatment of vertigo, and as add-on treatment in therapy-resistant forms of epilepsy. Flunarizine protects the brain against functional and/or structural neuronal damage in various animal models of cerebral ischemia. In addition to its cerebrovascular effect, flunarizine has also direct neuroprotective actions. New data have emerged on flunarizine with regard to Ca++ and Na+ channels in neuronal cells. There are several possible mechanisms involved in the mode of action of flunarizine. Flunarizine may block Ca++ and Na+ channels, both of which may flux Ca++ as well as Na+. A decrease in Ca++ influx may prevent further release of glutamate, and activation of NMDA receptor gated Ca++ channels at physiological pH. A decrease in Na+ influx may prevent cytotoxicity secondary to a large gain in intracellular Ca++, by reverse operation of the Na+/Ca++ exchanger. This mechanism may be important when the glycolytic rate is increased with concomitant acidosis, and phospholipids are broken down as occurs typically during ischemia. Given the complexity of biochemical events leading to cell death, blocking exclusively one channel subtype is not likely to yield sufficient protection. Hence, it may be useful to develop anti-ischemic compounds which act on a series of pathways involved in Ca++ overload, rather than selectively block one such channel.     

Inhibition of cardiac slow action potentials by 8-bromo-cyclic GMP occurs independent of changes in cyclic AMP levels

Cyclic GMP inhibits the slow inward Ca current of cardiac cells. This effect could be due to a cyclic GMP-mediated phosphorylation of the Ca channel (or some protein modifying Ca channel activity), or alternatively, to enhanced degradation of cyclic AMP owing to stimulation of a phosphodiesterase by cyclic GMP. To test the latter possibility, we examined the effect of extracellular 8-bromo-cyclic GMP on cyclic AMP levels in guinea pig papillary muscles, in parallel with electrophysiological experiments. Isoproterenol (10(-6) M) significantly increased the cyclic AMP levels and induced Ca-dependent slow action potentials. Superfusion with 8-bromo-cyclic GMP (10(-3) M) inhibited the slow action potentials induced by isoproterenol. However, muscles superfused with 8-bromo-cyclic GMP had cyclic AMP levels identical to those of muscles superfused with isoproterenol alone. Similarly, 8-bromo-cyclic GMP had no effect on the increase in cyclic AMP levels of muscles treated with forskolin (10(-6) M) or histamine (10(-6) M). We conclude that the inhibitory effect of cyclic GMP on slow Ca channels in guinea pig ventricular cells is not due to a decrease in the cyclic AMP levels. We hypothesize that a cyclic GMP-mediated phosphorylation is the most likely explanation for the Ca channel inhibition observed in this preparation.     

Properties of calcium channels in cardiac muscle and vascular smooth muscle

The voltage-dependent slow channels in the myocardial cell membrane are the major pathway by which Ca²⁺ ions enter the cell during excitation for initiation and regulation of the force of contraction of cardiac muscle. The slow channels have some special properties, including functional dependence on metabolic energy, selective blockade by acidosis, and regulation by the intracellular cyclic nucleotide levels. Because of these special properties of the slow channels, Ca²⁺ influx into the myocardial cell can be controlled by extrinsic factors (such as autonomic nerve stimulation or circulating hormones) and by intrinsic factors (such as cellular pH or ATP level). The slow Ca²⁺ channels of the heart are regulated by cAMP in a stimulatory fashion. Elevation of cAMP produces a very rapid increase in number of slow channels available for voltage activation during excitation. The probability of a slow channel opening and the mean open time of the channel are increased. Therefore, any agent that increases the cAMP level of the myocardial cell will tend to potentiate I_si, Ca²⁺ influx, and contraction. The myocardial slow Ca²⁺ channels are also regulated by cGMP, in a manner that is opposite to that of CAMP. The effect of cGMP is presumably mediated by means of phosphorylation of a protein, as for example, a regulatory protein (inhibitory-type) associated with the slow channel. Preliminary data suggest that calmodulin also may play a role in regulation of the myocardial slow Ca²⁺ channels, possibly mediated by the Ca²⁺-calmodulin-protein kinase and phosphorylation of some regulatory-type of protein. Thus, it appears that the slow Ca²⁺ channel is a complex structure, including perhaps several associated regulatory proteins, which can be regulated by a number of extrinsic and intrinsic factors.VSM cells contain two types of Ca²⁺ channels: slow (L-type) Ca²⁺ channels and fast (T-type) Ca²⁺ channels. Although regulation of voltage-dependent Ca²⁺ slow channels of VSM cells have not been fully clarified yet, we have made some progress towards answering this question. Slow (L-type, high-threshold) Ca²⁺ channels may be modified by phosphorylation of the channel protein or an associated regulatory protein. In contrast to cardiac muscle where cAMP and cGMP have antagonistic effects on Ca²⁺ slow channel activity, in VSM, cAMP and cGMP have similar effects, namely inhibition of the Ca²⁺ slow channels. Thus, any agent that elevates cAMP or cGMP will inhibit Ca²⁺ influx, and thereby act to produce vasodilation. The Ca²⁺ slow channels require ATP for activity, with a K_0.5 of about 0.3 mM. C-kinase may stimulate the Ca²⁺ slow channels by phosphorylation. G-protein may have a direct action on the Ca²⁺ channels, and may mediate the effects of activation of some receptors. These mechanisms of Ca²⁺ channel regulation may be invoked during exposure to agonists or drugs, which change second messenger levels, thereby controlling vascular tone.     

Inhibition of the glycogenolytic effects of alpha-adrenergic stimulation and glucagon by cobalt ions in perfused rat liver

Cobalt ions (2 mM) inhibited the glycogenolysis induced by phenylephrine and glucagon in perfused rat liver. Cobalt ions also inhibited 45Ca++ efflux from prelabelled livers induced by phenylephrine and glucagon. In addition, they inhibited the rise in tissue levels of cyclic AMP caused by glucagon, but did not inhibit the stimulation of 45Ca++ efflux or glycogenolysis by cyclic AMP or dibutyryl cyclic AMP. The specific binding of glucagon and alpha-agonist to hepatocytes was not inhibited by cobalt ions. These data suggest that cobalt ions, presumably through their high affinity for calcium binding sites on membranes inhibit the stimulation of glycogenolysis by phenylephrine and glucagon in distinct ways; one by inhibiting calcium mobilization and the other by inhibiting cyclic AMP production. Therefore, it is conceivable that membrane-bound calcium plays an important role in stimulating Ca++ mobilization by phenylephrine, and cyclic AMP production by glucagon.     

Voltage clamp analysis of two inward current mechanisms in the egg cell membrane of a starfish

Ionic mechanisms of excitation were studied in the immature egg cell membrane of a starfish, Mediaster aequalis, by analyzing membrane currents during voltage clamp. The cell membrane shows two different inward current mechanisms. One is activated at a membrane potential of -55 approximately -50 mV and the other at -7 approximately -6 mV. They are referred to as channels I and II, respectively. A similar difference is also found in the membrane potential of half inactivation. Currents of the two channels can, therefore, be separated by selective inactivation. The currents of both channels depend on Ca++ (Sr++ or Ba++) but only the current of channel I depends on Na+. The time-course of current differs significantly between the two channels when compared at the same membrane potential. The relationship between the membrane current and the concentration of the permeant ions is also different between the two channels. The result suggests that channel II is a more saturable system. The sensitivity of the current to blocking cations such as Co++ or Mg++ is substantially greater in channel II than in channel I. Currents of both channels depend on the external pH with an apparent pK of 5.6. They are insensitive to 3 muM tetrodotoxin (TTX) but are eliminated totally by 7.3 mM procaine. The properties of channel II are similar to those of the Ca channel found in various adult tissues. The properties of channel I differ, however, from those of either the typical Ca or Na channels. Although the current of the channel depends on the external Na the amplitude of the Na current decreases not only with the Na concentration but also with the Ca concentration. No selectivity is found among Li+, Na+, Rb+, and Cs+. The experimental result suggests that Na+ does not carry current but modifies the current carried by Ca in channel I.     

Lanthanum: inhibition of ACTH-stimulated cyclic AMP and corticosterone synthesis in isolated rat adrenocortical cells

Lanthanum (La+++) is a well-known Ca++ antagonist in a number of biological systems. It was used in the present study to examine the role of Ca++ in the regulation of adenyl cyclase of the adrenal cortex by ACTH. In micromolar concentrations, .La+++ inhibited both cyclic AMP and corticosterone response of isolated adrenal cortex cells to ACTH. However, a number of intracellular processes were not affected by La+++. These include the stimulation of steroidogenesis by dibutyryl cyclic AMP, conversion of several steroid precursors into corticosterone, and stimulation of the latter by glucose. Thus, inhibition of steroidogenesis by La+++ appears to be solely due to an inhibition of ACTH-stimulated cyclic AMP formation. Electron microscope examination showed that La+++ was localized on plasma membrane of the cells and did not appear to penetrate beyond this region. Since La+++ is believed to replace Ca++ at superficial binding sites on the cell membrane, it is proposed that Ca++ at these sites plays an important role in the regulation of adenyl cyclase by ACTH. Similarities in the role of Ca++ in "excitation-contraction" coupling and in the ACTH-adenyl cyclase system raise the possibility that a contractile protein may be involved in the regulation of adenyl cyclase by those hormones which are known to require Ca++ in the process.     

The permeability of the cell-to-cell membrane channel and its regulation in mammalian cell junctions

Mammalian cell-to-cell channels show polar permselective properties discriminating against negatively charged 14 A-wide molecules and are more restrictive than the channels of insect cell junctions. The channel permeability is modulated by conditions affecting the concentration of intracellular ionic Ca: elevation of the external Ca load (B cells), treatment of cell cultures with Ca-transporting ionophore (in the presence of external Ca, but not in its absence), treatment with a combination of cyanide and iodoacetate, or with high levels of carbon dioxide, all cause depression of channel permeability. Treatment of cell cultures with cyclic AMP or its more permeable derivative, dibutyryl cyclic AMP, produces increase in permeability. A similar channel up regulation is observed upon elevation of the endogenous level of cyclic AMP by serum deprivation or lowering of cell density.     

The permeability of endplate channels to monovalent and divalent metal cations

The relative permeability of endplate channels to monovalent and divalent metal ions was determined from reversal potentials. Thallium is the most permeant ion with a permeability ratio relative to Na+ of 2.5. The selectivity among alkali metals is weak with a sequence, Cs+ greater than Rb+ greater than K+ greater than Na+ greater than Li+, and permeability ratios of 1.4, 1.3, 1.1, 1.0, and 0.9. The selectivity among divalent ions is also weak, with a sequence for alkaline earths of Mg++ greater than Ca++ greater than Ba++ greater than Sr++. The transition metal ions Mn++, Co++, Ni++, Zn++, and Cd++ are also permeant. Permeability ratios for divalent ions decreased as the concentration of divalent ion was increased in a manner consistent with the negative surface potential theory of Lewis (1979 J. Physiol. (Lond.). 286: 417--445). With 20 mM XCl2 and 85.5 mM glucosamine.HCl in the external solution, the apparent permeability ratios for the alkaline earth cations (X++) are in the range 0.18--0.25. Alkali metal ions see the endplate channel as a water-filled, neutral pore without high-field-strength sites inside. Their permeability sequence is the same as their aqueous mobility sequence. Divalent ions, however, have a permeability sequence almost opposite from their mobility sequence and must experience some interaction with groups in the channel. In addition, the concentrations of monovalent and divalent ions are increased near the channel mouth by a weak negative surface potential.     

Attractant-induced changes and oscillations of the extracellular Ca++ concentration in suspensions of differentiating Dictyostelium cells

We used a Ca++-sensitive electrode to measure changes in extracellular Ca++ concentration in cell suspensions of Dictyostelium discoideum during differentiation and attractant stimulation. The cells maintained an external level of 3-8 microM Ca++ until the beginning of aggregation and then started to take up Ca++. The attractants, folic acid, cyclic AMP, and cyclic GMP, induced a transient uptake of Ca++ by the cells. The response was detectable within 6 s and peaked at 30 s. Half-maximal uptake occurred at 5 nM cyclic AMP or 0.2 microM folic acid, respectively. The apparent rate of uptake amounted to 2 X 10(7) Ca++ per cell per min. Following uptake, Ca++ was released by the cells with a rate of 5 X 10(6) ions per cell per min. Specificity studies indicated that the induced uptake of Ca++ was mediated by cell surface receptors. The amount of accumulated Ca++ remained constant as long as a constant stimulus was provided. No apparent adaptation occurred. The cyclic AMP-induced uptake of Ca++ increased during differentiation and was dependent on the external Ca++ concentration. Saturation was found above 10 microM external Ca++. The time course and magnitude of the attractant-induced uptake of external Ca++ agree with a role of Ca++ during contraction. During development the extracellular Ca++ level oscillated with a period of 6-11 min. The change of the extracellular Ca++ concentration during one cycle would correspond to a 30-fold change of the cellular free Ca++ concentration.     

"Calcium antagonists": a class of drugs with a bright future. Part I. Cellular calcium homeostasis and calcium as a coupling messenger

The aim of this series of minireviews is to present material from multidisciplinary sources to facilitate the understanding of the pharmacology and the ample clinical potential of a class of drugs that were originally designated as "calcium antagonists" and more recently have been referred to as "calcium entry blockers", "calcium slow channel blockers" or "calcium modulators". In this first report our attention will be focussed on the pivotal role of Ca++ as a messenger linking stimuli of extracellular origin to the intracellular environment. Eucaryotic cells have a number of powerful means to control their cytosolic Ca++ concentration. Firstly, in a cell at rest the cellular membrane is relatively impermeable to passive Ca++ movements. This property of the plasmalemma prevents the high free Ca++ concentration (approximately 1 mM) of the extracellular compartment from invading the cytosol (approximately 0.1 microM). However, extracellular Ca++ can reach the cytosol through the Na+/Ca++ exchange mechanism and the plasmalemma possesses special Ca++ channels the conductance of which is controlled by gates that are opened by critical changes in cellular polarization (voltage-operated channels: VOC) or by receptor activation (receptor-operated channel: ROC). The Ca++ entering via VOC or ROC can subsequently trigger the liberation of Ca++ from the sarcoplasmic reticulum or from calcium stores located in the inner side of the plasmalemma. The intracellular message generated by external stimuli is transferred to the response mechanism by several cytosolic proteins that require Ca++ as activator. Finally, the termination of the response is the result of a reduction in the cytosolic Ca++ concentration that is accomplished by the Na+/Ca++ exchange mechanism or by energy-dependent pumps which extrude Ca++ from the cell or store it in subcellular organelles. Therefore, any of the numerous steps of the excitation-response coupling which employ Ca++ as a messenger or as a protein activator can be the site of action of a pharmacological agent. In the follow-up minireview, some methods to determine the basic pharmacological profile of compounds interfering with cellular Ca++-dependent functions will be described.     

Sodium permeability of dog red blood cell membranes. I. Identification of regulatory sites

Divalent cations and group-specific chemical modifiers were used to modify sodium efflux in order to probe the molecular structure of sodium channels in dog red blood cells. Hg++, Ni++, Co++, and PCMBS (parachloromercuribenzene sulfonic acid), a sulfhydryl reactive reagent, induce large increases in Na+ permeability and their effects can be described by a curve which assumes 2:1 binding with the sodium channel. The sequence of affinities, as measured by the dissociation constants, reflects the reactivity of these divalent cations with sulfhydryl groups. In addition, the effects of Hg++ and PCMBS can be reversed by the addition of dithiothreitol, an SH-containing compound, to the medium. Much smaller increases in Na+ permeability are produced by Zn++ and the amino-specific reagents, TNBS (2,4,6-trinitrobenzene sulfonic acid) and SITS (4-acetamido-4'-isothiocyano-stilbene-2-2'-disulfonic acid). The Zn++ effect can be described by a curve which assumes bimolecular binding with the channel, and its effect on Na+ permeability can be reversed by the addition of glycine to the medium. The effects of Ni++ and SITS can be completely reversed by washing the cells in 0.16 M NaCl while TNBS binding is partially irreversible. Measurements of mean cell volumes (MCV) indicate that the modifier-induced increases in Na+ permeability are not caused by shrinkage of the cells. It is concluded that the movement of sodium ions through ionic channels in dog red blood cells can be enhanced by modification of amino and sulfhydryl groups. Zn++, TNBS, and SITS increase Na+ permeability by modifying amino groups in the channel while Hg++, Ni++, Co++, and PCMBS act on sulfhydryl groups.     

Interactions of sodium transport, cell volume, and calcium in frog urinary bladder

The volume of individual cells in intact frog urinary bladders was determined by quantitative microscopy and changes in volume were used to monitor the movement of solute across the basolateral membrane. When exposed to a serosal hyposmotic solution, the cells swell as expected for an osmometer, but then regulate their volume back to near control in a process that involves the loss of KCl. We show here that volume regulation is abolished by Ba++, which suggests that KCl movements are mediated by conductive channels for both ions. Volume regulation is also inhibited by removing Ca++ from the serosal perfusate, which suggests that the channels are activated by this cation. Previously, amiloride was observed to inhibit volume regulation: in this study, amiloride-inhibited, hyposmotically swollen cells lost volume when the Ca++ ionophore A23187 was added to Ca++-replete media. We attempted to effect volume changes under isosmotic conditions by suddenly inhibiting Na+ entry across the apical membrane with amiloride, or Na+ exit across the basolateral membrane with ouabain. Neither of these Na+ transport inhibitors produced the expected results. Amiloride, instead of causing a decrease in cell volume, had no effect, and ouabain, instead of causing cell swelling, caused cell shrinkage. However, increasing cell Ca++ with A23187, in both the absence and presence of amiloride, caused cells to lose volume, and Ca++-free Ringer's solution (serosal perfusate only) caused ouabain-blocked cells to swell. Finally, again under isosmotic conditions, removal of Na+ from the serosal perfusate caused a loss of volume from cells exposed to amiloride. These results strongly suggest that intracellular Ca++ mediates cell volume regulation by exerting a negative control on apical membrane Na+ permeability and a positive control on basolateral membrane K+ permeability. They also are compatible with the existence of a basolateral Na+/Ca++ exchanger.     

The role of calcium and guanosine 3':5'-monophosphate in the action of acetylcholine on thyroid metabolism

The role of calcium and guanosine 3':5'-monophosphate (cyclic GMP) in the regulation of thyroid metabolism has been investigated in dog thyroid slices. Carbamoylcholine enhanced glucose carbon-1 oxidation, protein iodination, cyclic GMP accumulation and decreased thyrotropin-induced adenosine 3':5'-monophosphate (cyclic AMP) accumulation and iodine secretion; it did not affect protein synthesis. The effects of carbamoylcholine were reproduced under various experimental conditions by supplementary calcium in the medium, ouabain, and in media in which Na+ had been replaced by choline chloride. They were inhibited by lanthanum. These results further support the hypothesis that free intracellular Ca2+ is the intracellular signal for carbamoylcholine effects and suggest that a Na+ -gradient-driven Ca2+ extrusion mechanism operates in the thyroid cell. Mn2+ reproduced the effect of Ca2+ on glucose oxidation, protein iodination and cyclic GMP accumulation in Ca2+ -depleted slices and medium, and thus mimicked some intracellular effects of Ca2+. On the other hand Mn2+ inhibited the carbamoylcholine effect on thyrotropin-induced thyroid secretion and cyclic AMP accumulation, and Ca2+ inhibited the Mn2+-induced cyclic GMP accumulation. This suggests that the two ions compete for the same channel. Similarly Mn2+ inhibited calcium effects in the presence of ionophore A23187. Procaine inhibited protein iodination under all conditions suggesting a primary effect; it also inhibited all carbamoylcholine and ouabain actions. However the drug did not inhibit the effects of choline chloride and its action was reversed by raising carbamoylcholine but not Ca2+ concentration; it is therefore doubtful that procaine acts by blocking Ca2+ channels. In media without added Ca2+, Mn2+ increased cyclic GMP accumulation but did not decrease thyrotropin-induced cyclic AMP accumulation or iodine secretion, which suggests that cyclic GMP cannot be the sole mediator of the latter two effects of carbamoylcholine.     

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.     

Coupling of voltage-dependent gating and Ba++ block in the high- conductance, Ca++-activated K+ channel

Voltage-dependent Ca++-activated K+ channels from rat skeletal muscle were reconstituted into planar lipid bilayers, and the kinetics of block of single channels by Ba++ were studied. The Ba++ association rate varies linearly with the probability of the channel being open, while the dissociation rate follows a rectangular hyperbolic relationship with open-state probability. Ba ions can be occluded within the channel by closing the channel with a strongly hyperpolarizing voltage applied during a Ba++-blocked interval. Occluded Ba ions cannot dissociate from the blocking site until after the channel opens. The ability of the closed channel to occlude Ba++ is used as an assay to study the channel's gating equilibrium in the blocked state. The blocked channel opens and closes in a voltage-dependent process similar to that of the unblocked channel. The presence of a Ba ion destabilizes the closed state of the blocked channel, however, by 1.5 kcal/mol. The results confirm that Ba ions block this channel by binding in the K+-conduction pathway. They further show that the blocking site is inaccessible to Ba++ from both the cytoplasmic and external solutions when the channel is closed.     

A derivative of amiloride blocks both the light-regulated and cyclic GMP-regulated conductances in rod photoreceptors

Vertebrate rod photoreceptors in the dark maintain an inward current across the outer segment membrane. The photoresponse results from a light-induced suppression of this dark current. The light-regulated current is not sensitive to either tetrodotoxin or amiloride, potent blockers of Na+ channels. Here, we report that a derivative of amiloride, 3',4'-dichlorobenzamil (DCPA), completely suppresses the dark current and light response recorded from rod photoreceptors. DCPA also blocks a cyclic GMP-activated current in excised patches of rod plasma membrane and a cGMP-induced Ca++ flux from rod disk membranes. These results are consistent with the notion that the Ca++ flux mechanism in the disk membrane and the light-regulated conductance in the plasma membrane are identical. DCPA also inhibits the Na/Ca exchange mechanism in intact rods, but at a 5-10-fold-higher concentration than is required to block the cGMP-activated flux and current. The blocking action of DCPA in 10 nM Ca++ is different from that in 1 mM Ca++, which suggests either that the conductance state of the light-regulated channel may be modified in high and low concentrations of Ca++, or that there may be two ionic channels in the rod outer segment membrane.     

Rat ovarian and adrenal prolactin receptors. Sizes and effects of divalent metal ions

Receptor fractions were prepared from follicle-rich ovaries (for FSH), luteal cell-rich ovaries (for LH and PRL), and adrenals (for PRL) of rats. Divalent metal ions, Mg++, Ca++, and Mn++ showed inhibitory effects on the binding of LH and FSH to their receptors. The binding of the former was more sensitive to these ions than the latter. On the other hand they showed bell-shaped promotive effects on PRL-ovarian receptor binding, the maximal effects being observed at 10-20 mM. Besides these ions, Ba++ also had a promotive effect, while other divalent metal ions such as Zn++, Cd++, Ni++, and Co++ showed inhibitory effects on PRL-ovarian receptor binding at 5 mM. Mg++ and Ca++ also promoted PRL-adrenal receptor binding, while Mn++ promoted the binding at 10 mM but inhibited it at higher concentrations. Association constant (Ka) and binding capacity (Bmax) of PRL receptors of the ovary and the adrenal were significantly different (ovary: Ka = 0.69 X 10(10) M-1, Bmax = 62 fmol/mg protein, adrenal: Ka = 0.21 X 10(10) M-1, Bmax = 99 fmol/mg protein). Ka of the ovarian PRL receptor was not influenced by these divalent ions, while that of the adrenal receptor was doubled by Ca and Mn ions, Bmax of the latter was also increased. A cooperative effect of Mg and Ca ions was observed on Ka and Bmax of the adrenal receptor. The sizes of the PRL binding sites of these organs revealed by affinity labelling were 17K and 40K in the ovary, and 40K and 110K in the adrenal. These results indicate the different properties of receptors in these different target organs.