The Ca2+ channel beta3 subunit differentially modulates G-protein sensitivity of alpha1A and alpha1B Ca2+ channels

We have shown previously that the Ca2+ channel beta3 subunit is capable of modulating tonic G-protein inhibition of alpha1A and alpha1B Ca2+ channels expressed in oocytes. Here we determine the modulatory effect of the Ca2+ channel beta3 subunit on M2 muscarinic receptor-activated G-protein inhibition and whether the beta3 subunit modulates the G-protein sensitivity of alpha1A and alpha1B currents equivalently. To compare the relative inhibition by muscarinic activation, we have used successive ACh applications to remove the large tonic inhibition of these channels. We show that the resulting rebound potentiation results entirely from the loss of tonic G-protein inhibition; although the currents are temporarily relieved of tonic inhibition, they are still capable of undergoing inhibition through the muscarinic pathway. Using this rebound protocol, we demonstrate that the inhibition of peak current amplitude produced by M2 receptor activation is similar for alpha1A and alpha1B calcium currents. However, the contribution of the voltage-dependent component of inhibition, characterized by reduced inhibition at very depolarized voltage steps and the relief of inhibition by depolarizing prepulses, was slightly greater for the alpha1B current than for the alpha1A current. After co-expression of the beta3 subunit, the sensitivity to M2 receptor-induced G-protein inhibition was reduced for both alpha1A and alpha1B currents; however, the reduction was significantly greater for alpha1A currents. Additionally, the difference in the voltage dependence of inhibition of alpha1A and alpha1B currents was heightened after co-expression of the Ca2+ channel beta3 subunit. Such differential modulation of sensitivity to G-protein modulation may be important for fine tuning release in neurons that contain both of these Ca2+ channels.     

Contrasting biophysical and pharmacological properties of T-type and R-type calcium channels

In contrast to other kinds of voltage-gated Ca2+ channels, the underlying molecular basis of T-type and R-type channels is not well-understood. To facilitate comparisons with cloned Ca2+ channel subunits, we have carried out a systematic analysis of the properties of T-type currents in undifferentiated NG108-15 cells and R-type currents in cerebellar granule neurons. Marked differences were found in their biophysical and pharmacological features under identical recording conditions. T-type channels became activated at potentials approximately 25 mV more negative than R-type channels; however, T-type channels required potentials approximately 15 mV less negative than R-type channels to be available. Accordingly, T-type channels display a much larger overlap between the curves describing inactivation and activation, making them more suitable for generating sustained Ca2+ entry in support of secretion or pacemaker activity. In contrast, R-type channels are not equipped to provide a steady current, but are very capable of supplying transient surges of Ca2+ influx. In response to a series of increasingly strong depolarizations T-type and R-type Ca2+ channels gave rise to very different kinetic patterns. T-type current records crossed each other in a characteristic pattern not found for R-type currents. These biophysical distinctions were independent of absolute membrane potential and were, therefore, complementary to the conventional categorization of T- and R-type Ca2+ channels as low- and high-voltage activated. R-type channels deactivated approximately eight-fold more quickly than T-type channels, with clear consequences for the generation of divalent cation influx during simulated action potentials. Pharmacological comparisons revealed additional contrasts. R-type current was responsive to block by omega-Aga IIIA but not nimodipine, while the opposite was true for T-type current. Both channel types were potently inhibited by the non-dihydropyridine compound mibefradil. In all respects examined, R-type currents were similar to currents derived from expression of the alpha1E subunit whereas T-type currents were not.     

Molecular diversity of the calcium channel alpha2delta subunit

Sequence database searches with the alpha2delta subunit as probe led to the identification of two new genes encoding proteins with the essential properties of this calcium channel subunit. Primary structure comparisons revealed that the novel alpha2delta-2 and alpha2delta-3 subunits share 55.6 and 30.3% identity with the alpha2delta-1 subunit, respectively. The number of putative glycosylation sites and cysteine residues, hydropathicity profiles, and electrophysiological character of the alpha2delta-3 subunit indicates that these proteins are functional calcium channel subunits. Coexpression of alpha2delta-3 with alpha1C and cardiac beta2a or alpha1E and beta3 subunits shifted the voltage dependence of channel activation and inactivation in a hyperpolarizing direction and accelerated the kinetics of current inactivation. The kinetics of current activation were altered only when alpha2delta-1 or alpha2delta-3 was expressed with alpha1C. The effects of alpha2delta-3 on alpha1C but not alpha1E are indistinguishable from the effects of alpha2delta-1. Using Northern blot analysis, it was shown that alpha2delta-3 is expressed exclusively in brain, whereas alpha2delta-2 is found in several tissues. In situ hybridization of mouse brain sections showed mRNA expression of alpha2delta-1 and alpha2delta-3 in the hippocampus, cerebellum, and cortex, with alpha2delta-1 strongly detected in the olfactory bulb and alpha2delta-3 in the caudate putamen.     

T-type Ca2+ channels and pharmacological blockade: potential pathophysiological relevance

Low-voltage-activated T-type Ca2+ channels are present in most excitable tissues including the heart (mainly pacemaker cells), smooth muscle, central and peripheral nervous systems, and endocrine tissues, but also in non-excitable cells, such as osteoblasts, fibroblasts, glial cells, etc. Although they comprise a slightly heterogeneous population, these channels share many defining characteristics: small conductance (< 10 pS), similar Ca2+ and Ba2+ permeabilities, slow deactivation, and a voltage-dependent inactivation rate. In addition, activation at low voltages, rapid inactivation, and blockade by Ni2+ are classical properties of T-type Ca2+ channels, which are less specific. T-type Ca2+ channels are weakly blocked by standard Ca2+ antagonists. Pharmacological blockers are scarce and often lack specificity and/or potency. The physiological modulation of T-type Ca2+ currents is complex: they are enhanced by endothelin-1, angiotensin II (AT1-receptor), ATP, and isoproterenol (cAMP-independent), but are reduced by angiotensin II (AT2-receptor), somatostatin and atrial natriuretic peptide. Norepinephrine enhances these currents in some cells but decreases them in others. T-type Ca2+ currents have many known or suggested physiological and pathophysiological roles in growth (protein synthesis, cell differentiation, and proliferation), neuronal firing regulation, some aspects of genetic hypertension, cardiac hypertrophy, cardiac fibrosis, cardiac rhythm (normal and abnormal), and atherosclerosis. Mibefradil is a new Ca2+ antagonist that is effective in hypertension and angina pectoris. Its favorable pharmacological profile and limited side effects appear to be related to selective block of T-type Ca2+ channels: mibefradil reduces vascular resistance and heart rate without negative inotropy or neurohormonal stimulation, and it also has significant antiproliferative actions.     

Identification of the amino terminus of neuronal Ca2+ channel alpha1 subunits alpha1B and alpha1E as an essential determinant of G-protein modulation

We have examined the basis for G-protein modulation of the neuronal voltage-dependent calcium channels (VDCCs) alpha1E and alpha1B. A novel PCR product of alpha1E was isolated from rat brain. This contained an extended 5' DNA sequence and was subcloned onto the previously cloned isoform rbEII, giving rise to alpha1Elong whose N terminus was extended by 50 amino acids. VDCC alpha1 subunit constructs were co-expressed with the accessory alpha2-delta and beta2a subunits in Xenopus oocytes and mammalian (COS-7) cells. The alpha1Elong showed biophysical properties similar to those of rbEII; however, when G-protein modulation of expressed alpha1 subunits was induced by activation of co-expressed dopamine (D2) receptors with quinpirole (100 nM) in oocytes, or by co-transfection of Gbeta1gamma2 subunits in COS-7 cells, alpha1Elong, unlike alpha1E(rbEII), was found to be G-protein-modulated, in terms of both a slowing of activation kinetics and a reduction in current amplitude. However, alpha1Elong showed less modulation than alpha1B, and substitution of the alpha1E1-50 with the corresponding region of alpha1B1-55 produced a chimera alpha1bEEEE, with G-protein modulation intermediate between alpha1Elong and alpha1B. Furthermore, deletion of the N-terminal 1-55 sequence from alpha1B produced alpha1BDeltaN1-55, which could not be modulated, thus identifying the N-terminal domain as essential for G-protein modulation. Taken together with previous studies, these results indicate that the intracellular N terminus of alpha1E1-50 and alpha1B1-55 is likely to contribute to a multicomponent site, together with the intracellular I-II loop and/or the C-terminal tail, which are involved in Gbetagamma binding and/or in subsequent modulation of channel gating.     

G-Protein-dependent facilitation of neuronal alpha1A, alpha1B, and alpha1E Ca channels

Modulation of neuronal voltage-gated Ca channels has important implications for synaptic function. To investigate the mechanisms of Ca channel modulation, we compared the G-protein-dependent facilitation of three neuronal Ca channels. alpha1A, alpha1B, or alpha1E subunits were transiently coexpressed with alpha2-deltab and beta3 subunits in HEK293 cells, and whole-cell currents were recorded. After intracellular dialysis with GTPgammaS, strongly depolarized conditioning pulses facilitated currents mediated by each Ca channel type. The magnitude of facilitation depended on current density, with low-density currents being most strongly facilitated and high-density currents often lacking facilitation. Facilitating depolarizations speeded channel activation approximately 1.7-fold for alpha1A and alpha1B and increased current amplitudes by the same proportion, demonstrating equivalent facilitation of G-protein-inhibited alpha1A and alpha1B channels. Inactivation typically obscured facilitation of alpha1E current amplitudes, but the activation kinetics of alpha1E currents showed consistent and pronounced G-protein-dependent facilitation. The onset and decay of facilitation had the same kinetics for alpha1A, alpha1B, and alpha1E, suggesting that Gbeta gamma dimers dissociate from and reassociate with these Ca channels at very similar rates. To investigate the structural basis for N-type Ca channel modulation, we expressed a mutant of alpha1B missing large segments of the II-III loop and C terminus. This deletion mutant exhibited undiminished G-protein-dependent facilitation, demonstrating that a Gbeta gamma interaction site recently identified within the C terminus of alpha1E is not required for modulation of alpha1B.     

Mechanism of auxiliary subunit modulation of neuronal alpha1E calcium channels

Voltage-gated calcium channels are composed of a main pore-forming alpha1 moiety, and one or more auxiliary subunits (beta, alpha2 delta) that modulate channel properties. Because modulatory properties may vary greatly with different channels, expression systems, and protocols, it is advantageous to study subunit regulation with a uniform experimental strategy. Here, in HEK 293 cells, we examine the expression and activation gating of alpha1E calcium channels in combination with a beta (beta1-beta4) and/or the alpha2 delta subunit, exploiting both ionic- and gating-current measurements. Furthermore, to explore whether more than one auxiliary subunit can concomitantly specify gating properties, we investigate the effects of cotransfecting alpha2delta with beta subunits, of transfecting two different beta subunits simultaneously, and of COOH-terminal truncation of alpha1E to remove a second beta binding site. The main results are as follows. (a) The alpha2delta and beta subunits modulate alpha1E in fundamentally different ways. The sole effect of alpha2 delta is to increase current density by elevating channel density. By contrast, though beta subunits also increase functional channel number, they also enhance maximum open probability (Gmax/Qmax) and hyperpolarize the voltage dependence of ionic-current activation and gating-charge movement, all without discernible effect on activation kinetics. Different beta isoforms produce nearly indistinguishable effects on activation. However, beta subunits produced clear, isoform-specific effects on inactivation properties. (b) All the beta subunit effects can be explained by a gating model in which subunits act only on weakly voltage-dependent steps near the open state. (c) We find no clear evidence for simultaneous modulation by two different beta subunits. (d) The modulatory features found here for alpha1E do not generalize uniformly to other alpha1 channel types, as alpha1C activation gating shows marked beta isoform dependence that is absent for alpha1E. Together, these results help to establish a more comprehensive picture of auxiliary-subunit regulation of alpha1E calcium channels.     

Hair cell-specific splicing of mRNA for the alpha1D subunit of voltage-gated Ca2+ channels in the chicken's cochlea

The L-type voltage-gated Ca2+ channels that control tonic release of neurotransmitter from hair cells exhibit unusual electrophysiological properties: a low activation threshold, rapid activation and deactivation, and a lack of Ca2+-dependent inactivation. We have inquired whether these characteristics result from cell-specific splicing of the mRNA for the L-type alpha1D subunit that predominates in hair cells of the chicken's cochlea. The alpha1D subunit in hair cells contains three uncommon exons: one encoding a 26-aa insert in the cytoplasmic loop between repeats I and II, an alternative exon for transmembrane segment IIIS2, and a heretofore undescribed exon specifying a 10-aa insert in the cytoplasmic loop between segments IVS2 and IVS3. We propose that the alternative splicing of the alpha1D mRNA contributes to the unusual behavior of the hair cell's voltage-gated Ca2+ channels.     

Modulation of cardiac sodium current by alpha1-stimulation and volatile anesthetics

BACKGROUND: Alpha1-adrenoceptor stimulation is known to produce electrophysiologic changes in cardiac tissues, which may involve modulations of the fast inward Na+ current (I(Na)). A direct prodysrhythmic alpha1-mediated interaction between catecholamines and halothane has been demonstrated, supporting the hypothesis that generation of halothane-epinephrine dysrhythmias may involve slowed conduction, leading to reentry. In this study, we examined the effects of a selective alpha1-adrenergic receptor agonist, methoxamine, on cardiac I(Na) in the absence and presence of equianesthetic concentrations of halothane and isoflurane in single ventricular myocytes from adult guinea pig hearts. METHODS: I(Na) was recorded using the standard whole-cell configuration of the patch-clamp technique. Voltage clamp protocols initiated from two different holding potentials (V(H)) were applied to examine state-dependent effects of methoxamine in the presence of anesthetics. Steady state activation and inactivation and recovery from inactivation were characterized using standard protocols. RESULTS: Methoxamine decreased I(Na) in a concentration- and voltage-dependent manner, being more potent at the depolarized V(H). Halothane and isoflurane interacted synergistically with methoxamine to suppress I(Na) near the physiologic cardiac resting potential of -80 mV. The effect of methoxamine with anesthetics appeared to be additive when using a V(H) of -110 mV, a potential where no Na+ channels are in the inactivated state. Methoxamine in the absence and presence of anesthetics significantly shifted the half maximal inactivation voltage in the hyperpolarizing direction but had no effect on steady-state activation. CONCLUSION: The present results show that methoxamine (alpha1-adrenergic stimulation) decreases cardiac Na+ current in a concentration- and voltage-dependent manner. Further, a form of synergistic interaction between methoxamine and inhalational anesthetics, halothane and isoflurane, was observed. This interaction appears to depend on the fraction of Na+ channels in the inactivated state. (Key words: Anesthetics, volatile: halothane; isoflurane; methoxamine. Patch clamp: whole-cell configuration; sodium current; ventricular guinea pig myocytes.)     

Antisense oligonucleotides against alpha1E reduce R-type calcium currents in cerebellar granule cells

Many neurons of the central nervous system display multiple high voltage-activated Ca2+ currents, pharmacologically classified as L-, N-, P-, Q-, and R-type. Of these current types, the R-type is the least understood. The leading candidate for the molecular correlate of R-type currents in cerebellar granule cells is the alpha1E subunit, which yields Ca2+ currents very similar to the R-type when expressed in heterologous systems. As a complementary approach, we tested whether antisense oligonucleotides against alpha1E could decrease the expression of R-type current in rat cerebellar granule neurons in culture. Cells were supplemented with either antisense or sense oligonucleotides and whole-cell patch clamp recordings were obtained after 6-8 days in vitro. Incubation with alpha1E antisense oligonucleotide caused a 52.5% decrease in the peak R-type current density, from -10 +/- 0.6 picoamperes/picofarad (pA/pF) (n = 6) in the untreated controls to -4.8 +/- 0.8 pA/pF (n = 11) (P < 0.01). In contrast, no significant changes in the current expression were seen in sense oligonucleotide-treated cells (-11.3 +/- 3.2 pA/pF). The specificity of the alpha1E antisense oligonucleotides was supported by the lack of change in estimates of the P/Q current amplitude. Furthermore, antisense and sense oligonucleotides against alpha1A did not affect R-type current expression (-11.5 +/- 1.7 and -11.7 +/- 1.7 pA/pF, respectively), whereas the alpha1A antisense oligonucleotide significantly reduced whole cell currents under conditions in which P/Q current is dominant. Our results support the hypothesis that members of the E class of alpha1 subunits support the high voltage-activated R-type current in cerebellar granule cells.     

Two types of TTX-resistant and one TTX-sensitive Na+ channel in rat dorsal root ganglion neurons and their blockade by halothane

The clinically employed general anaesthetic halothane was shown to exert action on the peripheral nervous system by suppressing spinal reflexes, but it is still unclear which mechanisms underlie this action. The present study addressed the question whether blockade of tetrodotoxin-sensitive (TTXs) and -resistant (TTXr) Na+-channels in rat dorsal root ganglia (DRG) neurons by halothane could explain its peripheral effects. Two types of TTXr Na+-currents, fast and slow, with distinct activation and inactivation kinetics were found in small (< 25 micrometer) and medium sized (25-40 micrometer) DRG neurons. These currents were blocked by halothane with IC50 values of 5.4 and 7.4 mmol/L, respectively. Additionally, in a concentration-dependent manner halothane accelerated the inactivation kinetics of both currents and shifted the inactivation curves to more hyperpolarized potentials. Neither the activation curves of both TTXr Na+-currents were influenced by halothane nor a voltage-dependent block at test potentials of the currents was seen. In contrast to that of fast current, the time-to-peak for slow current was changed in the presence of halothane. The TTXs Na+-current which prevailed in large neurons (> 40 micrometer) was blocked by halothane with an IC50 of 12.1 mmol/L. Its inactivation curve was also shifted to more hyperpolarized potentials and the inactivation kinetics accelerated with increasing halothane concentration. Similarly to TTXr Na+-currents, the activation curve of TTXs Na+-current and its time-to-peak were not influenced by halothane. It is suggested that two types of TTXr Na+-currents can explain the heterogeneity in kinetic data for TTXr Na+-currents. Furthermore, the incomplete blockade of Na+-currents might underlie the incomplete reduction of spinal reflexes at clinically used concentrations of halothane.     

An electrophysiological study of the postnatal development of the corticospinal system in the macaque monkey

We characterized toxin-insensitive calcium currents expressed by acutely dissociated embryonic dorsal root ganglion neurons. In the presence of 3 microM omega-conotoxin-GVIA, 3 microM nitrendipine and either 500 nM omega-agatoxin-IVA or 500 nM omega-conotoxin-MVIIC to inhibit N-, L- and P/Q-type currents, respectively, all neurons expressed two residual currents: a T-type and another which we referred to as toxin-resistant current. The toxin-resistant current (i) consisted of an inactivating and a sustained components, (ii) had a threshold of activation and a steady-state inactivation comprised between that of the T-type current and that of the other high-voltage-activated currents, (iii) had the same permeability for barium and calcium used as charge carriers, (iv) was highly sensitive to both cadmium and nickel; and (v) was insensitive to 500 microM amiloride which abolished the T-type at this concentration. The properties of the toxin-resistant current are very similar to those of the currents expressed in oocytes following injection of alpha(1E) subunits which we demonstrated to be present in these neurons. Therefore a component of the toxin-resistant current calcium channels in sensory neurons may be closely related to those calcium channels formed by alpha(1E) subunits.     

Inactivation of macroscopic late Na+ current and characteristics of unitary late Na+ currents in sensory neurons

Na+ currents in adult rat large dorsal root ganglion neurons were recorded during long duration voltage-clamp steps by patch clamping whole cells and outside-out membrane patches. Na+ current present >60 ms after the onset of a depolarizing pulse (late Na+ current) underwent partial inactivation; it behaved as the sum of three kinetically distinct components, each of which was blocked by nanomolar concentrations of tetrodotoxin. Inactivation of one component (late-1) of the whole cell current reached equilibrium during the first 60 ms; repolarizing to -40 or -50 mV from potentials of -30 mV or more positive gave rise to a characteristic increase in current (tau >/= 5 ms), attributed to removal of inactivation. A second component (late-2) underwent slower inactivation (tau > 80 ms) at potentials more positive than -80 mV, and steady-state inactivation appeared complete at -30 mV. In small membrane patches, bursts of brief openings (gamma = 13-18 pS) were usually recorded. The distribution of burst durations indicated that two populations of channel were present with inactivation rates corresponding to late-1 and late-2 macroscopic currents. The persistent Na+ current in the whole cell that extended to potentials more positive than -30 mV appeared to correspond to sporadic, brief openings that were recorded in patches (mean open time approximately 0.1 ms) over a wide potential range. None of the three types of gating described corresponded to activation/inactivation gating overlap of fast transient currents.     

Depolarization shifts the voltage dependence of cardiac sodium channel and calcium channel gating charge movements

In cardiac ventricular myocytes, membrane depolarization leads to the inactivation of the Na channel and Ca channel ionic currents. The inactivation of the ionic currents has been associated with a reduction of the gating charge movement ("immobilization") which governs the activation of Na channels and Ca channels. The nature of the apparent "immobilization" of the charge movement following depolarization was explored in embryonic chick ventricular myocytes using voltage protocols applied from depolarized holding potentials. It was found that although all of the charge was mobile following inactivation, the voltage dependence of its movement was shifted to more negative potentials. In addition, the shift in the distribution of the Na channel charge could be differentiated from that of the Ca channel charge on the basis of kinetic as well as steady-state criteria. These results suggest that the voltage-dependent activation of Na channel and Ca channel charge movements leads to conformational changes and charge rearrangements that differentially bias the movements of these voltage sensors, and concomitantly produce channel inactivation.     

Expression environment determines K+ current properties: Kv1 and Kv4 alpha-subunit-induced K+ currents in mammalian cell lines and cardiac myocytes

Voltage-gated K+ channel (Kv) pore-forming (alpha) subunits of the Kv1 and Kv4 subfamilies have been cloned from heart cDNA libraries, and are thought to play roles in the generation of the transient outward K+ current, Ito. Heterologous expression of these subunits in Xenopus oocytes, however, reveals K+ currents that are quite distinct from Ito. In the experiments here, the detailed time- and voltage-dependent properties of the currents expressed in mammalian cell lines and in cardiac myocytes by Kv1.4 and Kv4.2 were examined and compared to previous findings in studies of oocytes, as well as to Ito characterized in various myocardial cells. As in oocytes, expression of Kv1.4 in HEK-293, Ltk- or neonatal rat ventricular cells reveals rapidly activating K+ currents. In contrast to the currents in oocytes, however, there are two components of inactivation of the Kv1.4-induced currents in mammalian cells, and both components are significantly slower in myocytes than in either HEK-293 or Ltk- cells. In addition, in all three cell types, recovery of Kv1.4 from steady-state inactivation is very slow, proceeding with mean time constants in the range of 6-8 s. The properties of Kv4.2-induced currents also vary with cell type and, importantly, the rates of activation, inactivation and recovery from inactivation are significantly faster in mammalian cells than in Xenopus oocytes. In HEK-293, Chinese hamster ovary (CHO) and neonatal rat ventricular cells, for example, the currents recover from steady-state inactivation with mean (+/-SD) time constants of 153+/-32 (n=12), 245+/-112 (n=10) and 86+/-38 (n=11) ms, respectively; therefore, recovery proceeds 5-10 times faster than observed for Kv4.2 in oocytes. These results emphasize the importance of the cellular expression environment in efforts to correlate endogenous K+ currents with heterologously expressed K+ channel subunits. In addition, the finding that Kv alpha subunits produce distinct K+ currents in different cells suggests that cell-type-specific associations with endogenous Kv alpha or accessory beta subunits and/or post-translational processing play roles in determining the properties of functional K+ channels.     

Impact of knowledge and age on tip-of-the-tongue rates

The modulation of IA K+ current by ten trivalent lanthanide (Ln3+) cations spanning the series with ionic radii ranging from 0.99 A to 1.14 A was characterized by the whole-cell patch clamp technique in bovine adrenal zona fasciculata (AZF) cells. Each of the ten Ln3+s reduced IA amplitude measured at +20 mV in a concentration-dependent manner. Smaller Ln3+s were the most potent and half-maximally effective concentrations (EC50s) varied inversely with ionic radius for the larger elements. Estimation of EC50s yielded the following potency sequence: Lu3+ (EC50 = 3.0 microM) approximately Yb3+ (EC50 = 2.7 microM) > Er3+ (EC50 = 3.7 microM) >/= Dy3+ (EC50 = 4.7 microM) > Gd3+ (EC50 = 6.7 microM) approximately Sm3+ (EC50 = 6.9 microM) > Nd3+ (EC50 = 11.2 microM) > Pr3+ (EC50 = 22.3 microM) > Ce3+ (EC50 = 28.0 microM) > La3+ (EC50 = 33.7 microM). Ln3+s altered selected voltage-dependent gating and kinetic parameters of IA with a potency and order of effectiveness that paralleled the reduction of IA amplitude. Ln3+s markedly slowed activation kinetics and shifted the voltage-dependence of IA gating such that activation and steady-state inactivation occurred at more depolarized potentials. In contrast, Ln3+s did not measurably alter inactivation or deactivation kinetics and only slightly slowed kinetics of inactivated channels returning to the closed state. Replacement of external Ca2+ with Mg2+ had no effect on the concentration-dependent inhibition of IA by Ln3+s. In contrast to their action on IA K+ current, Ln3+s inhibited T-type Ca2+ currents in AZF cells without slowing activation kinetics. These results indicate that Ln3+ modulate IA K+ channels through binding to a site on IA channels located within the electric field but which is not specific for Ca2+. They are consistent with a model where Ln3+ binding to negative charges on the gating apparatus alters the voltage-dependence and kinetics of channel opening. Ln3+s modulate transient K+ and Ca2+ currents by two fundamentally different mechanisms.     

Voltage-operated potassium currents in the somatic membrane of rat dorsal root ganglion neurons: ontogenetic aspects

Whole-cell transmembrane potassium currents were studied in somatic membrane of freshly isolated rat dorsal root ganglion neurons. We defined three types of potassium currents, which were separated on the basis of their different potential dependence of activation and sensitivity to external tetraethylammonium and 4-aminopyridine. The potential dependence of kinetic and steady-state properties of a fast inactivating potassium current, a slow inactivating potassium current and a non-inactivating delayed rectifier current were described by the Hodgkin-Huxley equations. A transient fast inactivating potassium current was activated at the most negative membrane potentials and was not reduced in the presence of 10 mM tetraethylammonium in the external solution. 4-Aminopyridine (2 mM) caused an 80% inhibition of this current. The activation of the fast inactivating potassium current was properly described by fitting a single exponent raised to the fourth power. The time constant of activation changed from 4 to 1 ms in the voltage range between -30 and +40 mV. The time constant of inactivation decreased from 35 to 15 ms over the same range of potentials. Parameters for the fit of a Boltzmann equation to mean values for steady-state activation were V1/2=-20mV, k=11.8mV, and for steady-state inactivation V1/2= -85 mV, k=-9.8 mV. A transient slow inactivating potassium current had an activation threshold between -40 and -30 mV. At 2 mM 4-aminopyridine, the depression of the slow potassium current was 55%. The extracellular application of 10 mM tetraethylammonium was less effective and evoked a 40% reduction. The activation of the slow inactivating potassium current was also described by a single exponential function raised to the fourth power. The time constant of activation decreased from 12 ms at a membrane potential of -10 mV to 4 ms at the potential of 60 mV. The inactivation of slow inactivating potassium current was described by two exponents. The time constant for the fast exponent ranged from 300 ms at -20 mV to 160 ms at +60 mV. The slower exponent was also potential dependent and its time constant ranged from approximately 2600 to 1600 ms over the same potentials. Parameters for the Boltzmann equation fittings to mean values were V1/2= -12.8 mV, k=13.4 mV and V1/2= -54.6 mV, k= -12 mV for steady-state activation and inactivation, respectively. A non-inactivating delayed rectifier potassium current was activated at the most positive membrane potentials. This non-inactivating current did not change in the presence of 4-aminopyridine. Extracellular tetraethylammonium (10 mM) caused a 70% reduction of this current. The activation of the non-inactivating potassium current was described by one exponent raised to the fourth power. The time constant for activation ranged from 85 ms at -5 mV to 30 ms at 45 mV. No time-dependent inactivation was observed during 15-s testing potentials in the voltage range between 10 and +60 mV. The activation behavior was characterized by V1/2=15.3 mV, k=12.5 mV. The densities of these potassium currents were studied for three groups of animals: one, five to six and 14-15 days of postnatal development. Fifty cells were examined in each age group. All three types of potassium currents were found in each investigated neuron. The mean densities of slow and fast inactivating potassium currents increased during ontogenetic development. The densities of non-inactivating delayed rectifier potassium current decreased in the first week of ontogenetic development and did not change thereafter.     

P2 receptor modulation of voltage-gated potassium currents in Brown adipocytes

Using patch voltage-clamp techniques, we find there are two components to the voltage-gated potassium current (IKv) in rat brown adipocytes. The components differ in their gating and responses to purinergic stimulation, but not their pharmacology. IKv-A recovers from inactivation at physiological membrane potentials, while IKv-B inactivation recovers at more negative potentials. Both currents are >90% blocked by similar concentrations of quinine and tetraethylammonium, but not by beta-dendrotoxin, charybdotoxin, or apamin. The two current components are differentially modulated by extracellular ATP. ATP shifts the voltage dependence of IKv-A inactivation negative by 38 +/- 5 mV (n = 35, +/-SEM) and shifts activation by -14 +/- 2 mV in whole-cell experiments. ATP did not affect the steady state inactivation voltage dependence of IKv-B, but did apparently convert IKv-A into IKv-B. The pharmacology of the inactivation shift is consistent with mediation by a P2 purinergic receptor. Purinergic stimulation of perforated-patch clamped cells causes hyperpolarizing shifts in the window current of IKv-A by shifting inactivation -18 +/- 4 mV and activation -7 +/- 2 mV (n = 16). Since perforated-patch recordings will most closely resemble in vivo cell responses, this ATP-induced shift in the window current may facilitate IKv activation when the cell depolarizes. IKv activity is necessary for the proliferation and differentiation of brown adipocytes in culture (Pappone, P.A., and S.I. Ortiz-Miranda. 1993. Am. J. Physiol. 264:C1014-C1019) so purinergic modulation of IKv may be important in altering adipocyte growth and development.     

Presteady-state currents of the rabbit Na+/glucose cotransporter (SGLT1)

The rabbit Na+/glucose cotransporter (SGLT1) exhibits a presteady-state current after step changes in membrane voltage in the absence of sugar. These currents reflect voltage-dependent processes involved in cotransport, and provide insight on the partial reactions of the transport cycle. SGLT1 presteady-state currents were studied as a function of external Na+, membrane voltage Vm, phlorizin and temperature. Step changes in membrane voltage-from the holding Vh to test values, elicited transient currents that rose rapidly to a peak (at 3-4 msec), before decaying to the steady state, with time constants tau approximately 4-20 msec, and were blocked by phlorizin (Ki approximately 30 microm). The total charge Q was equal for the application of the voltage pulse and the subsequent removal, and was a function of Vm. The Q-V curves obeyed the Boltzmann relation: the maximal charge Qmax was 4-120 nC; V0.5, the voltage for 50% Qmax was -5 to +30 mV; and z, the apparent valence of the moveable charge, was 1. Qmax and z were independent of Vh (between 0 and -100 mV) and temperature (20-30 degrees C), while increasing temperature shifted V0.5 towards more negative values. Decreasing [Na+]o decreased Qmax, and shifted V0.5 to more negative voltages 9by -100 mV per 10-fold decrease in [Na+]o). The time constant tau was voltage dependent: the tau-V relations were bell-shaped, with maximal taumax 8-20 msec. Decreasing [Na+]o decreased taumax, and shifted the tau-V curves towards more negative voltages. Increasing temperature also shifted the tau-V curves, but did not affect taumax. The maximum temperature coefficient Q10 for tau was 3-4, and corresponds to an activation energy of 25 kcal/mole. Simulations of a 6-state ordered kinetic model for rabbit Na+/glucose cotransport indicate that charge-movements are due to Na+-binding/dissociation and a conformational change of the empty transporter. The model predicts that (i) transient currents rise to a peak before decay to steady-state; (ii) the tau-V relations are bell-shaped, and shift towards more negative voltages as [Na+]o is reduced; (iii) taumax is decreased with decreasing [Na+]o; and (iv) the Q-V relations are shifted towards negative voltages as [Na+]o is reduced. In general, the kinetic properties of the presteady-state currents are qualitatively predicted by the model.