Differential interactions of the C terminus and the cytoplasmic I-II loop of neuronal Ca2+ channels with G-protein alpha and beta gamma subunits. I. Molecular determination

Interactions of G-protein alpha (Galpha) and beta gamma subunits (Gbeta gamma) with N- (alpha1B) and P/Q-type (alpha1A) Ca2+ channels were investigated using the Xenopus oocyte expression system. Gi3alpha was found to inhibit both N- and P/Q-type channels by receptor agonists, whereas Gbeta1 gamma2 was responsible for prepulse facilitation of N-type channels. L-type channels (alpha1C) were not regulated by Galpha or Gbeta gamma. For N-type, prepulse facilitation mediated via Gbeta gamma was impaired when the cytoplasmic I-II loop (loop 1) was deleted or replaced with the alpha1C loop 1. Galpha-mediated inhibitions were also impaired by substitution of the alpha1C loop 1, but only when the C terminus was deleted. For P/Q-type, by contrast, deletion of the C terminus alone diminished Galpha-mediated inhibition. Moreover, a chimera of L-type with the alpha1B loop 1 gained Gbeta gamma-dependent facilitation, whereas an L-type chimera with the N- or P/Q-type C terminus gained Galpha-mediated inhibition. These findings provide evidence that loop 1 of N-type channels is a regulatory site for Gbeta gamma and the C termini of P/Q- and N-types for Galpha.     

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.     

Differential interactions of the C terminus and the cytoplasmic I-II loop of neuronal Ca2+ channels with G-protein alpha and beta gamma subunits. II. Evidence for direct binding

The present study was designed to obtain evidence for direct interactions of G-protein alpha (Galpha) and beta gamma subunits (Gbeta gamma) with N- (alpha1B) and P/Q-type (alpha1A) Ca2+ channels, using synthetic peptides and fusion proteins derived from loop 1 (cytoplasmic loop between repeat I and II) and the C terminus of these channels. For N-type, prepulse facilitation as mediated by Gbeta gamma was impaired when a synthetic loop 1 peptide was applied intracellularly. Receptor agonist-induced inhibition of N-type as mediated by Galpha was also impaired by the loop 1 peptide but only when applied in combination with a C-terminal peptide. For P/Q-type channels, by contrast, the Galpha-mediated inhibition was diminished by application of a C-terminal peptide alone. Moreover, in vitro binding analysis for N- and P/Q-type channels revealed direct interaction of Galpha with C-terminal fusion proteins as well as direct interaction of Gbeta gamma with loop 1 fusion proteins. These findings define loop 1 of N- and P/Q-type Ca2+ channels as an interaction site for Gbeta gamma and the C termini for Galpha.     

The alpha 1E calcium channel exhibits permeation properties similar to low-voltage-activated calcium channels

The physiological and pharmacological properties of the alpha 1E calcium (Ca) channel subtype do not exactly match any of the established categories described for native neuronal Ca currents. Many of the key diagnostic features used to assign cloned Ca channels to their native counterparts, however, are dependent on a number of factors, including cellular environment, beta subunit coexpression, and modulation by second messengers and G-proteins. Here, by examining the intrinsic pore characteristics of a family of transiently expressed neuronal Ca channels, we demonstrate that the permeation properties of alpha 1E closely resemble those described for a subset of low-threshold Ca channels. The alpha 1A (P-/Q-type), alpha 1B (N-type), and alpha 1C (L-type) high-threshold Ca channels all exhibit larger whole-cell currents with barium (Ba) as the charge carrier as compared with Ca or strontium (Sr). In contrast, macroscopic alpha 1E currents are largest in Sr, followed by Ca and then Ba. The unique permeation properties of alpha 1E are maintained at the single-channel level, are independent of the nature of the expression system, and are not affected by coexpression of alpha 2 and beta subunits. Overall, the permeation characteristics of alpha 1E are distinct from those described for R-type currents and share some similarities with native low-threshold Ca channels.     

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.     

Cloning and functional expression of a voltage-gated calcium channel alpha1 subunit from jellyfish

Voltage-gated Ca2+ channels in vertebrates comprise at least seven molecular subtypes, each of which produces a current with distinct kinetics and pharmacology. Although several invertebrate Ca2+ channel alpha1 subunits have also been cloned, their functional characteristics remain unclear, as heterologous expression of a full-length invertebrate channel has not previously been reported. We have cloned a cDNA encoding the alpha1 subunit of a voltage-gated Ca2+ channel from the scyphozoan jellyfish Cyanea capillata, one of the earliest existing organisms to possess neural and muscle tissue. The deduced amino acid sequence of this subunit, named CyCaalpha1, is more similar to vertebrate L-type channels (alpha1S, alpha1C, and alpha1D) than to non-L-type channels (alpha1A, alpha1B, and alpha1E) or low voltage-activated channels (alpha1G). Expression of CyCaalpha1 in Xenopus oocytes produces a high voltage-activated Ca2+ current that, unlike vertebrate L-type currents, is only weakly sensitive to 1,4-dihydropyridine or phenylalkylamine Ca2+ channel blockers and is not potentiated by the agonist S(-)-BayK 8644. In addition, the channel is less permeable to Ba2+ than to Ca2+ and is more permeable to Sr2+. CyCaalpha1 thus represents an ancestral L-type alpha1 subunit with significant functional differences from mammalian L-type channels.     

G-protein beta-subunit specificity in the fast membrane-delimited inhibition of Ca2+ channels

We investigated which subtypes of G-protein beta subunits participate in voltage-dependent modulation of N-type calcium channels. Calcium currents were recorded from cultured rat superior cervical ganglion neurons injected intranuclearly with DNA encoding five different G-protein beta subunits. Gbeta1 and Gbeta2 strongly mimicked the fast voltage-dependent inhibition of calcium channels produced by many G-protein-coupled receptors. The Gbeta5 subunit produced much weaker effects than Gbeta1 and Gbeta2, whereas Gbeta3 and Gbeta4 were nearly inactive in these electrophysiological studies. The specificity implied by these results was confirmed and extended using the yeast two-hybrid system to test for protein-protein interactions. Here, Gbeta1 or Gbeta2 coupled to the GAL4-activation domain interacted strongly with a channel sequence corresponding to the intracellular loop connecting domains I and II of a alpha1 subunit of the class B calcium channel fused to the GAL4 DNA-binding domain. In this assay, the Gbeta5 subunit interacted weakly, and Gbeta3 and Gbeta4 failed to interact. Together, these results suggest that Gbeta1 and/or Gbeta2 subunits account for most of the voltage-dependent inhibition of N-type calcium channels and that the linker between domains I and II of the calcium channel alpha1 subunit is a principal receptor for this inhibition.     

Structural features determining differential receptor regulation of neuronal Ca channels

Dihydropyridine-insensitive Ca channels are subject to direct receptor G-protein-mediated inhibition to differing extents. alpha1B channels are much more strongly modulated than alpha1E channels. To understand the structural basis for this difference, we have constructed and expressed various alpha1B and alpha1E chimeric Ca channels and examined their regulation by kappa-opioid receptors. Replacement of the first membrane-spanning domain of alpha1E with the corresponding region of alpha1B resulted in a chimeric Ca channel that was modulated by kappa-opioid receptors to a significantly greater extent than alpha1E. Transfer of the N terminus and I/II loop from alpha1B in addition to domain I resulted in a chimeric channel that was modulated to the same extent as alpha1B. Other regions of the molecule do not appear to contribute significantly to the degree of inhibition obtained, although the C terminus may contribute to facilitation.     

Run-down of L-type Ca2+ channels occurs on the alpha 1 subunit

Run-down of L-type Ca2+ channels in CHO cells stably expressing alpha 1c, alpha 1c beta 1a, or alpha 1c beta 1a alpha 2 delta gamma subunits was studied using the patch-clamp technique (single channel recording). The channel activity (NPo) of alpha 1c channels was increased 4- and 8-fold by coexpression with beta 1a and beta 1a alpha 2 delta gamma, respectively. When membranes containing channels composed of different subunits were excised into basic internal solution, the channel activity exhibited run-down, the time-course of which was independent of the subunit composition. The run-down was restored by the application of calpastatin (or calpastatin contained in cytoplasmic P-fraction) + H-fraction (a high molecular mass fraction of bovine cardiac cytoplasm) + 3 mM ATP, which has been shown to reverse the run-down in native Ca2+ channels in the guinea-pig heart. The restoration level was 64.7, 63.5, and 66.4% for channels composed of alpha 1c, alpha 1c beta 1a, and alpha 1c beta 1a alpha 2 delta gamma, respectively, and was thus also independent of the subunit composition. We conclude that run-down of L-type Ca2+ channels occurs via the alpha 1 subunit and that the cytoplasmic factors maintaining Ca2+ channel activity act on the alpha 1 subunit.     

Ca2+ channel beta3 subunit enhances voltage-dependent relief of G-protein inhibition induced by muscarinic receptor activation and Gbetagamma

The Ca2+ channel beta subunit has been shown to reduce the magnitude of G-protein inhibition of Ca2+ channels. However, neither the specificity of this action to different forms of G-protein inhibition nor the mechanism underlying this reduction in response is known. We have reported previously that coexpression of the Ca2+ channel beta3 subunit causes M2 muscarinic receptor-mediated inhibition of alpha1B Ca2+ currents to become more voltage-dependent. We report here that the beta3 subunit increases the rate of relief of inhibition produced by a depolarizing prepulse and also shifts the voltage dependency of this relief to more hyperpolarized voltages; these effects are likely to be responsible for the reduction of inhibitory response of alpha1B channels to G-protein-mediated inhibition seen after coexpression of the Ca2+ channel beta3 subunit. Additionally, the beta3 subunit alters the rate and voltage dependency of relief of the inhibition produced by coexpressed Gbeta1gamma1, in a manner similar to the changes it produces in relief of M2 receptor-induced inhibition. We conclude that the Ca2+ channel beta3 subunit reduces the magnitude of G-protein inhibition of alpha1B Ca2+ channels by enhancing the rate of dissociation of the G-protein betagamma subunit from the Ca2+ channel alpha1B subunit.     

Distribution of alpha 1A, alpha 1B and alpha 1E voltage-dependent calcium channel subunits in the human hippocampus and parahippocampal gyrus

The distribution of voltage-dependent calcium channel subunits in the central nervous system may provide information about the function of these channels. The present study examined the distribution of three alpha-1 subunits, alpha 1A, alpha 1B and alpha 1E, in the normal human hippocampal formation and parahippocampal gyrus using the techniques of in situ hybridization and immunocytochemistry. All three subunit mRNAs appeared to be similarly localized, with high levels of expression in the dentate granule and CA pyramidal layer. At the protein level, alpha 1A, alpha 1B and alpha 1E subunits were differentially localized. In general, alpha 1A-immunoreactivity was most intense in cell bodies and dendritic processes, including dentate granule cells, CA3 pyramidal cells and entorhinal cortex pre-alpha and pri-alpha cells. The alpha 1B antibody exhibited relatively weak staining of cell bodies but stronger staining of neuropil, especially in certain regions of high synaptic density such as the polymorphic layer of the dentate gyrus and the stratum lucidum and radiatum of the CA regions. The alpha 1E staining pattern shared features in common with both alpha 1A and alpha 1B, with strong immunoreactivity in dentate granule, CA3 pyramidal and entorhinal cortex pri-alpha cells, as well as staining of the CA3 stratum lucidum. These findings suggest regions in which particular subunits may be involved in synaptic communication. For example, comparison of alpha 1B and alpha 1E staining in the CA3 stratum lucidum with calbindin-immuno-reactivity suggested that these two calcium channels subunits may be localized presynaptically in mossy fibre terminals and therefore may be involved in neurotransmitter release from these terminals.     

Gbeta binding to GIRK4 subunit is critical for G protein-gated K+ channel activation

The cardiac G protein-gated K+ channel, IKACh, is directly activated by G protein beta gamma subunits (Gbeta gamma). IKAChis composed of two inward rectifier K+ channel subunits, GIRK1 and GIRK4. Gbeta gamma binds to both GIRK1 and GIRK4 subunits of the heteromultimeric IKACh. Here we delineate the Gbeta gamma binding regions of IKACh by studying direct Gbeta gamma interaction with native purified IKACh, competition of this interaction with peptides derived from GIRK1 or GIRK4 amino acid sequences, mutational analysis of regions implicated in Gbeta gamma binding, and functional expression of mutated subunits in mammalian cells. Only two GIRK4 peptides, containing amino acids 209-225 or 226-245, effectively competed for Gbeta gamma binding. A single point mutation introduced into GIRK4 at position 216 (C216T) dramatically reduced the potency of the peptide in inhibiting Gbeta gamma binding and Gbeta gamma activation of expressed GIRK1/GIRK4(C216T) channels. Conversion of 5 amino acids in GIRK4 (226-245) to the corresponding amino acids found in the G protein-insensitive IRK1 channel, completely abolished peptide inhibition of Gbeta gamma binding to IKACh and Gbeta gamma activation of GIRK1/mutant GIRK4 channels. We conclude from this data that Gbeta gamma binding to GIRK4 is critical for IKACh activation.     

Properties of Ba2+ currents arising from human alpha1E and alpha1Ebeta3 constructs expressed in HEK293 cells: physiology, pharmacology, and comparison to native T-type Ba2+ currents

Currents arising from human alpha1E and alpha1Ebeta3 Ca2+ channel subunits expressed in HEK-293 cells were examined with whole-cell recording methods and compared to properties of T-current in DRG neurons studied under identical ionic conditions. Coexpression of alpha1E subunit with the beta3 subunit shifted activation to more negative potentials. Activation and deactivation of both variants were comparable at most voltages, with deactivation becoming faster, but less voltage-dependent, at more negative potentials. The inactivation time course for alpha1E and alpha1Ebeta3 currents was best described by at least two exponential components. Recovery from inactivation was markedly voltage-dependent and similar for both constructs. In comparison to alpha1E and alpha1Ebeta3 constructs, T current activation was shifted to more negative potentials, activation was typically slower, deactivation exhibited a steeper voltage-dependence, and recovery from inactivation was less voltage-dependent. Over most of the activation range, native T current inactivated more completely and in a single exponential fashion. Despite some pharmacological similarities (e.g. octanol, barbiturates) between alpha1E and T-type currents, aspects of blockade by amiloride and phenytoin appear to distinguish alpha1E current from T-type currents. The results define several distinguishing features of alpha1E currents that distinguish them from native T-type currents.     

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.     

Differential regulation of N- and Q-type Ca2+ channels by cyclic nucleotides and G-proteins

Voltage-dependent Ca2+ channels play a central role in controlling neurotransmitter release at the synapse. They can be inhibited by certain G-protein-coupled receptors, acting by a pathway delimited to the membrane. In addition, modulation of Ca2+ channel activity by protein kinases also contributes to the dynamic regulation of neuronal physiology. Recently, differences in these modulations between Ca2+ channel subtypes have been shown in several neuronal preparations. Here we show that two types of presynaptic Ca2+ channel (N-type and Q-type) are differentially regulated by cAMP and G-proteins using a Xenopus oocyte expression system. Treatment to increase cytosolic cAMP concentration with forskolin and 3-isobutyl-1-methylxanthine (IBMX) markedly potentiated Q-type channel current, and the enhancement was reversed by protein kinase A inhibitors. Much smaller enhancement was observed in N-type channel current after the cAMP elevation. When large depolarizing prepulse was applied to the oocytes for evaluation of the tonic inhibition of Ca2+ channels by intrinsic G-protein activity, N-type channel current elicited a large prepulse facilitation but Q-type channels did not. The tonic inhibition of N-type channels was abolished by an intracellular perfusion with a 'cut-open' recording configuration, or by co-expression with G(alpha o). When kappa opioid receptors were co-expressed and stimulated with agonists, depolarization-resistant inhibition was more apparent in Q-type channels than in N-type channels. These results suggest that Q-type channels are more susceptible to the protein kinase A-mediated facilitation than N-type channels, and that activity of N-type channels can be more highly regulated in a voltage-dependent manner by G(betagamma) than that of Q-type channels. These differences may account for the selective regulation of neurotransmitter release by these Ca2+ channels.     

Nine L-type amino acid residues confer full 1,4-dihydropyridine sensitivity to the neuronal calcium channel alpha1A subunit. Role of L-type Met1188

Pharmacological modulation by 1,4-dihydropyridines is a central feature of L-type calcium channels. Recently, eight L-type amino acid residues in transmembrane segments IIIS5, IIIS6, and IVS6 of the calcium channel alpha1 subunit were identified to substantially contribute to 1,4-dihydropyridine sensitivity. To determine whether these eight L-type residues (Thr1066, Gln1070, Ile1180, Ile1183, Tyr1490, Met1491, Ile1497, and Ile1498; alpha1C-a numbering) are sufficient to form a high affinity 1,4-dihydropyridine binding site in a non-L-type calcium channel, we transferred them to the 1, 4-dihydropyridine-insensitive alpha1A subunit using site-directed mutagenesis. 1,4-Dihydropyridine agonist and antagonist modulation of barium inward currents mediated by the mutant alpha1A subunits, coexpressed with alpha2delta and beta1a subunits in Xenopus laevis oocytes, was investigated with the two-microelectrode voltage clamp technique. The resulting mutant alpha1A-DHPi displayed low sensitivity for 1,4-dihydropyridines. Analysis of the 1,4-dihydropyridine binding region of an ancestral L-type alpha1 subunit previously cloned from Musca domestica body wall muscle led to the identification of Met1188 (alpha1C-a numbering) as an additional critical constituent of the L-type 1,4-dihydropyridine binding domain. The introduction of this residue into alpha1A-DHPi restored full sensitivity for 1,4-dihydropyridines. It also transferred functional properties considered hallmarks of 1, 4-dihydropyridine agonist and antagonist effects (i.e. stereoselectivity, voltage dependence of drug modulation, and agonist-induced shift in the voltage-dependence of activation). Our gain-of-function mutants provide an excellent model for future studies of the structure-activity relationship of 1, 4-dihydropyridines to obtain critical structural information for the development of drugs for neuronal, non-L-type calcium channels.     

Inhibition of N-type calcium channels: the only mechanism by which presynaptic alpha 2-autoreceptors control sympathetic transmitter release

Alpha 2-Adrenoceptors are known to inhibit voltage-dependent Ca2+ channels located at neuronal cell bodies; the present study investigated whether this or alternative mechanisms, possibly downstream of Ca2+ entry, underlie the presynaptic alpha 2-adrenergic modulation of transmitter release from chick sympathetic neurons. Using chick sympathetic neurons, overflow of previously incorporated [3H]noradrenaline was elicited in the presence of extracellular Ca2+ by electrical pulses, 25 mM K+ or 10 microM nicotine, or by adding Ca2+ to otherwise Ca(2+)-free medium when cells had been made permeable by the calcium ionophore A23187 or by alpha-latrotoxin. Pretreatment of neurons with the N-type Ca2+ channel blocker omega-conotoxin GVIA and application of the alpha 2-adrenergic agonist UK 14304 reduced the overflow elicited by electrical pulses, K+ or nicotine, but not the overflow caused by Ca2+ after permeabilization with alpha-latrotoxin or A23187. In contrast, the L-type Ca2+ channel blocker nitrendipine reduced the overflow due to K+ and nicotine, but not the overflow following electrical stimulation or alpha-latrotoxin- and A23187-permeabilization. The inhibition of electrically evoked overflow by UK 14304 persisted in the presence of nitrendipine and the L-type Ca2+ channel agonist BayK 8644, which per se enhanced overflow. In omega-conotoxin GVIA-treated cultures, electrically evoked overflow was also enhanced by BayK 8644 and almost reached the value obtained in untreated neurons. However, UK 14304 lost its effect under these conditions. Whole-cell recordings of voltage-activated Ca2+ currents corroborated these results: UK 14304 inhibited Ca2+ currents by 33%, nitrendipine caused a 7% reduction, and BayK 8644 increased the currents by 30%. Moreover, the dihydropyridines failed to abolish the inhibition by UK 14304, but pretreatment with omega-conotoxin GVIA, which reduced mean amplitude from 0.95 to 0.23 nA, entirely prevented alpha 2-adrenergic effects. Our results indicate that the alpha 2-autoreceptor-mediated modulation of noradrenaline release from chick sympathetic neurons relies exclusively on the inhibition of omega-conotoxin GVIA-sensitive N-type Ca2+ channels. Mechanisms downstream of these channels and voltage-sensitive Ca2+ channels other than N-type appear not to be important.