Competitive and synergistic interactions of G protein beta(2) and Ca(2+) channel beta(1b) subunits with Ca(v)2.1 channels, revealed by mammalian two-hybrid and fluorescence resonance energy transfer measurements

Presynaptic Ca2+ channels are inhibited by metabotropic receptors. A possible mechanism for this inhibition is that G protein betagamma subunits modulate the binding of the Ca2+ channel beta subunit on the Ca2+ channel complex and induce a conformational state from which channel opening is more reluctant. To test this hypothesis, we analyzed the binding of Ca2+ channel beta and G protein beta subunits on the two separate binding sites, i.e. the loopI-II and the C terminus, and on the full-length P/Q-type alpha12.1 subunit by using a modified mammalian two-hybrid system and fluorescence resonance energy transfer (FRET) measurements. Analysis of the interactions on the isolated bindings sites revealed that the Ca2+ channel beta1b subunit induces a strong fluorescent signal when interacting with the loopI-II but not with the C terminus. In contrast, the G protein beta subunit induces FRET signals on both the C terminus and loopI-II. Analysis of the interactions on the full-length channel indicates that Ca2+ channel beta1b and G protein beta subunits bind to the alpha1 subunit at the same time. Coexpression of the G protein increases the FRET signal between alpha1/beta1b FRET pairs but not for alpha1/beta1b FRET pairs where the C terminus was deleted from the alpha1 subunit. The results suggest that the G protein alters the orientation and/or association between the Ca2+ channel beta and alpha12.1 subunits, which involves the C terminus of the alpha1 subunit and may corresponds to a new conformational state of the channel.     

A single Gbeta subunit locus controls cross-talk between protein kinase C and G protein regulation of N-type calcium channels

The modulation of N-type calcium channels is a key factor in the control of neurotransmitter release. Whereas N-type channels are inhibited by Gbetagamma subunits in a G protein beta-isoform-dependent manner, channel activity is typically stimulated by activation of protein kinase C (PKC). In addition, there is cross-talk among these pathways, such that PKC-dependent phosphorylation of the Gbetagamma target site on the N-type channel antagonizes subsequent G protein inhibition, albeit only for Gbeta(1)-mediated responses. The molecular mechanisms that control this G protein beta subunit subtype-specific regulation have not been described. Here, we show that G protein inhibition of N-type calcium channels is critically dependent on two separate but adjacent approximately 20-amino acid regions of the Gbeta subunit, plus a highly conserved Asn-Tyr-Val motif. These regions are distinct from those implicated previously in Gbetagamma signaling to other effectors such as G protein-coupled inward rectifier potassium channels, phospholipase beta(2), and adenylyl cyclase, thus raising the possibility that the specificity for G protein signaling to calcium channels might rely on unique G protein structural determinants. In addition, we identify a highly specific locus on the Gbeta(1) subunit that serves as a molecular detector of PKC-dependent phosphorylation of the G protein target site on the N-type channel alpha(1) subunit, thus providing for a molecular basis for G protein-PKC cross-talk. Overall, our results significantly advance our understanding of the molecular details underlying the integration of G protein and PKC signaling pathways at the level of the N-type calcium channel alpha(1) subunit.     

A switch mechanism for G beta gamma activation of I(KACh)

G protein-gated inwardly rectifying potassium (GIRK) channels are a family of K(+)-selective ion channels that slow the firing rate of neurons and cardiac myocytes. GIRK channels are directly bound and activated by the G protein G beta gamma subunit. As heterotetramers, they comprise the GIRK1 and the GIRK2, -3, or -4 subunits. Here we show that GIRK1 but not the GIRK4 subunit is phosphorylated when heterologously expressed. We found also that phosphatase PP2A dephosphorylation of a protein in the excised patch abrogates channel activation by G beta gamma. Experiments with the truncated molecule demonstrated that the GIRK1 C-terminal is critical for both channel phosphorylation and channel regulation by protein phosphorylation, but the critical phosphorylation sites were not located on the C terminus. These data provide evidence for a novel switch mechanism in which protein phosphorylation enables G beta gamma gating of the channel complex.     

Molecular mechanisms mediating inhibition of G protein-coupled inwardly-rectifying K+ channels

Neuronal G protein-coupled inwardly-rectifying potassium channels (GIRKs, Kir3.x) can be activated or inhibited by distinct classes of receptors (Galphai/o and Galphaq/11-coupled, respectively), providing dynamic regulation of neuronal excitability. In this mini-review, we highlight findings from our laboratory in which we used a mammalian heterologous expression system to address mechanisms of GIRK channel regulation by Galpha and Gbetagamma subunits. We found that, like beta1- and beta2-containing Gbetagamma dimers, GIRK channels are also activated by G protein betagamma dimers containing beta3 and beta4 subunits. By contrast, GIRK currents are inhibited by beta5-containing Gbetagamma dimers and/or by Galpha proteins of the Galphaq/11 family. The properties of Gbeta5-mediated inhibition suggest that beta5-containing Gbetagamma dimers act as competitive antagonists of other activating Gbetagamma pairs on GIRK channels. Inhibition of GIRK channels by Galpha subunits is specific to members of the Galphaq/11 family and appears to result, at least in part, from activation of phospholipase C (PLC) and the resultant decrease in membrane levels of phosphatidylinositol-4,5-bisphosphate (PIP2), an endogenous co-factor necessary for GIRK channel activity; this Galphaq/11 activated mechanism is largely responsible for receptor-mediated GIRK channel inhibition.     

Mapping the Gbetagamma-binding sites in GIRK1 and GIRK2 subunits of the G protein-activated K+ channel

G protein-activated K+ channels (Kir3 or GIRK) are activated by direct binding of Gbetagamma. The binding sites of Gbetagamma in the ubiquitous GIRK1 (Kir3.1) subunit have not been unequivocally charted, and in the neuronal GIRK2 (Kir3.2) subunit the binding of Gbetagamma has not been studied. We verified and extended the map of Gbetagamma-binding sites in GIRK1 by using two approaches: direct binding of Gbetagamma to fragments of GIRK subunits (pull down), and competition of these fragments with the Galphai1 subunit for binding to Gbetagamma. We also mapped the Gbetagamma-binding sites in GIRK2. In both subunits, the N terminus binds Gbetagamma. In the C terminus, the Gbetagamma-binding sites in the two subunits are not identical; GIRK1, but not GIRK2, has a previously unrecognized Gbetagamma-interacting segments in the first half of the C terminus. The main C-terminal Gbetagamma-binding segment found in both subunits is located approximately between amino acids 320 and 409 (by GIRK1 count). Mutation of C-terminal leucines 262 or 333 in GIRK1, recognized previously as crucial for Gbetagamma regulation of the channel, and of the corresponding leucines 273 and 344 in GIRK2 dramatically altered the properties of K+ currents via GIRK1/GIRK2 channels expressed in Xenopus oocytes but did not appreciably reduce the binding of Gbetagamma to the corresponding fusion proteins, indicating that these residues are mainly important for the regulation of Gbetagamma-induced changes in channel gating rather than Gbetagamma binding.     

Interaction sites of the G protein beta subunit with brain G protein-coupled inward rectifier K+ channel

G protein-coupled inward rectifier K(+) channels (GIRK channels) are activated directly by the G protein betagamma subunit. The crystal structure of the G protein betagamma subunits reveals that the beta subunit consists of an N-terminal alpha helix followed by a symmetrical seven-bladed propeller structure. Each blade is made up of four antiparallel beta strands. The top surface of the propeller structure interacts with the Galpha subunit. The outer surface of the betagamma torus is largely made from outer beta strands of the propeller. We analyzed the interaction between the beta subunit and brain GIRK channels by mutating the outer surface of the betagamma torus. Mutants of the outer surface of the beta(1) subunit were generated by replacing the sequences at the outer beta strands of each blade with corresponding sequences of the yeast beta subunit, STE4. The mutant beta(1)gamma(2) subunits were expressed in and purified from Sf9 cells. They were applied to inside-out patches of cultured locus coeruleus neurons. The wild type beta(1)gamma(2) induced robust GIRK channel activity with an EC(50) of about 4 nm. Among the eight outer surface mutants tested, blade 1 and blade 2 mutants (D1 and CD2) were far less active than the wild type in stimulating GIRK channels. However, the ability of D1 and CD2 to regulate type I and type II adenylyl cyclases was not very different from that of the wild type beta(1)gamma(2). As to the activities to stimulate phospholipase Cbeta(2), D1 was more potent and CD2 was less potent than the wild type beta(1)gamma(2). Additionally we tested four beta(1) mutants in which mutated residues are located in the top Galpha/beta interacting surface. Among them, mutant W332A showed far less ability than the wild type to activate GIRK channels. These results suggest that the outer surface of blade 1 and blade 2 of the beta subunit might specifically interact with GIRK and that the beta subunit interacts with GIRK both over the outer surface and over the top Galpha interacting surface.     

A dominant-negative strategy for studying roles of G proteins in vivo

G proteins play a critical role in transducing a large variety of signals into intracellular responses. Increasingly, there is evidence that G proteins may play other roles as well. Dominant-negative constructs of the alpha subunit of G proteins would be useful in studying the roles of G proteins in a variety of processes, but the currently available dominant-negative constructs, which target Mg2+-binding sites, are rather leaky. A variety of studies have implicated the carboxyl terminus of G protein alpha subunits in both mediating receptor-G protein interaction and in receptor selectivity. Thus we have made minigene plasmid constructs that encode oligonucleotide sequences corresponding to the carboxyl-terminal undecapeptide of Galphai, Galphaq, or Galphas. To determine whether overexpression of the carboxyl-terminal peptide would block cellular responses, we used as a test system the activation of the M2 muscarinic receptor activated K+ channels in HEK 293 cells. The minigenes were transiently transfected along with G protein-regulated inwardly rectifying K+ channels (GIRK) into HEK 293 cells that stably express the M2 muscarinic receptor. The presence of the Galphai carboxyl-terminal peptide results in specific inhibition of GIRK activity in response to agonist stimulation of the M2 muscarinic receptor. The Galphai minigene construct completely blocks agonist-mediated M2 mAChR K+ channel response whereas the control minigene constructs (empty vector, pcDNA3.1, and the Galpha carboxyl peptide in random order, pcDNA-GalphaiR) had no effect on agonist-mediated M2 muscarinic receptor GIRK response. The inhibitory effects of the Galphai minigene construct were specific because overexpression of peptides corresponding to the carboxyl terminus of Galphaq or Galphas had no effect on M2 muscarinic receptor stimulation of the K+ channel.     

Critical determinants of the G protein gamma subunits in the Gbetagamma stimulation of G protein-activated inwardly rectifying potassium (GIRK) channel activity

The betagamma subunits of G proteins modulate inwardly rectifying potassium (GIRK) channels through direct interactions. Although GIRK currents are stimulated by mammalian Gbetagamma subunits, we show that they were inhibited by the yeast Gbetagamma (Ste4/Ste18) subunits. A chimera between the yeast and the mammalian Gbeta1 subunits (ymbeta) stimulated or inhibited GIRK currents, depending on whether it was co-expressed with mammalian or yeast Ggamma subunits, respectively. This result underscores the critical functional influence of the Ggamma subunits on the effectiveness of the Gbetagamma complex. A series of chimeras between Ggamma2 and the yeast Ggamma revealed that the C-terminal half of the Ggamma2 subunit is required for channel activation by the Gbetagamma complex. Point mutations of Ggamma2 to the corresponding yeast Ggamma residues identified several amino acids that reduced significantly the ability of Gbetagamma to stimulate channel activity, an effect that was not due to improper association with Gbeta. Most of the identified critical Ggamma residues clustered together, forming an intricate network of interactions with the Gbeta subunit, defining an interaction surface of the Gbetagamma complex with GIRK channels. These results show for the first time a functional role for Ggamma in the effector role of Gbetagamma.     

Gbeta residues that do not interact with Galpha underlie agonist-independent activity of K+ channels.

Gbetagamma subunits interact directly and activate G protein-gated Inwardly Rectifying K(+) (GIRK) channels. Little is known about the identity of functionally important interactions between Gbetagamma and GIRK channels. We tested the effects of all mammalian Gbeta subunits on channel activity and showed that whereas Gbeta1-4 subunits activate heteromeric GIRK channels independently of receptor activation, Gbeta5 does not. Gbeta1 and Gbeta5 both bind the N and C termini of the GIRK1 and GIRK4 channel subunits. Chimeric analysis between the Gbeta1 and Gbeta5 proteins revealed a 90-amino acid stretch that spans blades two and three of the seven-propeller structure and is required for channel activation. Within this region, eight non-conserved amino acids were critical for the activity of Gbeta1, as mutation of each residue to its counterpart in Gbeta5 significantly reduced the ability of Gbeta1 to stimulate channel activity. In particular, mutation of residues Ser-67 and Thr-128 to the corresponding Gbeta5 residues completely abolished Gbeta1 stimulation of GIRK channel activity. Mapping these functionally important residues on the three-dimensional structure of Gbeta1 shows that Ser-67, Ser-98, and Thr-128 are the only surface accessible residues. Galpha(i)1 interacts with Ser-98 but not with Ser-67 and Thr-128 in the heterotrimeric Galphabetagamma structure. Further characterization of the three mutant proteins showed that they fold properly and interact with Ggamma2. Of the three identified functionally important residues, the Ser-67 and Thr-128 Gbeta mutants significantly inhibited basal currents of a channel point mutant that displays Gbetagamma-mediated basal but not agonist-induced currents. Our findings indicate that the presence of Gbeta residues that do not interact with Galpha are involved in Gbetagamma interactions in the absence of agonist stimulation.     

Co-expression of Gbeta5 enhances the function of two Ggamma subunit-like domain-containing regulators of G protein signaling proteins

Regulators of G protein signaling (RGS) stimulate the GTPase activity of G protein Galpha subunits and probably play additional roles. Some RGS proteins contain a Ggamma subunit-like (GGL) domain, which mediates a specific interaction with Gbeta5. The role of such interactions in RGS function is unclear. RGS proteins can accelerate the kinetics of coupling of G protein-coupled receptors to G-protein-gated inwardly rectifying K(+) (GIRK) channels. Therefore, we coupled m2-muscarinic acetylcholine receptors to GIRK channels in Xenopus oocytes to evaluate the effect of Gbeta5 on RGS function. Co-expression of either RGS7 or RGS9 modestly accelerated GIRK channel kinetics. When Gbeta5 was co-expressed with either RGS7 or RGS9, the acceleration of GIRK channel kinetics was strongly increased over that produced by RGS7 or RGS9 alone. RGS function was not enhanced by co-expression of Gbeta1, and co-expression of Gbeta5 alone had no effect on GIRK channel kinetics. Gbeta5 did not modulate the function either of RGS4, an RGS protein that lacks a GGL domain, or of a functional RGS7 construct in which the GGL domain was omitted. Enhancement of RGS7 function by Gbeta5 was not a consequence of an increase in the amount of plasma membrane or cytosolic RGS7 protein.     

Determinants of G protein inhibition of presynaptic calcium channels

The modulation of presynaptic calcium (Ca) channels by heterotrimeric G proteins is a key factor for the regulation of neurotransmission. Over the past 20 yr, a significant understanding of the molecular events underlying this regulation has been acquired. It is now widely accepted that binding of G protein betagamma dimers directly to the cytoplasmic region linking domains I and II of the Ca channel alpha1 subunit results in a stabilization of the closed conformation of the channel, thereby inhibiting current activity. The extent of the inhibition is dependent on the Gbeta subunit isoform, and is antagonized by both strong membrane depolarizations and protein kinase C-dependent phosphorylation of the channel. Finally, the inhibition is critically modulated by regulator of G protein signaling proteins, and by proteins forming the presynaptic vesicle release complex. Thus, the regulation of the activities of presynaptic Ca channels is becoming increasingly complex, a feature that may contribute to the overall fine-tuning of Ca entry into presynaptic nerve termini, and thus, neurotransmission.     

Stimulation of cellular signaling and G protein subunit dissociation by G protein betagamma subunit-binding peptides

We previously developed peptides that bind to G protein betagamma subunits and selectively block interactions between betagamma subunits and a subset of effectors in vitro (Scott, J. K., Huang, S. F., Gangadhar, B. P., Samoriski, G. M., Clapp, P., Gross, R. A., Taussig, R., and Smrcka, A. V. (2001) EMBO J. 20, 767-776). Here, we created cell-permeating versions of some of these peptides by N-terminal modification with either myristate or the cell permeation sequence from human immunodeficiency virus TAT protein. The myristoylated betagamma-binding peptide (mSIRK) applied to primary rat arterial smooth muscle cells caused rapid activation of extracellular signal-regulated kinase 1/2 in the absence of an agonist. This activation did not occur if the peptide lacked a myristate at the N terminus, if the peptide had a single point mutation to eliminate betagamma subunit binding, or if the cells stably expressed the C terminus of betaARK1. A human immunodeficiency virus TAT-modified peptide (TAT-SIRK) and a myristoylated version of a second peptide (mSCAR) that binds to the same site on betagamma subunits as mSIRK, also caused extracellular signal-regulated kinase activation. mSIRK also stimulated Jun N-terminal kinase phosphorylation, p38 mitogen-activated protein kinase phosphorylation, and phospholipase C activity and caused Ca2+ release from internal stores. When tested with purified G protein subunits in vitro, SIRK promoted alpha subunit dissociation from betagamma subunits without stimulating nucleotide exchange. These data suggest a novel mechanism by which selective betagamma-binding peptides can release G protein betagamma subunits from heterotrimers to stimulate G protein pathways in cells.     

Differential role of the alpha1C subunit tails in regulation of the Cav1.2 channel by membrane potential, beta subunits, and Ca2+ ions

Voltage-gated Ca(v)1.2 channels are composed of the pore-forming alpha1C and auxiliary beta and alpha2delta subunits. Voltage-dependent conformational rearrangements of the alpha1C subunit C-tail have been implicated in Ca2+ signal transduction. In contrast, the alpha1C N-tail demonstrates limited voltage-gated mobility. We have asked whether these properties are critical for the channel function. Here we report that transient anchoring of the alpha1C subunit C-tail in the plasma membrane inhibits Ca2+-dependent and slow voltage-dependent inactivation. Both alpha2delta and beta subunits remain essential for the functional channel. In contrast, if alpha1C subunits with are expressed alpha2delta but in the absence of a beta subunit, plasma membrane anchoring of the alpha1C N terminus or its deletion inhibit both voltage- and Ca2+-dependent inactivation of the current. The following findings all corroborate the importance of the alpha1C N-tail/beta interaction: (i) co-expression of beta restores inactivation properties, (ii) release of the alpha1C N terminus inhibits the beta-deficient channel, and (iii) voltage-gated mobility of the alpha1C N-tail vis a vis the plasma membrane is increased in the beta-deficient (silent) channel. Together, these data argue that both the alpha1C N- and C-tails have important but different roles in the voltage- and Ca2+-dependent inactivation, as well as beta subunit modulation of the channel. The alpha1C N-tail may have a role in the channel trafficking and is a target of the beta subunit modulation. The beta subunit facilitates voltage gating by competing with the N-tail and constraining its voltage-dependent rearrangements. Thus, cross-talk between the alpha1C C and N termini, beta subunit, and the cytoplasmic pore region confers the multifactorial regulation of Ca(v)1.2 channels.     

Modulation of cardiac Ca2+ channels in Xenopus oocytes by protein kinase C.

L-Type calcium channel was expressed in Xenopus laevis oocytes injected with RNAs coding for different cardiac Ca2+ channel subunits, or with total heart RNA. The effects of activation of protein kinase C (PKC) by the phorbol ester PMA (4 beta-phorbol 12-myristate 13-acetate) were studied. Currents through channels composed of the main (alpha 1) subunit alone were initially increased and then decreased by PMA. A similar biphasic modulation was observed when the alpha 1 subunit was expressed in combination with alpha 2/delta, beta and/or gamma subunits, and when the channels were expressed following injection of total rat heart RNA. No effects on the voltage dependence of activation were observed. The effects of PMA were blocked by staurosporine, a protein kinase inhibitor. beta subunit moderate the enhancement caused by PMA. We conclude that both enhancement and inhibition of cardiac L-type Ca2+ currents by PKC are mediated via an effect on the alpha 1 subunit, while the beta subunit may play a mild modulatory role.     

Distinct sites on G protein beta gamma subunits regulate different effector functions

G proteins interact with effectors at multiple sites and regulate their activity. The functional significance of multiple contact points is not well understood. We previously identified three residues on distinct surfaces of Gbetagamma that are crucial for G protein-coupled inward rectifier K(+) (GIRK) channel activation. Here we show that mutations at these sites, S67K, S98T, and T128F, abolished or reduced direct GIRK current activation in inside-out patches, but, surprisingly, all mutants synergized with sodium in activating K(+) currents. Each of the three Gbeta(1) mutants bound the channel indicating that the defects reflected mainly functional impairments. We tested these mutants for functional interactions with effectors other than K(+) channels. With N-type calcium channels, Gbetagamma wild type and mutants all inhibited basal currents. A depolarizing pre-pulse relieved Gbetagamma inhibition of Ca(2+) currents by the wild type and the S98T and T128F mutants but not the S67K mutant. Both wild type and mutant Gbetagamma subunits activated phospholipase C beta(2) with similar potencies; however, the S67K mutant showed reduced maximal activity. These data establish a pattern where mutations can alter the Gbetagamma regulation of a specific effector function without affecting other Gbetagamma-mediated functions. Moreover, Ser-67 showed this pattern in all three effectors tested, suggesting that this residue participates in a common functional domain on Gbeta(1) that regulates several effectors. These data show that distinct domains within Gbetagamma subserve specific functional roles.     

Identification of critical residues controlling G protein-gated inwardly rectifying K(+) channel activity through interactions with the beta gamma subunits of G proteins.

G protein-sensitive inwardly rectifying potassium (GIRK) channels are activated through direct interactions of their cytoplasmic N- and C-terminal domains with the beta gamma subunits of G proteins. By using a combination of biochemical and electrophysiological approaches, we identified minimal N- and C-terminal G beta gamma -binding domains responsible for stimulation of GIRK4 channel activity. Within these domains one N-terminal residue, His-64, and one C-terminal residue, Leu-268, proved critical for G beta gamma-mediated GIRK4 activity. Moreover, mutations at these GIRK4 sites reduced significantly binding of the channel domains to G beta gamma . The corresponding residues in GIRK1 also showed a critical involvement in G beta gamma sensitivity. In GIRK4/GIRK1 heteromers the GIRK4 His-64 and Leu-268 residues showed greater contributions to G beta zeta sensitivity than did the corresponding GIRK1 His-57 and Leu-262 residues. These results identify functionally important channel interaction sites with the beta gamma subunits of G proteins, critical for channel activity.     

Modulation of voltage- and Ca2+-dependent gating of CaV1.3 L-type calcium channels by alternative splicing of a C-terminal regulatory domain

Low voltage activation of Ca(V)1.3 L-type Ca(2+) channels controls excitability in sensory cells and central neurons as well as sinoatrial node pacemaking. Ca(V)1.3-mediated pacemaking determines neuronal vulnerability of dopaminergic striatal neurons affected in Parkinson disease. We have previously found that in Ca(V)1.4 L-type Ca(2+) channels, activation, voltage, and calcium-dependent inactivation are controlled by an intrinsic distal C-terminal modulator. Because alternative splicing in the Ca(V)1.3 alpha1 subunit C terminus gives rise to a long (Ca(V)1.3(42)) and a short form (Ca(V)1.3(42A)), we investigated if a C-terminal modulatory mechanism also controls Ca(V)1.3 gating. The biophysical properties of both splice variants were compared after heterologous expression together with beta3 and alpha2delta1 subunits in HEK-293 cells. Activation of calcium current through Ca(V)1.3(42A) channels was more pronounced at negative voltages, and inactivation was faster because of enhanced calcium-dependent inactivation. By investigating several Ca(V)1.3 channel truncations, we restricted the modulator activity to the last 116 amino acids of the C terminus. The resulting Ca(V)1.3(DeltaC116) channels showed gating properties similar to Ca(V)1.3(42A) that were reverted by co-expression of the corresponding C-terminal peptide C(116). Fluorescence resonance energy transfer experiments confirmed an intramolecular protein interaction in the C terminus of Ca(V)1.3 channels that also modulates calmodulin binding. These experiments revealed a novel mechanism of channel modulation enabling cells to tightly control Ca(V)1.3 channel activity by alternative splicing. The absence of the C-terminal modulator in short splice forms facilitates Ca(V)1.3 channel activation at lower voltages expected to favor Ca(V)1.3 activity at threshold voltages as required for modulation of neuronal firing behavior and sinoatrial node pacemaking.     

Receptor-mediated inhibition of G protein-coupled inwardly rectifying potassium channels involves G(alpha)q family subunits, phospholipase C, and a readily diffusible messenger

G protein-coupled inwardly rectifying K+ (GIRK) channels can be activated or inhibited by distinct classes of receptor (G(alpha)i/o- and G(alpha)q-coupled), providing dynamic regulation of cellular excitability. Receptor-mediated activation involves direct effects of G(beta)gamma subunits on GIRK channels, but mechanisms involved in GIRK channel inhibition have not been fully elucidated. An HEK293 cell line that stably expresses GIRK1/4 channels was used to test G protein mechanisms that mediate GIRK channel inhibition. In cells transiently or stably cotransfected with 5-HT1A (G(alpha)i/o-coupled) and TRH-R1 (G(alpha)q-coupled) receptors, 5-HT (5-hydroxytryptamine; serotonin) enhanced GIRK channel currents, whereas thyrotropin-releasing hormone (TRH) inhibited both basal and 5-HT-activated GIRK channel currents. Inhibition of GIRK channel currents by TRH primarily involved signaling by G(alpha)q family subunits, rather than G(beta)gamma dimers: GIRK channel current inhibition was diminished by Pasteurella multocida toxin, mimicked by constitutively active members of the G(alpha)q family, and reduced by minigene constructs that disrupt G(alpha)q signaling, but was completely preserved in cells expressing constructs that interfere with signaling by G(beta)gamma subunits. Inhibition of GIRK channel currents by TRH and constitutively active G(alpha)q was reduced by, an inhibitor of phospholipase C (PLC). Moreover, TRH- R1-mediated GIRK channel inhibition was diminished by minigene constructs that reduce membrane levels of the PLC substrate phosphatidylinositol bisphosphate, further implicating PLC. However, we found no evidence for involvement of protein kinase C, inositol trisphosphate, or intracellular calcium. Although these downstream signaling intermediaries did not contribute to receptor-mediated GIRK channel inhibition, bath application of TRH decreased GIRK channel activity in cell-attached patches. Together, these data indicate that receptor-mediated inhibition of GIRK channels involves PLC activation by G(alpha) subunits of the G(alpha)q family and suggest that inhibition may be communicated at a distance to GIRK channels via unbinding and diffusion of phosphatidylinositol bisphosphate away from the channel.     

G protein-gated inhibitory module of N-type (ca(v)2.2) ca2+ channels

Voltage-dependent G protein (Gbetagamma) inhibition of N-type (CaV2.2) channels supports presynaptic inhibition and represents a central paradigm of channel modulation. Still controversial are the proposed determinants for such modulation, which reside on the principal alpha1B channel subunit. These include the interdomain I-II loop (I-II), the carboxy tail (CT), and the amino terminus (NT). Here, we probed these determinants and related mechanisms, utilizing compound-state analysis with yeast two-hybrid and mammalian cell FRET assays of binding among channel segments and G proteins. Chimeric channels confirmed the unique importance of NT. Binding assays revealed selective interaction between NT and I-II elements. Coexpressing NT peptide with Gbetagamma induced constitutive channel inhibition, suggesting that the NT domain constitutes a G protein-gated inhibitory module. Such inhibition was limited to NT regions interacting with I-II, and G-protein inhibition was abolished within alpha1B channels lacking these NT regions. Thus, an NT module, acting via interactions with the I-II loop, appears fundamental to such modulation.     

Structure and function of neuronal Ca2+ channels and their role in neurotransmitter release

Electrophysiological studies of neurons reveal different Ca2+ currents designated L-, N-, P-, Q-, R-, and T-type. High-voltage-activated neuronal Ca2+ channels are complexes of a pore-forming alpha 1 subunit of about 190-250 kDa, a transmembrane, disulfide-linked complex of alpha 2 and delta subunits, and an intracellular beta subunit, similar to the alpha 1, alpha 2 delta, and beta subunits previously described for skeletal muscle Ca2+ channels. The primary structures of these subunits have all been determined by homology cDNA cloning using the corresponding subunits of skeletal muscle Ca2+ channels as probes. In most neurons, L-type channels contain alpha 1C or alpha 1D subunits, N-type contain alpha 1B subunits, P- and Q-types contain alternatively spliced forms of alpha 1A subunits, R-type contain alpha 1E subunits, and T-type contain alpha 1G or alpha 1H subunits. Association with different beta subunits also influences Ca2+ channel gating substantially, yielding a remarkable diversity of functionally distinct molecular species of Ca2+ channels in neurons.