G(o) transduces GABAB-receptor modulation of N-type calcium channels in cultured dorsal root ganglion neurons

The intracellular loop between domains I and II of the B-type calcium channel confers aspects of G-protein sensitivity to the E-type calcium channel

Neuronal voltage-dependent calcium channels undergo inhibitory modulation by G-protein activation, generally involving both kinetic slowing and steady-state inhibition. We have shown previously that the beta-subunit of neuronal calcium channels plays an important role in this process, because when it is absent, greater receptor-mediated inhibition is observed (). We therefore hypothesized that the calcium channel beta-subunits normally may occlude G-protein-mediated inhibition. Calcium channel beta-subunits bind to the cytoplasmic loop between transmembrane domains I and II of the alpha1-subunits (). We have examined the hypothesis that this loop is involved in G-protein-mediated inhibition by making chimeras containing the I-II loop of alpha1B or alpha1A inserted into alpha1E (alpha1EBE and alpha1EAE, respectively). This strategy was adopted because alpha1B (the molecular counterpart of N-type channels) and, to a lesser extent, alpha1A (P/Q-type) are G-protein-modulated, whereas this has not been observed to any great extent for alpha1E. Although alpha1B, coexpressed with alpha2-delta and beta1b transiently expressed in COS-7 cells, showed both kinetic slowing and steady-state inhibition when recorded with GTPgammaS in the patch pipette, both of which were reversed with a depolarizing prepulse, the chimera alpha1EBE (and, to a smaller extent, alpha1EAE) showed only kinetic slowing in the presence of GTPgammaS, and this also was reversed by a depolarizing prepulse. These results indicate that the I-II loop may be the molecular substrate of kinetic slowing but that the steady-state inhibition shown by alpha1B may involve a separate site on this calcium channel.

Mechanism of inhibition of calcium channels in rat nucleus tractus solitarius by neurotransmitters

1. High-threshold Ca2+ channel currents were measured every 15 s following a 200 ms voltage step from -80 mV to 0 mV in order to study the coupling mechanism between neurotransmitter receptors and Ca2+ channels in neurones acutely isolated from the nucleus tractus solitarius (NTS) of the rat. 2. Application of 30 microM baclofen (GABAB receptor agonist) caused 38.9 +/- 1.2% inhibition of the peak inward Ba2+ current (IBa2+) in most NTS cells tested (n = 85 of 88). Somatostatin, 300 nM, also reduced IBa2+ by 31.3 +/- 1.6% in 53 cells of 82 tested. 3. Activation of mu-opioid-, GABAB- or somatostatin-receptors inhibited both N- and P/Q-type Ca2+ channels. 4. The inhibition of Ca2+ currents by DAMGo (mu-opioid receptor agonist), baclofen and somatostatin was reduced by treatment with pertussis toxin and partially relieved by application of a 50 ms conditioning prepulse to +80 mV. This suggests that a pertussis toxin-sensitive G-protein was involved in the neurotransmitter-mediated action in the observed inhibition of Ca2+ currents. 5. Intracellular loading with an antiserum raised against the amino terminus of Go alpha (GC/2) markedly attenuated the somatostatin-induced inhibition, but did not block the DAMGO- and baclofen-induced inhibition. 6. These findings suggest at least two different pertussis toxin-sensitive G-protein-mediated pathways are involved in receptor-induced inhibition of Ca2+ currents in the NTS.

Presynaptic GABAB-and gamma-hydroxybutyric acid-mediated mechanisms in generalized absence seizures

gamma-Hydroxybutyric acid (GHB) is a naturally occurring compound which has the ability to induce generalized absence seizures when given to animals. This effect of GHB may be blocked by either GHB or GABAB receptor antagonists. We sought to test the hypothesis that pre-synaptic GHB- and GABAB-mediated mechanisms in thalamus and cortex are operative in the GHB model of generalized absence seizures. Presynaptic Ca(2+)-dependent K+ efflux was determined using Ca(2+)-stimulated Rb86 efflux in synaptosomes prepared from thalamus and cortex in the presence of GHB, a specific GHB receptor antagonist, the specific GABAB agonist (-)baclofen, or the specific GABAB antagonists, phaclofen and CGP 35348. The effect of these compounds was determined also on basal and K(+)-stimulated 45Ca2+ uptake and basal and K(+)-stimulated synaptosomal cytosolic Ca2+([Ca2]i) in synaptosomes prepared from thalamus and cortex and on [125I] omega-conotoxin binding in thalamus and cortex using autoradiographic binding techniques. There was no demonstrable change in Ca(2+)-stimulated Rb86 efflux in any experimental condition studied; however GHB and (-)baclofen both suppressed K(+)-stimulated 45Ca2+ uptake and [Ca2]i in synaptosomes and were associated with a decrease in [125I] omega-conotoxin binding which achieved statistical significance only in frontal cortex, a brain region selectively involved in the genesis of GHB-induced absence seizures. The effects of GHB and (-)baclofen on K(+)-stimulated 45Ca2+ uptake and [Ca2]i in synaptosomes were additive. The effects of GHB in this regard were attenuated by the GHB antagonist and phaclofen while that of (-)baclofen was attenuated by CGP 35348. These data do not support the hypothesis that the GHB and GABAB receptor are one and the same. Rather, they raise the possibility that a presynaptic GHB/GABAB receptor complex might be involved in the pathogenesis of GHB-induced generalized absence seizures.

Facilitation of Ca2+ current in excitable cells

Voltage-dependent Ca2+ channels are one of the main routes for the entry of Ca2+ into excitable cells. These channels are unique in cell-signalling terms in that they can transduce an electrical signal (membrane depolarization) via Ca2+ entry into a chemical signal, by virtue of the diverse range of intracellular Ca(2+)-dependent enzymes and processes. In a variety of cell types, currents through voltage-dependent Ca2+ channels can be increased in amplitude by a number of means. Although the term facilitation was originally defined as an increase of Ca2+ current resulting from one or a train of prepulses to depolarizing voltages, there is a great deal of overlap between facilitation by this means and enhancement by other routes, such as phosphorylation.

Interactions of N-ethylmaleimide and aluminium fluoride with GABAB receptor function in rat neocortical slices

Interactions of N-ethylmaleimide and aluminium fluoride (AlF - 4) with GABAB receptors have been examined using spontaneously discharging rat neocortical slices. The suppression of discharges by the GABAB receptor agonist baclofen (5-10 mu M) was irreversibly prevented by N-ethylmaleimide (10-50 mu M) and its analog N-phenylmaleimide (10-50 mu M), whilst superfusion of slices with NaF (10 mM) and AlCl3 (100 mu M) to form a fluoroaluminate (AlF - 4) complex markedly potentiated the action of baclofen. The lipoxygenase inhibitors, nordihydroguaiaretic acid (10-50 mu M) and eicosatetraynoic acid (10-50 mu M) or the phospholipase A2 inhibitor bromophenacylbromide (50-100 mu M) did not affect the response to baclofen. The depressant action of baclofen is evidently mediated through G-proteins, but is not dependent on arachidonic acid metabolites.

Molecular biology of calcium channels

Pharmacological and electrophysiological studies have established that there are multiple types of voltage-gated Ca2+ channels. Molecular biology has uncovered an even greater number of channel molecules. Thus, the molecular diversity of Ca2+ channels has its basis in the expression of many alpha 1 and beta genes, and also in the splice variants produced from these genes. This ability to mix and match subunits provides the cell with yet another mechanism to control the influx of calcium. Future studies will describe new subunits, the subunit composition of each type of channel, and the cloning of new Ca2+ channel types.

Voltage-dependent calcium channel beta-subunits in combination with alpha 1 subunits, have a GTPase activating effect to promote the hydrolysis of GTP by G alpha o in rat frontal cortex

The dihydropyridine-sensitive calcium channel agonist (-)-BayK 8644 was found to produce an enhancement of the intrinsic hydrolysis of GTP by Go in rat frontal cortex membranes. An anti-calcium channel beta-subunit antiserum abolished the (-)-BayK 8644-stimulated hydrolysis of GTP by Go and reduced the dihydropyridine binding capacity of the cortical membranes. A peptide which mimics the beta-subunit binding domain of the calcium channel complex, also attenuated (-)-BayK 8644 activation of GTPase. This study suggests that the calcium channel beta-subunit is the principal component of the channel complex involved in linking dihydropyridine agonist binding to enhanced hydrolysis of GTP by Go. This may be a mechanism by which calcium channels can normally act to limit the duration of a G-protein modulatory signal.

A physiological role for GABAB receptors and the effects of baclofen in the mammalian central nervous system

The inhibitory neurotransmitter GABA acts in the mammalian brain through two different receptor classes: GABAA and GABAB receptors. GABAB receptors differ fundamentally from GABAA receptors in that they require a G-protein. GABAB receptors are located pre- and/or post-synaptically, and are coupled to various K+ and Ca2+ channels presumably through both a membrane delimited pathway and a pathway involving second messengers. Baclofen, a selective GABAB receptor agonist, as well as GABA itself have pre- and post-synaptic effects. Pre-synaptic effects comprise the reduction of the release of excitatory and inhibitory transmitters. GABAergic receptors on GABAergic terminals may regulate GABA release, however, in most instances spontaneous inhibitory synaptic activity is not modulated by endogenous GABA. Post-synaptic GABAB receptor-mediated inhibition is likely to occur through a membrane delimited pathway activating K+ channels, while baclofen, in some neurons, may activate K+ channels through a second messenger pathway involving arachidonic acid. Some, but not all GABAB receptor-gated K+ channels have the typical properties of those G-protein-activated K+ channels which are also gated by other endogenous ligands of the brain. New, high affinity GABAB antagonists are now available, and some pharmacological evidence points to a receptor heterogeneity. The pharmacological distinction of receptor subtypes, however, has to await final support from a characterization of the molecular structure. The function importance of post-synaptic GABAB receptors is highlighted by a segregation of GABAA and GABAB synapses in the mammalian brain.

Inhibition of the interaction of G protein G(o) with calcium channels by the calcium channel beta-subunit in rat neurones

1. The beta-subunit has marked effects on the biophysical and pharmacological properties of voltage-dependent calcium channels. In the present study we examined the ability of the GABAB agonist (-) -baclofen to inhibit calcium channel currents in cultured rat dorsal root ganglion neurones following depletion of beta-subunit immunoreactivity, 108-116 h after microinjection of a beta-subunit antisense oligonucleotide. 2.We observed that, although the calcium channel current was markedly reduced in amplitude following beta-subunit depletion, the residual current (comprising both N- and L-type calcium channel currents) showed an enhanced response to application of (-) -baclofen. Therefore, it is possible that there is normally competition between activated G protein G(o) and the calcium channel beta-subunit for binding to the calcium channel alpha 1-subunit; and this competition shifts in favour of the binding of activated G(o) following depletion of the beta-subunit, resulting in increased inhibition. 3. This hypothesis is supported by evidence that an antibody against the calcium channel beta-subunit completely abolishes stimulation of the GTPase activity of G(o) by the dihydropyridine agonist S-(-) -Bay K 8644 in brain membranes. This stimulation of GTPase is thought to result from an interaction of G(o) alpha-subunit (G alpha o) with its calcium channel effector which may operate as a GTPase-activating protein. 4. These data suggest that the calcium channel beta-subunit when complexed with the beta 1-subunit normally inhibits its association with activated G(o). It may function as a GTPase-activating protein to reduce the ability of activated G(o) to associate with the calcium channel, and thus limit the efficacy of agonists such as (-) -baclofen.

Use of site-directed antibodies to probe the topography of the alpha 2 subunit of voltage-gated Ca2+ channels

Polyclonal antibodies were raised against peptides corresponding to residues 1-15, 469-483 and 933-951 of the rabbit skeletal muscle L-type calcium channel alpha 2/delta primary translation product, for use as topological probes. Immunocytochemical comparison of the abilities of the antibodies to bind to the alpha 2 and delta subunits in intact and detergent-permeabilised rat dorsal root ganglion cells enabled the membrane orientation of these regions to be established. The resultant data indicate that the regions containing residues 1-15 and 469-483 of the alpha 2 subunit, and residues 1-17 of the delta subunit, are exposed on the extracellular surface of the membrane, findings consistent with a model that proposes alpha 2 to be entirely extracellular.

GABAB receptors

GABAB receptors are a distinct subclass of receptors for the major inhibitory transmitter 4-aminobutanoic acid (GABA) that mediate depression of synaptic transmission and contribute to the inhibition controlling neuronal excitability. The development of specific agonists and antagonists for these receptors has led to a better understanding of their physiology and pharmacology, highlighting their diverse coupling to different intracellular effectors through Gi/G(o) proteins. This review emphasises our current knowledge of the neurophysiology and neurochemistry of GABAB receptors, including their heterogeneity, as well as the therapeutic potential of drugs acting at these sites.

Transmitter-mediated inhibition of N-type calcium channels in sensory neurons involves multiple GTP-binding proteins and subunits

The modulation of voltage-activated Ca2+ channels by neurotransmitters and peptides is very likely a primary means of regulating Ca(2+)-dependent physiological functions such as neurosecretion, muscle contraction, and membrane excitability. In neurons, N-type Ca2+ channels (defined as omega-conotoxin GVIA-sensitive) are one prominent target for transmitter-mediated inhibition. This inhibition is widely thought to result from a shift in the voltage independence of channel gating. Recently, however, voltage-independent inhibition has also been described for N channels. As embryonic chick dorsal root ganglion neurons express both of these biophysically distinct modulatory pathways, we have utilized these cells to test the hypothesis that the voltage-dependent and -independent actions of transmitters are mediated by separate biochemical pathways. We have confirmed this hypothesis by demonstrating that the two modulatory mechanisms activated by a single transmitter involve not only different classes of G protein but also different G protein subunits.

Low- and high-voltage-activated calcium channel currents and their modulation in the dorsal root ganglion cell line ND7-23

The dorsal root ganglion-neuroblastoma cell line ND7-23 expresses low-voltage-activated calcium channel currents, and also expresses high-voltage-activated currents in about 50% of differentiated cells. Calcium channel currents were recorded with Ba2+ as the charge carrier. Low-voltage-activated currents were maximally activated at -30 mV and completely inactivated at holding potentials of -60 to -50 mV. omega-Conotoxin GVIA produced a reversible inhibition of low-voltage-activated currents, whereas the inhibition of high-voltage-activated current was largely irreversible. Dihydropyridine antagonists did not inhibit low-voltage-activated currents, whereas they inhibited a sustained, high-voltage-activated current. Low-voltage-activated currents were inhibited to a greater extent than high-voltage-activated currents by Ni2+ (100 microM) and by phenytoin (10 microM). Bradykinin (0.1 microM), baclofen (2 microM) and internal guanosine-5'-O-3-thiotriphosphate (100 microM) inhibited low-voltage-activated currents without affecting their kinetics of activation. Two classes of low-voltage-activated current were distinguished by their kinetics of inactivation. In the majority of cells, currents were slowly inactivating with a time-constant of inactivation of about 50 ms. They also exhibited a sustained component to the current, representing about 20% of the peak current. This component could be distinguished pharmacologically from high-voltage-activated current. The remainder of cells expressed a rapidly and completely inactivating current, with a time-constant of inactivation of about 20 ms. Two distinct single channel currents were observed in these cells, from cell-attached patch measurements, one had a single channel conductance of 7.9 pS, and the ensemble average current showed some inactivation. It is likely that this channel subtype underlies the low-voltage-activated current. The other showed long openings in the presence of a dihydropyridine agonist, had a conductance of 23.1 pS, and was non-inactivating.