Isabelle M. Mintz

P-type calcium channels in rat central and peripheral neurons

The peptide toxin omega-Aga-IVA blocked P-type Ca2+ channel current in rat Purkinje neurons (KD approximately 2 nM) but had no effect on identified T-type, L-type, or N-type currents in a variety of central and peripheral neurons. omega-Aga-IVA blocked a substantial fraction of high threshold Ca2+ channel current in neurons from the hippocampal CA1 region (mean 26%), visual cortex (32%), spinal cord (45%), and dorsal root ganglia (23%), but less in hippocampal CA3 neurons (14%) and none in sympathetic neurons. In all cases, omega-Aga-IVA block could be reversed by a brief train of strong depolarizations. There was no overlap between current blocked by omega-Aga-IVA and the fractions blocked by dihydropyridines and omega-conotoxin GVIA, but not all current resistant to dihydropyridines and omega-conotoxin was blocked by omega-Aga-IVA. The results suggest that omega-Aga-IVA is highly selective for P-type channels and that many central neurons and some peripheral neurons possess substantial P-type current.

Calcium control of transmitter release at a cerebellar synapse

The manner in which presynaptic Ca2+ influx controls the release of neurotransmitter was investigated at the granule cell to Purkinje cell synapse in rat cerebellar slices. Excitatory postsynaptic currents were measured using whole-cell voltage clamp, and changes in presynaptic Ca2+ influx were determined with the Ca(2+)-sensitive dye furaptra. We manipulated presynaptic Ca2+ entry by altering external Ca2+ levels and by blocking Ca2+ channels with Cd2+ or with the toxins omega-conotoxin GVIA and omega-Aga-IVA. For all of the manipulations, other than the application of omega-Aga-IVA, the relationship between Ca2+ influx and release was well approximated by a power law, n approximately 2.5. When omega-Aga-IVA was applied, release appeared to be more steeply dependent on Ca2+ (n approximately 4), suggesting that omega-Aga-IVA-sensitive channels are more effective at triggering release. Based on interactive effects of toxins on synaptic currents, we conclude that multiple types of Ca2+ channels synergistically control individual release sites.

GABAB Receptor Inhibition of P-type Ca2+ Channels in Central Neurons

P-type Ca2+ channels in cerebellar Purkinje neurons were inhibited by GABA and the GABAB receptor agonist baclofen. Inhibition of P-type Ca2+ channel current involved changes in voltage dependence and kinetics. Baclofen induced a slow phase of activation and altered tail current kinetics, and inhibition could be partly overcome by large depolarizations. These effects were mimicked by internal application of GTP gamma S, which also made the action of baclofen irreversible. In spinal cord neurons, use of selective channel blockers showed that baclofen inhibited both P-type and N-type Ca2+ channels, but not L-type Ca2+ channels; a high threshold current resistant to blockers of P-type, N-type, and L-type channels was also modulated by baclofen. These results show that stimulation of GABAB receptors in central neurons can modulate P-type Ca2+ channels through a G protein-mediated mechanism similar to the one linked to N-type Ca2+ channels.

Participation of multiple calcium channel types in transmission at single climbing fiber to Purkinje cell synapses

The sensitivity of synaptic transmission to antagonists of different calcium channels was examined at the powerful climbing fiber synapse between neurons from the inferior olive and cerebellar Purkinje cells. In rat brain slices, climbing fibers were activated with extracellular electrodes, and synaptic currents were recorded with whole-cell patch clamp. Dihydropyridines did not discernibly affect synaptic strength. omega-Conotoxin GVIA, a potent antagonist of N-type calcium channels, reduced synaptic currents by an average of 29%. omega-Agatoxin-IVA, a high affinity blocker of P-type calcium channels, reduced synaptic strength by an average of 77%. Together, the two toxins virtually eliminated synaptic transmission (91% inhibition). These results indicate that omega-agatoxin-IVA-sensitive calcium channels play an important role in transmission at the climbing fiber synapse. They also suggest that in single climbing fibers, release is evoked by at least two pharmacologically distinct calcium currents, one sensitive to omega-agatoxin-IVA, the other to omega-conotoxin GVIA.

Block of calcium channels in rat neurons by synthetic ω-Aga-IVA

We investigated block of voltage-dependent Ca channels in freshly dissociated rat central and peripheral neurons by the synthetic peptide ω-Aga-IVA. Synthetic ω-Aga-IVA blocked ∼90% of the high-threshold Ca current in cerebellar Purkinje neurons with an estimated Kd of ∼ 1.5 nM, slightly higher than that determined for block by toxin purified from Agelenopsis aperta venom. At 200 nM, the synthetic peptide blocked a small fraction of current in dorsal root ganglion neurons but had no effect on identified components of current carried by low-threshold T-type channels or by dihydropyridine-sensitive L-type Ca channels. Up to 800 nM synthetic peptide had no effect on the current in sympathetic neurons, carried mainly by ω-conotoxin GVIA-sensitive N-type channels. In spinal cord neurons, the same fraction of high-threshold current was blocked by synthetic peptide or purified toxin. We conclude that synthetic ω-Aga-IVA has the same high selectivity for blocking P-type Ca channels as does toxin purified from spider venom.

Interactions among toxins that inhibit N-type and P-type calcium channels.

A number of peptide toxins from venoms of spiders and cone snails are high affinity ligands for voltage-gated calcium channels and are useful tools for studying calcium channel function and structure. Using whole-cell recordings from rat sympathetic ganglion and cerebellar Purkinje neurons, we studied toxins that target neuronal N-type (CaV2.2) and P-type (CaV2.1) calcium channels. We asked whether different toxins targeting the same channels bind to the same or different sites on the channel. Five toxins (ω-conotoxin-GVIA, ω-conotoxin MVIIC, ω-agatoxin-IIIA, ω-grammotoxin-SIA, and ω-agatoxin-IVA) were applied in pairwise combinations to either N- or P-type channels. Differences in the characteristics of inhibition, including voltage dependence, reversal kinetics, and fractional inhibition of current, were used to detect additive or mutually occlusive effects of toxins. Results suggest at least two distinct toxin binding sites on the N-type channel and three on the P-type channel. On N-type channels, results are consistent with blockade of the channel pore by ω-CgTx-GVIA, ω-Aga-IIIA, and ω-CTx-MVIIC, whereas grammotoxin likely binds to a separate region coupled to channel gating. ω-Aga-IIIA produces partial channel block by decreasing single-channel conductance. On P-type channels, ω-CTx-MVIIC and ω-Aga-IIIA both likely bind near the mouth of the pore. ω-Aga-IVA and grammotoxin each bind to distinct regions associated with channel gating that do not overlap with the binding region of pore blockers. For both N- and P-type channels, ω-CTx-MVIIC binding produces complete channel block, but is prevented by previous partial channel block by ω-Aga-IIIA, suggesting that ω-CTx-MVIIC binds closer to the external mouth of the pore than does ω-Aga-IIIA.

ALTERATION OF P-TYPE CALCIUM CHANNEL GATING BY THE SPIDER TOXIN OMEGA -AGA-IVA

We studied the mechanism of inhibition of P-type calcium channels in rat cerebellar Purkinje neurons by the peptide toxin omega-Aga-IVA. Saturating concentrations of omega-Aga-IVA (> 50 nM) inhibited inward current carried by 2-5 mM Ba almost completely. However, outward current at depolarizations of > +60 mV, carried by internal Cs, was inhibited much less, as was the tail current after such depolarizations. omega-Aga-IVA shifted the midpoint of the tail current activation curve by about +50 mV and made the curve less steep. The inactivation curve was also shifted in the depolarized direction and was made less steep. With omega-Aga-IVA, channels activated more slowly and deactivated more quickly than in control. Trains of repeated large depolarizations relieved the inhibition of current (as tested with moderate depolarizations), probably reflecting the unbinding of toxin. The relief of inhibition was faster with increasing depolarization, but did not require internal permeant ions. We conclude that omega-Aga-IVA alters voltage-dependent gating by stabilizing closed states of the channel and that omega-Aga-IVA dissociates much more rapidly from open channels than from closed.