Timothy J. Turner

Exocytotic Ca2+ channels in mammalian central neurons

Intracellular Ca2+ initiates physiological events as diverse as gene transcription, muscle contraction, cell division and exocytosis. Predictably, the metabolic machinery that elicits and responds to changes in intracellular Ca2+ is correspondingly heterogeneous. This review focuses on one element of this complex web that is of particular importance to neurobiologists: identifying which members of the voltage-dependent Ca(2+)-channel superfamily are responsible for the Ca2+ that enters nerve terminals and elicits vesicular release of chemical transmitters.

Multiple calcium channel types control glutamatergic synaptic transmission in the hippocampus

N-type calcium channels play a dominant role in controlling synaptic transmission in many peripheral neurons. Transmitter release from mammalian central nerve terminals, however, is relatively resistant to the N channel antagonist omega-conotoxin GVIA. We studied the sensitivity of glutamatergic synaptic transmission in rat hippocampal slices to omega-conotoxin and to omega-Aga-IVA, a P channel antagonist. Both toxins reduced the amplitude of excitatory postsynaptic potentials in CA1 pyramidal neurons, but omega-Aga-IVA was the more rapid and efficacious. These results were corroborated by biochemical studies measuring subsecond, calcium-dependent [3H]glutamate release from hippocampal synaptosomes. Thus, at least two calcium channel types trigger glutamate release from hippocampal neurons, but P-type plays a more prominent role. Eliminating synaptic transmission in the CNS, therefore, may require inhibiting more than a single calcium channel type.

Selective attenuation of psychostimulant-induced behavioral responses in mice lacking A2A adenosine receptors

A(2A) adenosine receptors are highly expressed in the striatum where they modulate dopaminergic activity. The role of A(2A) receptors in psychostimulant action is less well understood because of the lack of A(2A)-selective compounds with access to the central nervous system. To investigate the A(2A) adenosinergic regulation of psychostimulant responses, we examined the consequences of genetic deletion of A(2A) receptors on psychostimulant-induced behavioral responses. The extent of dopaminergic innervation and expression of dopamine receptors in the striatum were indistinguishable between A(2A) receptor knockout and wild-type mice. However, locomotor responses to amphetamine and cocaine were attenuated in A(2A) knockout mice. In contrast, D(1)-like receptor agonists SKF81297 and SKF38393 produced identical locomotor stimulation and grooming, respectively, in wild-type and A(2A) knockout mice. Similarly, the D(2)-like agonist quinpirole produced motor-depression and stereotypy that were indistinguishable between A(2A) knockout and wild-type mice. Furthermore, attenuated amphetamine- (but not SKF81297-) induced locomotion was observed in pure 129-Steel as well as hybrid 129-SteelxC57BL/6 mice, confirming A(2A) receptor deficiency (and not genetic background) as the cause of the blunted psychostimulant responses in A(2A) knockout mice. These results demonstrate that A(2A) receptor deficiency selectively attenuates psychostimulant-induced behavioral responses and support an important role for the A(2A) receptor in modulating psychostimulant effects.

Pharmacological characterization of presynaptic calcium channels using subsecond biochemical measurements of synaptosomal neurosecretion

The recent development of peptide antagonists that selectively block subtypes of neuronal calcium channel has provided tools to study the role of presynaptic calcium channels in triggering exocytosis. A variety of methods have consistently demonstrated that multiple channel types participate in exocytosis. We have studied the subsecond kinetics of [3H]glutamate release from rat cortical synaptosomes as an assay for presynaptic calcium channel activity. The system has been characterized over a broad range of conditions in an effort to compare biochemical measurements of transmitter release with electrophysiological measurements of synaptic currents. The efficacies of omega-agatoxin IVA and omega-conotoxins GVIA and MVIIC were increased when Ca2+ influx was decreased by: (1) decreasing the KCl concentration to diminish the extent of depolarization, (2) decreasing the Ca2+ concentration, or (3) partially blocking Ca2+ influx with one of the other antagonists. By using these toxins in combination, we found that at least three types of pharmacologically distinct channel participate in exocytosis. The largest fraction of glutamate release is blocked by omega-agatoxin IVA (IC50 = 12.2 nM) and by omega-conotoxin MVIIC (IC50 = 35 nM), consistent with the pharmacology of a P type channel. The effects of saturating concentrations (1 microM) of omega-agatoxin IVA or omega-conotoxin MVIIC occlude each other, suggesting that these peptides overlap completely. The specific N type antagonist omega-conotoxin GVIA inhibits a significant portion of release (IC50 less than 1 nM) but only under conditions of reduced Ca2+ concentration. These results suggest that the N type channel in nerve terminals is distinct from that found in hippocampal somata, since it appears to be resistant to by omega-conotoxin MVIIC. The combination of omega-conotoxin GVIA (100 nM) and either omega-agatoxin IVA or omega-conotoxin MVIIC (1 microM each) blocked approx 90% of release when the Ca2+ concentration was reduced (0.46 mM or less), but 30-40% of release remained when the concentration of Ca2+ in the stimulus buffer was 1 mM or greater, indicating that a resistant channel type(s) also participates in exocytosis. Specific inhibitors of this resistant phenotype will be useful for further refinement of our understanding of the role of presynaptic calcium channels in mediating neurosecretion.

Inositol 1,4,5-Trisphosphate and Calcium Regulate the Calcium Channel Function of the Hepatic Inositol 1,4,5-Trisphosphate Receptor

The regulation of the inositol 1,4,5-trisphosphate (IP3) receptor in liver was analyzed using a novel superfusion method. Hepatic microsomes were loaded with 45Ca2+, and superfused at high flow rates to provide precise control over IP3 and Ca2+ concentrations ([Ca2+]) and to isolate 45Ca2+ release from reuptake. 45Ca2+ release was dependent on both [Ca2+] and IP3. The initial rate of 45Ca2+ release was a biphasic function of [Ca2+], increasing as [Ca2+] approached 3 μM but decreasing at higher concentrations, suggesting that the hepatic IP3 receptor is regulated by [Ca2+] at two sites, a high affinity potentiation site and a low affinity inhibitory site. The relationship between initial rates and IP3 concentration was steep (Hill coefficient of 3.4), suggesting that activation of the calcium channel requires binding of at least 3 IP3 molecules. IP3 concentrations above 10 μM produced rapid decay of release rates, suggesting receptor inactivation. Superfusion with 10 μM IP3 under conditions that minimize calcium release ([Ca2+] < 1 nM) inhibited 45Ca2+ release in response to subsequent stimulation (400 nM Ca2+). These data suggest sequential positive and negative regulation of the hepatic IP3 receptor by cytosolic calcium and by IP3, which may underlie hepatocellular propagation of regenerative, oscillatory calcium signals.

Calcium influx through presynaptic 5-HT3 receptors facilitates GABA release in the hippocampus: in vitro slice and synaptosome studies

Serotonin 5-hydroxytryptamine type 3 receptors (5HT3R) are Ca2+-permeant, non-selective cation channels that have been localized to presynaptic terminals and demonstrated to modulate neurotransmitter release. In the present study the effect of 5-HT on GABA release in the hippocampus was characterized using both electrophysiological and biochemical techniques. 5-HT elicited a burst-like, 6- to 10-fold increase in the frequency of GABAA receptor-mediated inhibitory postsynaptic currents (IPSCs) measured with whole-cell voltage-clamp recordings of CA1 neurons in hippocampal slices. When tetrodotoxin was used to block action potential propagation, the 5-HT-induced burst of IPSCs was still observed. Stimulation of hippocampal synaptosomes with 5-HT resulted in a significant increase in the amount of [3H]GABA released by hyperosmotic saline. In both preparations, the 5-HT effect was shown to be mediated by 5HT3Rs, as it was mimicked by the selective 5HT3R agonist m-chlorophenyl biguanide and blocked by the selective 5HT3R antagonist 3-tropanylindole-3-carboxylate hydrochloride. The 5HT3R-mediated increase in GABA release was blocked by 100 microM cadmium or by omitting Ca2+ in external solutions, indicating the Ca2+-dependence of the effect. The high voltage-activated Ca2+ channel blockers omega-conotoxin GVIA and omega-conotoxin MVIIC and 10 microM cadmium had no significant effect on the 5-HT3R-mediated enhancement of GABA release, indicating that Ca2+ influx through the 5-HT3R facilitates GABA release. Taken together, these data provide direct evidence that Ca2+ entry via presynaptic 5HT3Rs facilitates the release of GABA from hippocampal interneurons.

Enhanced G protein-dependent modulation of excitatory synaptic transmission in the cerebellum of the Ca2+ channel-mutant mouse, tottering.

Tottering, a mouse model for absence epilepsy and cerebellar ataxia, carries a mutation in the gene encoding class A (P/Q‐type) Ca2+ channels, the dominant exocytotic Ca2+ channel at most synapses in the mammalian central nervous system. Comparing tottering to wild‐type mice, we have studied glutamatergic transmission between parallel fibres and Purkinje cells in cerebellar slices. Results from biochemical assays and electrical field recordings demonstrate that glutamate release from parallel fibre terminals of the tottering mouse is controlled largely by class B Ca2+ channels (N‐type), in contrast to the P/Q‐channels that dominate release from wild‐type terminals. Since N‐channels, in a variety of assays, are more effectively inhibited by G proteins than are P/Q‐channels, we tested whether synaptic transmission between parallel fibres and Purkinje cells in tottering mice was more susceptible to inhibitory modulation by G protein‐coupled receptors than in their wild‐type counterparts. GABAB receptors and α2‐adrenergic receptors (activated by bath application of transmitters) produced a three‐ to fivefold more potent inhibition of transmission in tottering than in wild‐type synapses. This increased modulation is likely to be important for cerebellar transmission in vivo, since heterosynaptic depression, produced by activating GABAergic interneurones, greatly prolonged GABAB receptor‐mediated presynaptic inhibition in tottering as compared to wild‐type slices. We propose that this enhanced modulation shifts the balance of synaptic input to Purkinje cells in favour of inhibition, reducing Purkinje cell output from the cerebellum, and may contribute to the aberrant motor phenotype that is characteristic of this mutant animal.

Chapter 1 Calcium channels coupled to glutamate release

Publisher Summary This chapter reviews the current understanding of the properties of presynaptic calcium channels and considers how defects in the channels or their interactions might result in pathological abnormalities. Voltage-gated calcium channels stand as the pivotal regulatory element of excitation–secretion coupling at nerve endings in brain. Recent advancement has resulted in an explosive increase in information about the identity of both the calcium channels and the proteins that comprise the neurosecretory machinery. Analysis of calcium channel gene expression has revealed numerous related genes, each of which with splice variants that, in principle, could amount to impressive combinatorial possibilities. The nerve terminal is of particular importance to neuroscientists, because it is the cellular locus where electrical information is transduced to intercellular chemical messages, and calcium channels play a pivotal role in this transduction. Calcium channels, by virtue of regulating excitation–secretion coupling, provide an attractive target for pharmacological management of neuronal activity.

Prolonged time course of glutamate release from nerve terminals : relationship between stimulus duration and the secretory event

Abstract: The kinetics of synaptosomal [3H]glutamate release were measured on a subsecond time scale to study the relationship between the length of depolarization and the duration of the secretory event. The time course of release evoked by elevated K+ was complex, proceeding for several seconds after a 200‐ms depolarization. We developed a protocol for depolarizing excitable membranes on a millisecond time scale to deliver brief depolarizations, termed the synthetic action potential, by using batrachotoxin to activate Na+ channels. Depolarization is achieved by superfusing with solutions containing elevated concentrations of Na+, and the duration of the depolarization is limited by including tetrodotoxin (TTX) in the superfusion solution to block Na+ entry. Direct measurements of the time courses of Na+ current and membrane depolarizations were made in batrachotoxin‐treated sensory neurons using patch clamp recording methods. Rapid increases in Na+ and TTX concentrations produced transient increases in inward Na+ current that decayed with a time course proportional to TTX concentration. Current clamp measurements indicated that, with 10 µM TTX, depolarizations last ∼30 ms. Nonetheless, synaptosomal release of [3H]glutamate triggered by the synthetic action potential remained prolonged. Brief neuronal action potentials at some synapses may trigger transmitter release that persists for several seconds.

Pertussis Toxin-Sensitive GTP-Binding Proteins Characterized in Synaptosomal Fractions of Embryonic Avian Cerebral Cortex

Pertussis toxin (PTX)-sensitive GTP-binding proteins (G proteins) are essential intermediaries subserving neuronal signal transduction pathways that regulate excitation-secretion coupling. Despite this established role, relatively little is known regarding the identity, subcellular distribution, and relative abundance of this class of G proteins in synaptic nerve endings. Here, sucrose density gradient centrifugation was combined with 1- and 2-dimensional gel electrophoresis to characterize PTX-sensitive G protein alpha subunits in synaptosomal fractions of embryonic (day 12) chick cerebral cortical homogenates. These findings demonstrate multiple isoforms of M(r) 40-41 kDa Gi alpha and G(o) alpha subunits that can be identified on the basis of PTX-catalyzed ADP-ribosylation and immunoblot analysis.