A rare schizophrenia risk variant of CACNA1I disrupts CaV3.3 channel activity.

CACNA1I is a candidate schizophrenia risk gene. It encodes the pore-forming human CaV3.3 α1 subunit, a subtype of voltage-gated calcium channel that contributes to T-type currents. Recently, two de novo missense variations, T797M and R1346H, of hCaV3.3 were identified in individuals with schizophrenia. Here we show that R1346H, but not T797M, is associated with lower hCaV3.3 protein levels, reduced glycosylation, and lower membrane surface levels of hCaV3.3 when expressed in human cell lines compared to wild-type. Consistent with our biochemical analyses, whole-cell hCaV3.3 currents in cells expressing the R1346H variant were ~50% of those in cells expressing WT hCaV3.3, and neither R1346H nor T797M altered channel biophysical properties. Employing the NEURON simulation environment, we found that reducing hCaV3.3 current densities by 22% or more eliminates rebound bursting in model thalamic reticular nucleus (TRN) neurons. Our analyses suggest that a single copy of Chr22: 39665939G > A CACNA1I has the capacity to disrupt CaV3.3 channel-dependent functions, including rebound bursting in TRN neurons, with potential implications for schizophrenia pathophysiology.

Neuronal Ca(V)1.3alpha(1) L-type channels activate at relatively hyperpolarized membrane potentials and are incompletely inhibited by dihydropyridines.

L-type calcium channels regulate a diverse array of cellular functions within excitable cells. Of the four molecularly defined subclasses of L-type Ca channels, two are expressed ubiquitously in the mammalian nervous system (Ca(V)1.2alpha(1) and Ca(V)1.3alpha(1)). Despite diversity at the molecular level, neuronal L-type channels are generally assumed to be functionally and pharmacologically similar, i.e., high-voltage activated and highly sensitive to dihydropyridines. We now show that Ca(V)1.3alpha(1) L-type channels activate at membrane potentials approximately 25 mV more hyperpolarized, compared with Ca(V)1.2alpha(1). This unusually negative activation threshold for Ca(V)1.3alpha(1) channels is independent of the specific auxiliary subunits coexpressed, of alternative splicing in domains I-II, IVS3-IVS4, and the C terminus, and of the expression system. The use of high concentrations of extracellular divalent cations has possibly obscured the unique voltage-dependent properties of Ca(V)1.3alpha(1) in certain previous studies. We also demonstrate that Ca(V)1.3alpha(1) channels are pharmacologically distinct from Ca(V)1.2alpha(1). The IC(50) for nimodipine block of Ca(V)1.3alpha(1) L-type calcium channel currents is 2.7 +/- 0.3 microm, a value 20-fold higher than the concentration required to block Ca(V)1.2alpha(1). The relatively low sensitivity of the Ca(V)1.3alpha(1) subunit to inhibition by dihydropyridine is unaffected by alternative splicing in the IVS3-IVS4 linker. Our results suggest that functional and pharmacological criteria used commonly to distinguish among different Ca currents greatly underestimate the biological importance of L-type channels in cells expressing Ca(v)1.3alpha(1).

Alternative splicing in the cytoplasmic II-III loop of the N-type Ca channel alpha 1B subunit: functional differences are beta subunit-specific.

Structural diversity of voltage-gated Ca channels underlies much of the functional diversity in Ca signaling in neurons. Alternative splicing is an important mechanism for generating structural variants within a single gene family. In this paper, we show the expression pattern of an alternatively spliced 21 amino acid encoding exon in the II-III cytoplasmic loop region of the N-type Ca channel alpha(1B) subunit and assess its functional impact. Exon-containing alpha(1B) mRNA dominated in sympathetic ganglia and was present in approximately 50% of alpha(1B) mRNA in spinal cord and caudal regions of the brain and in the minority of alpha(1B) mRNA in neocortex, hippocampus, and cerebellum (<20%). The II-III loop exon affected voltage-dependent inactivation of the N-type Ca channel. Steady-state inactivation curves were shifted to more depolarized potentials without affects on either the rate or voltage dependence of channel opening. Differences in voltage-dependent inactivation between alpha(1B) splice variants were most clearly manifested in the presence of Ca channel beta(1b) or beta(4), rather than beta(2a) or beta(3), subunits. Our results suggest that exon-lacking alpha(1B) splice variants that associate with beta(1b) and beta(4) subunits will be susceptible to voltage-dependent inactivation at voltages in the range of neuronal resting membrane potentials (-60 to -80 mV). In contrast, alpha(1B) splice variants that associate with either beta(2a) or beta(3) subunits will be relatively resistant to inactivation at these voltages. The potential to mix and match multiple alpha(1B) splice variants and beta subunits probably represents a mechanism for controlling the plasticity of excitation-secretion coupling at different synapses.

Calcium channel activation stabilizes a neuronal calcium channel mRNA.

We have identified a calcium-dependent pathway in neurons that regulates expression levels of the alpha1B subunit and N channel current. When neurons are depolarized and voltage-gated calcium channels activated, the half-life of cellular N channel alpha1B mRNA is prolonged. This stabilizing effect of depolarization is mediated through the 3' untranslated region of a long form of the alpha1B mRNA and may represent a form of modulation of N-channel levels that does not require changes in gene transcription. Increases in N channel expression would affect several key neuronal functions controlled by calcium, including transmitter release and neurite outgrowth.

Alternative splicing of a short cassette exon in alpha1B generates functionally distinct N-type calcium channels in central and peripheral neurons.

The N-type Ca channel alpha1B subunit is localized to synapses throughout the nervous system and couples excitation to release of neurotransmitters. In a previous study, two functionally distinct variants of the alpha1B subunit were identified, rnalpha1B-b and rnalpha1B-d, that differ at two loci;four amino acids [SerPheMetGly (SFMG)] in IIIS3-S4 and two amino acids [GluThr (ET)] in IVS3-S4. These variants are reciprocally expressed in rat brain and sympathetic ganglia (). We now show that the slower activation kinetics of rnalpha1B-b (DeltaSFMG/+ET) compared with rnalpha1B-d (+SFMG/DeltaET) channels are fully accounted for by the insertion of ET in IVS3-S4 and not by the lack of SFMG in IIIS3-S4. We also show that the inactivation kinetics of these two variants are indistinguishable. Through genomic analysis we identify a six-base cassette exon that encodes the ET site and with ribonuclease protection assays demonstrate that the expression of this mini-exon is essentially restricted to alpha1B RNAs of peripheral neurons. We also show evidence for regulated alternative splicing of a six-base exon encoding NP in the IVS3-S4 linker of the closely related alpha1A gene and establish that residues NP can functionally substitute for ET in domain IVS3-S4 of alpha1B. The selective expression of functionally distinct Ca channel splice variants of alpha1B and alpha1A subunits in different regions of the nervous system adds a new dimension of diversity to voltage-dependent Ca signaling in neurons that may be important for optimizing action potential-dependent transmitter release at different synapses.

Identification of functionally distinct isoforms of the N-type Ca2+ channel in rat sympathetic ganglia and brain.

The N channel is critical for regulating release of neurotransmitter at many synapses, and even subtle differences in its activity would be expected to influence the efficacy of synaptic transmission. Although several splice variants of the N channel are expressed in the mammalian nervous system, their biological importance is presently unclear. Here, we show that variants of the alpha1B subunit of the N channel are expressed in sympathetic ganglia and that alternative splicing within IIIS3-S4 and IVS3-S4 generate kinetically distinct channels. We further show a striking difference between the expression pattern of the S3-S4 variants in brain and peripheral ganglia and conclude that the brain-dominant form of the N channel gates 2-to-4-fold more rapidly than that predominant in ganglia.

The molecular identity of Ca channel alpha 1-subunits expressed in rat sympathetic neurons.

Much of our understanding of the mechanisms of the gating, modulation, and function of neuronal Ca channels has its origins in investigations of sympathetic neurons. In this article, we use molecular analyses to identify the three Ca channel alpha 1-subunits that are the likely counterparts to the pharmacologically defined: omega-Conotoxin GVIA-sensitive N-type; dihydropyridine-sensitive L-type, and omega-Conotoxin GVIA-insensitive, dihydropyridine-insensitive Ca channel currents observed in sympathetic neurons. With a combination of degenerate and exact primers, small regions of Ca channel alpha 1-subunit sequences were amplified by the polymerase chain reaction (PCR). Although all five Ca channel alpha 1-subunit genes were expressed in rat sympathetic ganglia, alpha 1B-, alpha 1D-, and alpha 1E-derived cDNAs were the dominant species. No novel Ca channel alpha 1-sequences were identified in the regions selected for amplification, and we conclude that alpha 1B, alpha 1D, and alpha 1E likely encode, respectively, N-type, L-type, and non-N/non-L-type channel currents of rat sympathetic neurons. In addition, we show that Ca channel beta 2-, beta 3-, and beta 4-subunit sequences are strongly represented in sympathetic ganglia. The results of this study also suggest that alpha 1D, and not alpha 1C, regulates Ca influx through dihydropyridine-sensitive Ca channel currents.

Multiple modes of N-type calcium channel activity distinguished by differences in gating kinetics.

In many neurons, N-type Ca2+ channels are a major Ca2+ entry pathway and strongly influence neurotransmitter release. We carried out cell-attached patch recordings (110 mM Ba2+ as charge carrier) to characterize the rapid opening and closing kinetics of N-type Ca2+ channel gating in frog sympathetic neurons. Single channels display at least three distinct patterns of gating, characterized as low-, medium-, and high-rho o modes on the basis of channel open probability (rho o) during depolarizing pulses to -10 mV. Spontaneous transitions from one mode to another are infrequent, with an exponential distribution of dwell times and mean sojourns of approximately 10 sec in each mode. Thus, a channel typically undergoes hundreds or thousands of open-closed transitions in one mode before switching to a different mode. Transitions between modes during a depolarization were occasionally detected, but were rare, as expected for infrequent modal switching. Within each mode, the activation kinetics were well described by a simple scheme (C2-C1-O), as previously reported for other types of Ca2+ channels. Rate constants are strikingly different from one mode to another, giving each mode its own characteristic kinetic signature. The gating behavior at -10 mV ranges from brief openings (approximately 0.3 msec) and long closures (10-20 msec) for low-rho o gating to long openings (3 msec) and brief closures (approximately 1 msec) for high-rho o gating. Intermediate values for mean open durations (approximately 1.5 msec) and mean closed durations (approximately 3 msec) were found for medium-rho o gating. In addition to being kinetically distinct, channel openings in the low-rho o mode often exhibit a unitary current approximately 0.2 pA larger than in the medium- or high-rho o mode. Each mode is characterized by its own voltage dependence: activation occurs at relatively negative potentials and is most steeply voltage dependent in the high-rho o mode, while activation requires very strong depolarizations and is weakly voltage dependent in the low-rho o mode. The proportion of time spent in the individual modes varies greatly from one patch to another, suggesting that modal gating may be subject to cellular control.

Alpha-adrenergic inhibition of sympathetic neurotransmitter release mediated by modulation of N-type calcium-channel gating.

In sympathetic neurons, catecholamines interact with prejunctional alpha-adrenergic receptors to reduce delivery of transmitter to postjunctional target organs. This autoinhibitory feedback is a general phenomenon seen in diverse neurons containing a variety of transmitters. The underlying mechanisms of alpha-adrenergic inhibition are not clear, although decreases in cyclic AMP and cAMP-mediated phosphorylation have been implicated. We have studied depolarization-induced catecholamine release and calcium-channel currents in frog sympathetic neurons. Here we show that alpha-adrenergic inhibition of transmitter release can be explained by inhibition of Ca2+-channel currents and not by modulation of intracellular proteins. Noradrenaline strongly reduces the activity of N-type Ca2+ channels, the dominant calcium entry pathway triggering sympathetic transmitter release, whereas L-type Ca2+ channels are not significantly inhibited. The down-modulation of N-type channels involves changes in rapid gating kinetics but not in unitary flux. This is the first detailed description of inhibition of a high-voltage activated neuronal Ca2+ channel at the single-channel level. The coupling between alpha-adrenergic receptors and N-type channels involves a G protein, but not a readily diffusible cytoplasmic messenger or protein kinase C, and may be well suited for rapid and spatially localized feedback-control of transmitter release.

Nicotinic receptors of frog ganglia resemble pharmacologically those of skeletal muscle.

The actions of ACh antagonists were studied on synaptic currents of autonomic ganglia of the frog. Fast excitatory synaptic currents (ESCs) were recorded from cardiac and paravertebral neurons with the use of the 2-microelectrode voltage-clamp method. The actions of 4 ACh antagonists, tubocurarine, hexamethonium, trimetaphan, and decamethonium were studied. Tubocurarine was effective at reducing the peak amplitude of ESCs (50% inhibition at 3 microM). In contrast, tubocurarine (1-30 microM) reduced the time constant of ESC decay by only 9% compared with controls. Both of these effects of tubocurarine were independent of membrane potential. Hexamethonium was a weak inhibitor of ESCs; at 600 microM peak amplitude was reduced only to about 60% of controls and decay time constants were unaffected at concentrations between 10 and 600 microM. These effects of tubocurarine and hexamethonium are consistent with these drugs being receptor antagonists with no evidence of ion channel block. Trimetaphan (3-100 microM) and decamethonium (100 microM) reduced the peak amplitude of ESCs. In the presence of 100 microM trimetaphan or 10 microM decamethonium, ESC decays were biexponential. The 2 exponential components induced by the presence of these drugs were faster and slower, respectively, than the single-exponential component of control ESC decays. The effects of these 2 drugs were more pronounced at hyperpolarized potentials and are consistent with a channel-blocking action. The actions of the 4 ACh antagonists on frog autonomic ganglia are similar to their effects at the neuromuscular junction but dissimilar to their effects on the rat submandibular ganglion.(ABSTRACT TRUNCATED AT 250 WORDS)

Imaging of cytosolic Ca2+ transients arising from Ca2+ stores and Ca2+ channels in sympathetic neurons.

Changes in cytosolic free Ca2+ concentration [( Ca2+]i) due to Ca2+ entry or Ca2+ release from internal stores were spatially resolved by digital imaging with the Ca2+ indicator fura-2 in frog sympathetic neurons. Electrical stimulation evoked a rise in [Ca2+]i spreading radially from the periphery to the center of the soma. Elevated [K+]o also increased [Ca2+]i, but only in the presence of external Ca2+, indicating that Ca2+ influx through Ca2+ channels is the primary event in the depolarization response. Ca2+ release or uptake from caffeine-sensitive internal stores was able to amplify or attenuate the effects of Ca2+ influx, to generate continued oscillations in [Ca2+]i, and to persistently elevate [Ca2+]i above basal levels after the stores had been Ca2(+)-loaded.

Spatial distribution of calcium channels and cytosolic calcium transients in growth cones and cell bodies of sympathetic neurons.

Ca2+ imaging and single-channel recording were used to study the regulation of cytosolic free Ca2+ ([Ca2+]i) in local regions of frog sympathetic neurons. Digital imaging with the fluorescent Ca2+ indicator fura-2 demonstrated: (i) resting [Ca2+]i of 70-100 nM; (ii) significant increases in [Ca2+]i in growth cones and cell bodies following depolarization induced by extracellular electrical stimulation or increased external K+; (iii) in cell bodies, large transient increases in [Ca2+]i following exposure to caffeine and sustained oscillations in [Ca2+]i in the presence of elevated K+ and caffeine; and (iv) in growth cones, smaller and briefer changes in [Ca2+]i in response to caffeine. The nature of the depolarization-induced Ca2+ entry was studied with cell-attached patch recordings (110 mM Ba2+ in recording pipette). Ca2+ channel activity was observed in 18 of 20 patches on cell bodies, 3 of 5 patches along neurites, and 36 of 41 patch recordings from growth cones. We observed two types of Ca2+ channels: L-type channels, characterized by a 28-pS slope conductance, sensitivity to dihydropyridine Ca2+ channel agonist, and availability even with depolarizing holding potentials; and N-type channels, characterized by a 15-pS slope conductance, resistance to dihydropyridines, and inactivation with depolarized holding potentials. Both types of channels were found on growth cones and along neurites as well as on cell bodies; channels often appeared concentrated in local hot spots, sometimes dominated by one channel type.