Differential distribution of three members of a gene family encoding low voltage-activated (T-type) calcium channels

Block of T-Type Ca2+ Channels Is an Important Action of Succinimide Antiabsence Drugs

The role of calcium channel blockade in the antiepileptic action of ethosuximide is controversial, especially regarding the potency and efficacy of block. However, recent evidence obtained from transgenic animals and heterologous expression systems supports a major role of T-type calcium channels in both the generation of absence seizures and the action of ethosuximide in human absence epilepsy.

Block of T -Type Ca(2+) Channels Is an Important Action of Succinimide Antiabsence Drugs

The role of calcium channel blockade in the antiepileptic action of ethosuximide is controversial, especially regarding the potency and efficacy of block. However, recent evidence obtained from transgenic animals and heterologous expression systems supports a major role of T-type calcium channels in both the generation of absence seizures and the action of ethosuximide in human absence epilepsy.

Reversible peripheral neuropathy in idiopathic hypoparathyroidism

We describe a 40-year-old male with idiopathic hypoparathyroidism presenting with tetany, proximal weakness, signs of hypocalcaemia including Chvostek and Trousseau's and diminished tendon reflexes in the upper and lower limbs. Electrophysiological studies revealed a sensory-motor neuropathy, predominantly axonal as evidenced by decreased CMAP amplitudes, with normal distal latencies-velocites, except for median nerve where a prolonged distal latency was observed. Serial nerve conduction studies were performed at repeated intervals for 2 years, while he received treatment for hypoparathyroidism (calcium and vitamin D supplementation). A progressive improvement in neuropathy both clinical and on electrophysiological studies was observed. Occurrence of peripheral neuropathy in hypocalcaemic states such as hypoparathyroidism and its reversibility after normalization of calcium homeostasis lend proof to the role of critical Ca2+ ion concentration in the normal functioning of the peripheral axons.

Differential and age-dependent expression of hyperpolarization-activated, cyclic nucleotide-gated cation channel isoforms 1-4 suggests evolving roles in the developing rat hippocampus

Hyperpolarization-activated cation currents (I(h)) are found in several brain regions including thalamus and hippocampus. Important functions of these currents in promoting synchronized network activity and in determining neuronal membrane properties have been progressively recognized, but the molecular underpinnings of these currents are only emerging. I(h) currents are generated by hyperpolarization-activated, cyclic nucleotide-gated cation channels (HCNs). These channel proteins are encoded by at least four HCN genes, that govern the kinetic and functional properties of the resulting channels. Because of the potential impact of I(h)-mediated coordinated neuronal activity on the maturation of the functional hippocampal network, this study focused on determining the expression of the four members of the HCN gene family throughout postnatal hippocampal development at both the regional and single cell level.The results of these experiments demonstrated that HCNs 1, 2 and 4 are differentially expressed in interneuronal and principal cell populations of the rat hippocampal formation. Expression profiles of each HCN isoform evolve during postnatal development, and patterns observed during early postnatal ages differ significantly from those in mature hippocampus. The onset of HCN expression in interneurons of the hippocampus proper precedes that in the dentate gyrus, suggesting that HCN-mediated pacing activity may be generated in hippocampal interneurons prior to those in the hilus. Taken together, these findings indicate an age-dependent spatiotemporal evolution of specific HCN expression in distinct hippocampal cell populations, and suggest that these channels serve differing and evolving functions in the maturation of coordinated hippocampal activity.

Changes in voltage-gated calcium channel alpha(1) gene expression in rat dorsal root ganglia following peripheral nerve injury

Although an increase in the excitability and ectopic spontaneous discharge (ESD) of primary sensory neurons can lead to abnormal burst activity, which is associated with neuropathic pain, the underlying molecular mechanisms are not fully understood. To investigate the relationship between these electrical abnormalities in injured neurons and voltage-gated calcium channel (VGCC) gene expression, reverse transcription-polymerase chain reaction (RT-PCR) was used to monitor the expression of the VGCC alpha(1) gene in the dorsal root ganglion (DRG) following chronic constriction injury (CCI) and axotomy of the rat sciatic nerve. Electrophoresis of the RT-PCR products showed the presence of multiple types of VGCC alpha(1) transcripts with various levels of basal expression in lumbar 4, 5, and 6 DRGs. CCI decreased alpha(1C), alpha(1D), alpha(1H), and alpha(1I) mRNA expression at 7 days in the ipsilateral DRG, to approximately 34-50% of the contralateral side. The same transcripts were repressed 7 days after sciatic axotomy and their reduction levels proved similar to those of CCI. Considering that changes of the intracellular calcium concentration modify the maintenance of ESD in injured DRG, these results suggest that the downregulation of alpha(1C), alpha(1D), alpha(1H) and alpha(1I) subunit gene expression in the rat DRG following peripheral nerve injury may contribute to the production of ESD associated with damaged nerves.

The alpha1I T-type calcium channel exhibits faster gating properties when overexpressed in neuroblastoma/glioma NG 108-15 cells

The recently cloned T-type calcium channel alpha1I (Cav3.3) displays atypically slow kinetics when compared to native T-channels. Possible explanations might involve alternative splicing of the alpha1I subunit, or the use of expression systems that do not provide a suitable environment (auxiliary subunit, phosphorylation, glycosylation...). In this study, two human alpha1I splice variants, the alpha1I-a and alpha1I-b isoforms that harbour distinct carboxy-terminal regions were studied using various expression systems. As the localization of the alpha1I subunit is primarily restricted to neuronal tissues, its functional expression was conducted in the neuroblastoma/glioma cell line NG 108-15, and the results compared to those obtained in HEK-293 cells and Xenopus oocytes. In Xenopus oocytes, both isoforms exhibited very slow current kinetics compared to those obtained in HEK-293 cells, but the alpha1I-b isoform generated faster currents than the alpha1I-a isoform. Both activation and inactivation kinetics of alpha1I currents were significantly faster in NG 108-15 cells, while deactivating tail currents were two times slower, compared to those obtained in HEK-293 cells. Moreover, the alpha1-b isoform showed significantly slower deactivation kinetics both in NG 1080-15 and in HEK-293 cells. Altogether, these data emphasize the advantage of combining several expression systems to reveal subtle differences in channel properties and further indicate that the major functional differences between both human alpha1I isoforms are related to current kinetics. More importantly, these data suggest that the expression of the alpha1I subunit in neuronal cells contributes to the "normalization" of current kinetics to the more classical, fast-gated T-type Ca2+ current.

Gating kinetics of the alpha1I T-type calcium channel

The alpha1I T-type calcium channel inactivates almost 10-fold more slowly than the other family members (alpha1G and alpha1H) or most native T-channels. We have examined the underlying mechanisms using whole-cell recordings from rat alpha1I stably expressed in HEK293 cells. We found several kinetic differences between alpha1G and alpha1I, including some properties that at first appear qualitatively different. Notably, alpha1I tail currents require two or even three exponentials, whereas alpha1G tails were well described by a single exponential over a wide voltage range. Also, closed-state inactivation is more significant for alpha1I, even for relatively strong depolarizations. Despite these differences, gating of alpha1I can be described by the same kinetic scheme used for alpha1G, where voltage sensor movement is allosterically coupled to inactivation. Nearly all of the rate constants in the model are 5-12-fold slower for alpha1I, but the microscopic rate for channel closing is fourfold faster. This suggests that T-channels share a common gating mechanism, but with considerable quantitative variability.

T-type Ca(2+) channels mediate neurotransmitter release in retinal bipolar cells

Transmitter release in neurons is thought to be mediated exclusively by high-voltage-activated (HVA) Ca(2+) channels. However, we now report that, in retinal bipolar cells, low-voltage-activated (LVA) Ca(2+) channels also mediate neurotransmitter release. Bipolar cells are specialized neurons that release neurotransmitter in response to graded depolarizations. Here we show that these cells express T-type Ca(2+) channel subunits and functional LVA Ca(2+) currents sensitive to mibefradil. Activation of these currents results in Ca(2+) influx into presynaptic terminals and exocytosis, which we detected as a capacitance increase in isolated terminals and the appearance of reciprocal currents in retinal slices. The involvement of T-type Ca(2+) channels in bipolar cell transmitter release may contribute to retinal information processing.

Aldosterone increases T-type calcium currents in human adrenocarcinoma (H295R) cells by inducing channel expression

In adrenal glomerulosa cells, low-threshold voltage-activated (T-type) calcium channels are known to play a crucial role in coupling physiological variations of extracellular potassium to aldosterone biosynthesis. On the other hand, aldosterone itself has been recently shown to regulate Ca(2+) currents in its target cells. In the present study, we have investigated the effect of aldosterone on Ca(2+) channels of the steroidogenic human adrenocarcinoma cell line, using both electrophysiological and molecular techniques. Cell incubation with aldosterone (1 microM) for 24 h increased by 39% the density of T-type calcium currents, as assessed with the patch clamp technique. This effect of aldosterone was not related to a modification of T channel activation and inactivation properties. In contrast, L-type calcium currents remained unaffected by aldosterone treatment. The mineralocorticoid receptor antagonist, spironolactone, blunted the aldosterone-induced increase in T-type calcium current. By RT-PCR, we detected in human adrenocarcinoma cells the presence of mRNA coding for the alpha(1) subunits of three different calcium channels: the alpha(1)H isoform of T channels and the alpha(1)C and alpha(1)D isoforms of the L channels. The presence of mRNA coding for the mineralocorticoid receptor was also found in these cells. Aldosterone treatment induced a 36% increase of mRNA coding for alpha(1)H, as assessed by real-time PCR. This aldosterone-evoked stimulation of mRNA expression was maximal at 24-48 h and reversed by spironolactone, suggesting a receptor-mediated genomic effect of aldosterone. Pregnenolone production in response to KCl stimulation was increased after aldosterone treatment, in parallel to T channel expression, confirming the essential role of these channels in the steroidogenic response to potassium. Taken together, these data indicate that, in human adrenocarcinoma cells, aldosterone increases, through an autocrine pathway, the expression of T-type calcium channels and therefore modifies the ability of these cells to respond to steroidogenic agonists.

Expression of voltage-gated calcium channel subunits in rat dorsal root ganglion neurons

In the present study, we have used in situ hybridisation to examine the distribution of calcium channel subunits in rat dorsal root ganglion (DRG) neurons. Within DRG neurons, the calcium channel alpha subunit mRNAs alpha(1A), alpha(1B), alpha(1C), alpha(1D), alpha(1E), alpha(1I) and alpha(1S) were readily detected in small (<25 microm), medium (25-45 microm) and large (>45 microm) diameter neurons. alpha(1F) was present at very low levels in these neurons whilst alpha(1G) was virtually undetectable. The calcium channel auxiliary subunits alpha(2)delta(1) and alpha(2)delta(2) showed a complementary pattern of distribution to that of alpha(2)delta(3) in DRG neurons. alpha(2)delta(1) and alpha(2)delta(2) transcripts were expressed predominantly in small c-type sensory neurons and were present at lower levels in large Abeta-type sensory neurons. In contrast, alpha(2)delta(3) mRNA was present in high quantities in the large-diameter cells but was expressed at lower levels in small-diameter neurons of the DRG. The present study provides an insight into the molecular profile of calcium channel alpha(1) and alpha(2)delta subunits in the neurons responsible for transmitting sensory information.

Pharmacological and biophysical characterization of voltage-gated calcium currents in the endopiriform nucleus of the guinea pig

The endopiriform nucleus (EPN) is a well-defined structure that is located deeply in the piriform region at the border with the striatum and is characterized by dense intrinsic connections and prominent projections to piriform and limbic cortices. The EPN has been proposed to promote synchronization of large populations of neurons in the olfactory cortices via the activation of transient depolarizations possibly mediated by Ca(2+) spikes. It is known that principal cells in the EPN express both a low- and high-voltage-activated (HVA) Ca(2+) currents. We further characterized HVA conductances possibly related to Ca(2+)-spike generation in the EPN with a whole cell, patch-clamp study on neurons acutely dissociated from the EPN of the guinea pig. To study HVA currents in isolation, experiments were performed from a holding potential of -60 mV, using Ba(2+) as the permeant ion. Total Ba(2+) currents (I(Ba)) evoked by depolarizing square pulses peaked at 0/+10 mV and were completely abolished by 200 microM Cd(2+). The pharmacology of HVA I(Ba)s was analyzed by applying saturating concentrations of specific Ca(2+)-channel blockers. The L-type blocker nifedipine (10 microM; n = 11), the N-type-channel blocker omega-conotoxin GVIA (0.5 microM; n = 24), and the P/Q-type blocker omega-conotoxin MVIIC (1 microM; n = 16) abolished fractions of total I(Ba)s equal on average to 24.7 +/- 5.4%, 27.1 +/- 3.4%, and 22.2 +/- 2.4%, respectively (mean +/- SE). The simultaneous application of the three blockers reduced I(Ba) by 68.5 +/- 6.6% (n = 10). Nifedipine-sensitive currents and most N- and P/Q-type currents were slowly decaying, the average fractional persistence after 300 ms of steady depolarization being 0.77 +/- 0.02, 0.60 +/- 0.06, and 0.68 +/- 0.04, respectively. The residual, blocker-resistant (R-type) currents were consistently faster inactivating, with an average fractional persistence after 300 ms of 0.30 +/- 0.08. Fast-decaying R-type currents also displayed a more negative threshold of activation (by about 10 mV) than non-R-type HVA currents. These results demonstrate that EPN neurons express multiple pharmacological components of the HVA Ca(2+) currents and point to the existence of an R-type current with specific functional properties including fast inactivation kinetics and intermediate threshold of activation.

Inositol hexakisphosphate increases L-type Ca2+ channel activity by stimulation of adenylyl cyclase

Inositol hexakisphosphate (InsP6) is a most abundant inositol polyphosphate that changes simultaneously with inositol 1,4,5-trisphosphate in depolarized neurons. However, the role of InsP6 in neuronal signaling is unknown. Mass assay reveals that the basal levels of InsP6 in several brain regions tested are similar. InsP6 mass is significantly elevated in activated brain neurons and lowered by inhibition of neuronal activity. Furthermore, the hippocampus is most sensitive to electrical challenge with regard to percentage accumulation of InsP6. In hippocampal neurons, InsP6 stimulates adenylyl cyclase (AC) without influencing cAMP phosphodiesterases, resulting in activation of protein kinase A (PKA) and thereby selective enhancement of voltage-gated L-type Ca2+ channel activity. This enhancement was abolished by preincubation with PKA and AC inhibitors. These data suggest that InsP6 increases L-type Ca2+ channel activity by facilitating phosphorylation of PKA phosphorylation sites. Thus, in hippocampal neurons, InsP6 serves as an important signal in modulation of voltage-gated L-type Ca2+ channel activity.

Lack of the burst firing of thalamocortical relay neurons and resistance to absence seizures in mice lacking alpha(1G) T-type Ca(2+) channels

T-type Ca(2+) currents have been proposed to be involved in the genesis of spike-and-wave discharges, a sign of absence seizures, but direct evidence in vivo to support this hypothesis has been lacking. To address this question, we generated a null mutation of the alpha(1G) subunit of T-type Ca(2+) channels. The thalamocortical relay neurons of the alpha(1G)-deficient mice lacked the burst mode firing of action potentials, whereas they showed the normal pattern of tonic mode firing. The alpha(1G)-deficient thalamus was specifically resistant to the generation of spike-and-wave discharges in response to GABA(B) receptor activation. Thus, the modulation of the intrinsic firing pattern mediated by alpha(1G) T-type Ca(2+) channels plays a critical role in the genesis of absence seizures in the thalamocortical pathway.

It takes T to tango

Of three recently cloned T-type voltage-gated calcium channels, alpha(1g) is most likely responsible for burst firing in thalamic relay cells. These neurons burst during various thalamocortical oscillations including absence seizures. In this issue of Neuron, Kim et al. inactivated alpha(1g), and resultant mice were deficient in relay cell bursting and resistant to GABA(B) receptor-dependent absence seizures, suggesting roles for alpha(1g) and relay cell bursting in absences.

Redox modulation of T-type calcium channels in rat peripheral nociceptors

Although T-type calcium channels were first described in sensory neurons, their function in sensory processing remains unclear. In isolated rat sensory neurons, we show that redox agents modulate T currents but not other voltage- and ligand-gated channels thought to mediate pain sensitivity. Similarly, redox agents modulate currents through Ca(v)3.2 recombinant channels. When injected into peripheral receptive fields, reducing agents, including the endogenous amino acid L-cysteine, induce thermal hyperalgesia. This hyperalgesia is blocked by the oxidizing agent 5,5'-dithio-bis-(2-nitrobenzoic acid) (DTNB) and the T channel antagonist mibefradil. DTNB alone and in combination with mibefradil induces thermal analgesia. Likewise, L-cysteine induces mechanical DTNB-sensitive hyperalgesia in peripheral receptive fields. These data strongly suggest a role for T channels in peripheral nociception. Redox sites on T channels in peripheral nociceptors could be important targets for agents that modify pain perception.

Cerebellar long-term depression: characterization, signal transduction, and functional roles

Cerebellar Purkinje cells exhibit a unique type of synaptic plasticity, namely, long-term depression (LTD). When two inputs to a Purkinje cell, one from a climbing fiber and the other from a set of granule cell axons, are repeatedly associated, the input efficacy of the granule cell axons in exciting the Purkinje cell is persistently depressed. Section I of this review briefly describes the history of research around LTD, and section II specifies physiological characteristics of LTD. Sections III and IV then review the massive data accumulated during the past two decades, which have revealed complex networks of signal transduction underlying LTD. Section III deals with a variety of first messengers, receptors, ion channels, transporters, G proteins, and phospholipases. Section IV covers second messengers, protein kinases, phosphatases and other elements, eventually leading to inactivation of DL-alpha-amino-3-hydroxy-5-methyl-4-isoxazolone-propionate-selective glutamate receptors that mediate granule cell-to-Purkinje cell transmission. Section V defines roles of LTD in the light of the microcomplex concept of the cerebellum as functionally eliminating those synaptic connections associated with errors during repeated exercises, while preserving other connections leading to the successful execution of movements. Section VI examines the validity of this microcomplex concept based on the data collected from recent numerous studies of various forms of motor learning in ocular reflexes, eye-blink conditioning, posture, locomotion, and hand/arm movements. Section VII emphasizes the importance of integrating studies on LTD and learning and raises future possibilities of extending cerebellar research to reveal memory mechanisms of implicit learning in general.

High voltage-activated Ca2+ currents in rat supraoptic neurones: biophysical properties and expression of the various channel alpha1 subunits

The diversity of Ca2+ currents was studied in voltage-clamped acutely dissociated neurones from the rat supraoptic nucleus (SON), and the expression of the various corresponding pore-forming alpha1 subunits determined by immunohistochemistry. We observed the presence of all high voltage-activated L-, N-, P/Q- and R-type currents. We did not observe low-voltage-activated T-type current. The multimodal current/voltage relationships of L- and R-type currents indicated further heterogeneity within these current types, each exhibiting two components that differed by a high (-20 mV) and a lower (-40 mV) threshold potential of activation. L- and R-type currents were fast activating and showed time-dependent inactivation, conversely to N- and P/Q-type currents, which activated more slowly and did not inactivate. The immunocytochemical staining indicated that the soma and proximal dendrites of SON neurones were immunoreactive for Cav1.2, Cav1.3 (forming L-type channels), Cav2.1 (P/Q-type), Cav2.2 (N-type) and Cav2.3 subunits (R-type). Each subunit exhibited further specificity in its distribution throughout the nucleus, and we particularly observed strong immunostaining of Cav1.3 and Cav2.3 subunits within the dendritic zone of the SON. These data show a high heterogeneity of Ca2+ channels in SON. neurones, both in their functional properties and cellular distribution. The lower threshold and rapidly activating L- and R-type currents should underlie major Ca2+ entry during action potentials, while the slower and higher threshold N- and P/Q-type currents should be preferentially recruited during burst activity. It will be of key interest to determine their respective role in the numerous Ca2+-dependent events that control the activity and physiology of SON neurones

Kinetic modification of the alpha(1I) subunit-mediated T-type Ca(2+) channel by a human neuronal Ca(2+) channel gamma subunit

1. Voltage-sensitive Ca(2+) channels (VSCCs) are often heteromultimeric complexes. The VSCC subtype specifically expressed by skeletal muscle has long been known to contain a gamma subunit, gamma(1), that is only expressed in this tissue. Recent work, initiated by the identification of the mutation present in the stargazer mouse, has led to the identification of a series of novel potential Ca(2+) channel gamma subunits expressed in the CNS. 2. Based on bioinformatic techniques we identified and cloned the human gamma(2), gamma(3) and gamma(4) subunits. 3. TaqMan analysis was used to quantitatively characterise the mRNA expression patterns of all the gamma subunits. All three subunits were extensively expressed in adult brain with overlapping but subunit-specific distributions. gamma(2) and gamma(3) were almost entirely restricted to the brain, but gamma(4) expression was seen in a broad range of peripheral tissues. 4. Using a myc epitope the gamma(2) subunit was tagged both intracellularly at the C-terminus and on a predicted extracellular site between the first and second transmembrane domains. The cellular distribution was then examined immunocytochemically, which indicated that a substantial proportion of the cellular pool of the gamma(2) subunit was present on the plasma membrane and provided initial evidence for the predicted transmembrane topology of the gamma subunits. 5. Using co-transfection techniques we investigated the functional effects of each of the gamma subunits on the biophysics of the T-type VSCC encoded by the alpha(1I) subunit. This revealed a substantially slowed rate of deactivation in the presence of gamma(2). In contrast, there was no significant corresponding effect of either gamma(3) or gamma(4) on alpha(1I) subunit-mediated currents.

Effects of ethosuximide, a T-type Ca(2+) channel blocker, on dorsal horn neuronal responses in rats

Plasticity in transmission and modulatory systems are implicated in mechanisms of neuropathic pain. Studies demonstrate the importance of high voltage-activated Ca(2+) channels in pain transmission, but the role of low voltage-activated, T-type Ca(2+) channels in nociception has not been investigated. The Kim and Chung rodent model of neuropathy [Pain 50 (1992) 355] was used to induce mechanical and cold allodynia in the ipsilateral hindpaw. In vivo electrophysiological techniques were used to record the response of dorsal horn neurones to innocuous and noxious electrical and natural (mechanical and thermal) stimuli after spinal nerve ligation. Spinal ethosuximide (5-1055 microg) exerted dose-related inhibitions of both the electrically and low- and high-intensity mechanical and thermal evoked neuronal responses and its profile remained unaltered after neuropathy. Measures of spinal cord hyperexcitability were most susceptible to ethosuximide. This study, for the first time, indicates a possible role for low voltage-activated Ca(2+) channels in sensory transmission.

Angiotensin II and calcium channels

Sixty years after its initial discovery, the octapeptide hormone angiotensin II (AngII) has proved to play numerous physiological roles that reach far beyond its initial description as a hypertensive factor. In spite of the host of target tissues that have been identified, only two major receptor subtypes, AT1 and AT2, are currently fully identified. The specificity of the effects of AngII relies upon numerous and complex intracellular signaling pathways that often mobilize calcium ions from intracellular stores or from the extracellular medium. Various types of calcium channels (store- or voltage-operated channels) endowed with distinct functional properties play a crucial role in these processes. The activity of these channels can be modulated by AngII in a positive and/or negative fashion, depending on the cell type under observation. This chapter reviews the main characteristics of AngII receptor subtypes and of the various calcium channels as well as the involvement of the multiple signal transduction mechanisms triggered by the hormone in the cell-specific modulation of the activity of these channels.

Neuropeptide Y receptors differentially modulate G-protein-activated inwardly rectifying K+ channels and high-voltage-activated Ca2+ channels in rat thalamic neurons

1. Using whole-cell patch-clamp recordings, infrared videomicroscopy and fast focal solution exchange methods, the actions of neuropeptide Y (NPY) were examined in thalamic slices of postnatal (10-16 days) rats. 2. NPY activated a K+-selective current in neurons of the thalamic reticular nucleus (RT; 20/29 neurons) and ventral basal complex (VB; 19/25 neurons). The currents in both nuclei had activation and deactivation kinetics that were very similar to those of GABAB receptor-induced currents, were totally blocked by 0.1 mM Ba2+ and showed voltage-dependent relaxation. These properties indicate that the NPY-sensitive K+ current is mediated by G-protein-activated, inwardly rectifying K+ (GIRK) channels. 3. In RT neurons, NPY application reversibly reduced high-voltage-activated (HVA) currents to 33 +/- 5 % (n = 40) of the control level but did not affect the T-type currents. Inhibition of Ca2+ currents was voltage independent and was largely mediated by effects on N- and P/Q-type channels. 4. NPY activation of GIRK channels was mediated via NPY1 receptors, whereas inhibition of N- and P/Q-type Ca2+ channels was mediated by NPY2 receptors. 5. These results show that neuropeptide Y activates K+ channels and simultaneously inhibits HVA Ca2+ channels via different receptor subtypes.

Molecular and functional characterization of a family of rat brain T-type calcium channels

Voltage-gated calcium channels represent a heterogenous family of calcium-selective channels that can be distinguished by their molecular, electrophysiological, and pharmacological characteristics. We report here the molecular cloning and functional expression of three members of the low voltage-activated calcium channel family from rat brain (alpha(1G), alpha(1H), and alpha(1I)). Northern blot and reverse transcriptase-polymerase chain reaction analyses show alpha(1G), alpha(1H), and alpha(1I) to be expressed throughout the newborn and juvenile rat brain. In contrast, while alpha(1G) and alpha(1H) mRNA are expressed in all regions in adult rat brain, alpha(1I) mRNA expression is restricted to the striatum. Expression of alpha(1G), alpha(1H), and alpha(1I) subunits in HEK293 cells resulted in calcium currents with typical T-type channel characteristics: low voltage activation, negative steady-state inactivation, strongly voltage-dependent activation and inactivation, and slow deactivation. In addition, the direct electrophysiological comparison of alpha(1G), alpha(1H), and alpha(1I) under identical recording conditions also identified unique characteristics including activation and inactivation kinetics and permeability to divalent cations. Simulation of alpha(1G), alpha(1H), and alpha(1I) T-type channels in a thalamic neuron model cell produced unique firing patterns (burst versus tonic) typical of different brain nuclei and suggests that the three channel types make distinct contributions to neuronal physiology.

alpha1H T-type Ca2+ channel is the predominant subtype expressed in bovine and rat zona glomerulosa

The low voltage-activated (T-type) Ca2+ channel has been implicated in the regulation of aldosterone secretion from the adrenal zona glomerulosa by extracellular K+ levels, angiotensin II, and ACTH. However, the identity of the specific subtype mediating this regulation has not been determined. We utilized in situ hybridization to examine the distribution of three newly cloned members of the T-type Ca2+ channel family, alpha1G, alpha1H, and alpha1I, in the rat and bovine adrenal gland. Substantial expression of only the mRNA transcript for the alpha1H-subunit was detected in the zona glomerulosa of both rat and bovine. A much weaker expression signal was detected for the alpha1H transcript in the zona fasciculata of bovine. Whole cell recordings of isolated bovine adrenal zona glomerulosa cells showed the native low voltage-activated current to be inhibited by NiCl2 with an IC50 of 6.4 +/- 0.2 microM. Because the alpha1H subtype exhibits similar NiCl2 sensitivity, we propose that the alpha1H subtype is the predominant T-type Ca2+ channel present in the adrenal zona glomerulosa.

Alternative splicing in intracellular loop connecting domains II and III of the alpha 1 subunit of Cav1.2 Ca2+ channels predicts two-domain polypeptides with unique C-terminal tails

Novel splice variants of the alpha(1) subunit of the Ca(v)1.2 voltage-gated Ca(2+) channel were identified that predicted two truncated forms of the alpha(1) subunit comprising domains I and II generated by alternative splicing in the intracellular loop region linking domains II and III. In rabbit heart splice variant 1 (RH-1), exon 19 was deleted, which resulted in a reading frameshift of exon 20 with a premature termination codon and a novel 19-amino acid carboxyl-terminal tail. In the RH-2 variant, exons 17 and 18 were deleted, leading to a reading frameshift of exons 19 and 20 with a premature stop codon and a novel 62-amino acid carboxyl-terminal tail. RNase protection assays with RH-1 and RH-2 cRNA probes confirmed the expression in cardiac and neuronal tissue but not skeletal muscle. The deduced amino acid sequence from full-length cDNAs encoding the two variants predicted polypeptides of 99.0 and 99.2 kDa, which constituted domains I and II of the alpha(1) subunit of the Ca(v)1.2 channel. Antipeptide antibodies directed to sequences in the second intracellular loop between domains II and III identified the 240-kDa Ca(v)1.2 subunit in sarcolemmal and heavy sarcoplasmic reticulum (HSR) membranes and a 99-kDa polypeptide in the HSR. An antipeptide antibody raised against unique sequences in the RH-2 variant also identified a 99-kDa polypeptide in the HSR. These data reveal the expression of additional Ca(2+) channel structural units generated by alternative splicing of the Ca(v)1.2 gene.

Mg(2+) block unmasks Ca(2+)/Ba(2+) selectivity of alpha1G T-type calcium channels

We have examined permeation by Ca(2+) and Ba(2+), and block by Mg(2+), using whole-cell recordings from alpha1G T-type calcium channels stably expressed in HEK 293 cells. Without Mg(o)(2+), inward currents were comparable with Ca(2+) and Ba(2+). Surprisingly, three other results indicate that alpha1G is actually selective for Ca(2+) over Ba(2+). 1) Mg(2+) block is approximately 7-fold more potent with Ba(2+) than with Ca(2+). With near-physiological (1 mM) Mg(o)(2+), inward currents were approximately 3-fold larger with 2 mM Ca(2+) than with 2 mM Ba(2+). The stronger competition between Ca(2+) and Mg(2+) implies that Ca(2+) binds more tightly than Ba(2+). 2) Outward currents (carried by Na(+)) are blocked more strongly by Ca(2+) than by Ba(2+). 3) The reversal potential is more positive with Ca(2+) than with Ba(2+), thus P(Ca) > P(Ba). We conclude that alpha1G can distinguish Ca(2+) from Ba(2+), despite the similar inward currents in the absence of Mg(o)(2+). Our results can be explained by a 2-site, 3-barrier model if Ca(2+) enters the pore 2-fold more easily than Ba(2+) but exits the pore at a 2-fold lower rate.

Characterization of Ca(2+) channels in rat subthalamic nucleus neurons

The subthalamic nucleus (STN) plays a key role in motor control. Although previous studies have suggested that Ca(2+) conductances may be involved in regulating the activity of STN neurons, Ca(2+) channels in this region have not yet been characterized. We have therefore investigated the subtypes and functional characteristics of Ca(2+) conductances in STN neurons, in both acutely isolated and slice preparations. Acutely isolated STN cells were identified by retrograde filling with the fluorescent dye, Fluoro-Gold. In acutely isolated STN neurons, Cd(2+)-sensitive, depolarization-activated Ba(2+) currents were observed in all cells studied. The current-voltage relationship and current kinetics were characteristic of high-voltage-activated Ca(2+) channels. The steady-state voltage-dependent activation curves and inactivation curves could both be fitted with a single Boltzmann function. Currents evoked with a prolonged pulse, however, inactivated with multiple time constants, suggesting either the presence of more than one Ca(2+) channel subtype or multiple inactivation processes with a single channel type in STN neurons. Experiments using organic Ca(2+) channel blockers revealed that on average, 21% of the current was nifedipine sensitive, 52% was sensitive to omega-conotoxin GVIA, 16% was blocked by a high concentration of omega-agatoxin IVA (200 nM), and the remainder of the current (9%) was resistant to the co-application of all blockers. These currents had similar voltage dependencies, but the nifedipine-sensitive current and the resistant current activated at slightly lower voltages. omega-Agatoxin IVA at 20 nM was ineffective in blocking the current. Together, the above results suggest that acutely isolated STN neurons have all subtypes of high-voltage-activated Ca(2+) channels except for P-type, but have no low-voltage-activated channels. Although acutely isolated neurons provide a good preparation for whole cell voltage-clamp study, dendritic processes are lost during dissociation. To gain information on Ca(2+) channels in dendrites, we thus studied Ca(2+) channels of STN neurons in a slice preparation, focusing on low-voltage-activated channels. In current-clamp recordings, a slow spike was always observed following termination of an injected hyperpolarizing current. The slow spike occurred at resting membrane potentials and was sensitive to micromolar concentrations of Ni(2+), suggesting that it is a low-threshold Ca(2+) spike. Together, our results suggest that STN neurons express low-voltage-activated Ca(2+) channels and several high-voltage-activated subtypes. Our results also suggest the possibility that the low-voltage-activated channels have a preferential distribution to the dendritic processes.

Unique properties of R-type calcium currents in neocortical and neostriatal neurons

Whole cell recordings from acutely dissociated neocortical pyramidal neurons and striatal medium spiny neurons exhibited a calcium-channel current resistant to known blockers of L-, N-, and P/Q-type Ca(2+) channels. These R-type currents were characterized as high-voltage-activated (HVA) by their rapid deactivation kinetics, half-activation and half-inactivation voltages, and sensitivity to depolarized holding potentials. In both cell types, the R-type current activated at potentials relatively negative to other HVA currents in the same cell type and inactivated rapidly compared with the other HVA currents. The main difference between cell types was that R-type currents in neocortical pyramidal neurons inactivated at more negative potentials than R-type currents in medium spiny neurons. Ni(2+) sensitivity was not diagnostic for R-type currents in either cell type. Single-cell RT-PCR revealed that both cell types expressed the alpha1E mRNA, consistent with this subunit being associated with the R-type current.

Localization of mRNAs for novel, atypical as well as conventional protein kinase C (PKC) isoforms in the brain of developing and mature rats

Using in situ hybridization histochemistry, the localization of mRNAs for 10 isoforms of protein kinase C (PKC) in the rat brain was studied at embryonic and postnatal stages. In the embryonic brain, the gene expression was positive only for PKCepsilon, mu, lambda, and zeta with the former three more evident: The expression for PKCmu and lambda in the ventricular germinal zone and that for PKCepsilon, zeta, and lambda in the mantle zone. In the postnatal brain, the expression for PKCdelta, eta, and theta was detected differentially in a few circumscribed loci such as the thalamus, the habenula, the septum, and the cerebellar granule cells, whereas that for the other isoforms was seen widely in various loci of the gray matter with different intensity. The expression in the cerebellar external granule cell layer was positive only for PKCbeta (betaI and betaII), mu, and lambda with that for PKCbeta confined to its inner zone. There is a general tendency for all PKC isoforms that the expression levels reach at peaks in early postnatal brain and decreases more or less in adult specimens. This is the first report on the spatio-temporal heterogeneity in the gene expression for the whole members of PKC family in the brain throughout development, especially at embryonic days.

Dendro-somatic distribution of calcium-mediated electrogenesis in purkinje cells from rat cerebellar slice cultures

The role of Ca2+ entry in determining the electrical properties of cerebellar Purkinje cell (PC) dendrites and somata was investigated in cerebellar slice cultures. Immunohistofluorescence demonstrated the presence of at least three distinct types of Ca2+ channel proteins in PCs: the alpha1A subunit (P/Q type Ca2+ channel), the alpha1G subunit (T type) and the alpha1E subunit (R type). In PC dendrites, the response started in 66 % of cases with a slow depolarization (50 +/- 15 ms) triggering one or two fast (approximately 1 ms) action potentials (APs). The slow depolarization was identified as a low-threshold non-P/Q Ca2+ AP initiated, most probably, in the dendrites. In 16 % of cases, this response propagated to the soma to elicit an initial burst of fast APs. Somatic recordings revealed three modes of discharge. In mode 1, PCs display a single or a short burst of fast APs. In contrast, PCs fire repetitively in mode 2 and 3, with a sustained discharge of APs in mode 2, and bursts of APs in mode 3. Removal of external Ca2+ or bath applications of a membrane-permeable Ca2+ chelator abolished repetitive firing. Tetraethylammonium (TEA) prolonged dendritic and somatic fast APs by a depolarizing plateau sensitive to Cd2+ and to omega-conotoxin MVII C or omega-agatoxin TK. Therefore, the role of Ca2+ channels in determining somatic PC firing has been investigated. Cd2+ or P/Q type Ca2+ channel-specific toxins reduced the duration of the discharge and occasionallyinduced the appearance of oscillations in the membrane potential associated with bursts of APs. In summary, we demonstrate that Ca2+ entry through low-voltage gated Ca2+ channels, not yet identified, underlies a dendritic AP rarelyeliciting a somatic burst of APs whereas Ca2+ entry through P/Q type Ca2+ channels allowed a repetitive firing mainly by inducing a Ca2+-dependent hyperpolarization.

Differential involvement of L-type calcium channels in epileptogenesis of rat hippocampal slices during ontogenesis

Organic calcium channel antagonists block epileptiform activity in adult tissue, suggesting an essential role of L-type channels in epileptogenesis in the mature CNS. By contrast, this remains doubtful for neonatal tissue, as the density of calcium channels changes markedly with ontogenesis. The paper addresses this question by exploring the antiepileptic efficacy of the L-type calcium channel blockers verapamil and nifedipine in low-Mg(2+)-epilepsy in rat hippocampal slices of different postnatal (PN) ages. Field (CA3, CA1) and membrane potentials (CA3) were recorded. Washout of Mg(2+) induced epileptiform potentials, which were blocked age-dependently: Verapamil suppressed activity in all preparations of PN1-5 and PN13-30+, but only in 70% of PN6-12. Nifedipine depressed activity in >75% of slices of PN13-30+, but only in 33% of PN1-12. The findings indicate a role of L-type calcium channels in epileptogenesis from PN13 onwards, with phenylalkylamine-sensitive calcium channels also being involved during PN1-5.

Molecular and functional heterogeneity of hyperpolarization-activated pacemaker channels in the mouse CNS

The hyperpolarization-activated cation current (termed I(h), I(q), or I(f)) was recently shown to be encoded by a new family of genes, named HCN for hyperpolarization-activated cyclic nucleotide-sensitive cation nonselective. When expressed in heterologous cells, each HCN isoform generates channels with distinct activation kinetics, mirroring the range of biophysical properties of native I(h) currents recorded in different classes of neurons. To determine whether the functional diversity of I(h) currents is attributable to different patterns of HCN gene expression, we determined the mRNA distribution across different regions of the mouse CNS of the three mouse HCN genes that are prominently expressed there (mHCN1, 2 and 4). We observe distinct patterns of distribution for each of the three genes. Whereas mHCN2 shows a widespread expression throughout the CNS, the expression of mHCN1 and mHCN4 is more limited, and generally complementary. mHCN1 is primarily expressed within neurons of the neocortex, hippocampus, and cerebellar cortex, but also in selected nuclei of the brainstem. mHCN4 is most highly expressed within neurons of the medial habenula, thalamus, and olfactory bulb, but also in distinct neuronal populations of the basal ganglia. Based on a comparison of mRNA expression with an electrophysiological characterization of native I(h) currents in hippocampal and thalamic neurons, our data support the idea that the functional heterogeneity of I(h) channels is attributable, in part, to differential isoform expression. Moreover, in some neurons, specific functional roles can be proposed for I(h) channels with defined subunit composition.

CaV2.2 and CaV2.3 (N- and R-type) Ca2+ channels in depolarization-evoked entry of Ca2+ into mouse sperm

As sperm prepare for fertilization, surface Ca(2+) channels must open to initiate required, Ca(2+)-mediated events. However, the molecular identity and functional properties of sperm Ca(2+) channels remain uncertain. Here, we use rapid local perfusion and single-cell photometry to examine the kinetics of calcium responses of mouse sperm to depolarizing stimuli. The linear rise of intracellular [Ca(2+)] evoked by approximately 10-s applications of an alkaline high [K(+)] medium directly reports activity of voltage-gated Ca(2+) channels. Little response occurs if external Ca(2+) is removed or if external or internal pH is elevated without depolarization. Responses are inhibited 30-40% by 30-100 micrometer Ni(2+) and more completely by 100-300 micrometer Cd(2+). They resist the dihydropyridines nitrendipine and PN200-110, but 1-10 micrometer mibefradil inhibits reversibly. They also resist the venom toxins calciseptine, omega-conotoxin MVIIC, and kurtoxin, but omega-conotoxin GVIA (5 micrometer) inhibits approximately 50%. GVIA also partially blocks transient, low voltage activated Ca(2+) currents of patch-clamped spermatids. Differential sensitivity of sperm responses to Ni(2+) and Cd(2+) and partial blockade by GVIA indicate that depolarization opens at least two types of voltage-gated Ca(2+) channels in epididymal sperm examined prior to capacitation. Involvement of a previously undetected Ca(V)2.2 (N-type) channel, suggested by the action of GVIA, is substantiated by immunodetection of Ca(2+) channel alpha(1B) subunits in sperm and sperm extracts. Resistance to dihydropyridines, calciseptine, MVIIC, and kurtoxin indicates that Ca(V)1, Ca(V)2.1, and Ca(V)3 (L-, P/Q-, and T-type) channels contribute little to this evoked response. Partial sensitivity to 1 micrometer mibefradil and an enhanced sensitivity of the GVIA-resistant component of response to Ni(2+) suggest participation of a Ca(V)2.3 (R-type) channel specified by previously found alpha(1E) subunits. Our examination of depolarization-evoked Ca(2+) entry indicates that mature sperm possess a larger palette of voltage-gated Ca(2+) channels than previously thought. Such diversity may permit specific responses to multiple cues encountered on the path to fertilization.

Biophysical and pharmacological characterization of voltage-sensitive calcium currents in neonatal rat inferior colliculus neurons

Calcium conductances have been found in neonatal inferior colliculus neurons, however the biophysical and pharmacological profiles of the underlying calcium currents have not yet been characterized. In this study, we examined which types of voltage-activated calcium currents comprise the whole-cell inward current of neonatal inferior colliculus neurons (10-22microm in diameter). On the basis of their voltage-dependence and pharmacological sensitivities, three major components of barium currents were identified. A low threshold voltage-activated current that activated around -70mV, a mid threshold voltage-activated current that activated near -50mV, and a high threshold voltage-activated current that activated around -40mV. Low and mid threshold voltage-activated currents were present in 33% and 41% of the recordings, respectively, whereas high threshold voltage-activated currents were recorded in all inferior colliculus neurons tested. Nickel chloride (50microM) and U-92032 (1microM), which both block low threshold voltage-activated currents, reduced the amplitude of low threshold voltage-activated peak currents at a test potential of -60mV by 72% and 10%, respectively. In addition, 50microM nickel chloride and 1microM U-92032 reduced the amplitude of mid threshold voltage-activated peak currents measured at -20mV by 55% and 21%, respectively. Further pharmacological analysis indicated the presence of multiple types of high threshold voltage-activated currents in neonatal inferior colliculus neurons. The dihydropyridine nimodipine (1microM), a selective L-type current antagonist, reduced the amplitude of high threshold voltage-activated peak currents by 25%. In addition, FPL 64176 (1microM), a non-dihydropyridine L-type current agonist caused a dramatic 534% increase in the amplitude of the slow sustained component of the tail current measured at -40mV. These data indicate that inferior colliculus neurons express L-type channels. omega-Conotoxin GVIA (1microM), a selective blocker of N-type current, inhibited high threshold voltage-activated peak currents by 28% indicating the presence of N-type channels. omega-Agatoxin IVA (300nM), a potent P/Q-type antagonist, reduced high threshold voltage-activated peak currents by 27%, suggesting that inferior colliculus neurons express P/Q-type channels. Concomitant application of nimodipine (1microM), omega-conotoxin GVIA (1microM) and omega-agatoxin IVA (300nM) onto inferior colliculus neurons decreased the control high threshold voltage-activated peak currents only by 62%.Thus, inferior colliculus neurons may express at least one more type of calcium current in addition to low and mid threshold voltage-activated currents and L-type, N-type and P/Q-type high threshold currents.

Specific properties of T-type calcium channels generated by the human alpha 1I subunit

We have cloned and expressed a human alpha(1I) subunit that encodes a subtype of T-type calcium channels. The predicted protein is 95% homologous to its rat counterpart but has a distinct COOH-terminal region. Its mRNA is detected almost exclusively in the human brain, as well as in adrenal and thyroid glands. Calcium currents generated by the functional expression of human alpha(1I) and alpha(1G) subunits in HEK-293 cells were compared. The alpha(1I) current activated and inactivated approximately 10 mV more positively. Activation and inactivation kinetics were up to six times slower, while deactivation kinetics was faster and showed little voltage dependence. A slower recovery from inactivation, a lower sensitivity to Ni(2+) ions (IC(50) approximately 180 micrometer), and a larger channel conductance (approximately 11 picosiemens) were the other discriminative features of the alpha(1I) current. These data demonstrate that the alpha(1I) subunit encodes T-type Ca(2+) channels functionally distinct from those generated by the human alpha(1G) or alpha(1H) subunits and point out that human and rat alpha(1I) subunits have species-specific properties not only in their primary sequence, but also in their expression profile and electrophysiological behavior.

Characterization of calcium currents in functionally mature mouse spinal motoneurons

Motoneurons integrate synaptic input and produce output in the form of trains of action potentials such that appropriate muscle contraction occurs. Motoneuronal calcium currents play an important role in the production of this repetitive firing. Because these currents change in the postnatal period, it is necessary to study them in animals in which the motor system is 'functionally mature', that is, animals that are able to weight-bear and walk. In this study, calcium currents were recorded using whole-cell patch-clamp techniques from large (> 20 microm) ventral horn cells in lumbar spinal cord slices prepared from mature mice. Ninety percent (nine out of 10) of the recorded cells processed for choline acetyltransferase were found to be cholinergic, confirming their identity as motoneurons. A small number of motoneurons were found to have currents with low-voltage-activated (T-type) characteristics. Pharmacological dissection of the high-voltage-activated current demonstrated omega-agatoxin-TK- (P/Q-type), omega-conotoxin GVIA- (N-type), and dihydropyridine- and FPL-64176-sensitive (L-type) components. A cadmium-sensitive component of the current that was insensitive to these chemicals (R-type) was also seen in these cells. These results indicate that the calcium current in lumbar spinal motoneurons from functionally mature mice is mediated by a number of different channel subtypes. The characterization of these calcium channels in mature mammalian motoneurons will allow for the future study of their modulation and their roles during behaviours such as locomotion.

Inhibition of recombinant low-voltage-activated Ca(2+) channels by the neuroprotective agent BW619C89 (Sipatrigine)

T-type Ca(2+) currents were recorded in 2 mM Ca(2+) from HEK 293 cells stably expressing recombinant low-voltage-activated Ca(2+) channel subunits. Current-voltage relationships revealed that these currents were low-voltage activated in nature and could be reversibly antagonised by mibefradil, a known T-type channel blocker. At a test potential of -25 mV alpha(1I)-mediated Ca(2+) currents were rapidly and reversibly inhibited by 1-100 microM BW619C89 (IC(50)=14 microM, Hill coefficient 1.3). In contrast to its actions on N-type Ca(2+) channels, a near IC(50) dose (10 microM) of BW619C89 produced no alterations in either the kinetics or voltage-dependence of T-type currents. In additional single dose experiments, currents mediated by rat alpha(1G), human alpha(1H) or human alpha(1I) channel subunits were also inhibited by BW619C89. Overall our data indicate that T-type Ca(2+) channels are more potently blocked by BW619C89 than either type-II Na(+) channels or N-type Ca(2+) channels. It seems, therefore, that inhibition of low-voltage-activated Ca(2+) channels is likely to contribute to the anticonvulsant and neuroprotective actions of this and related compounds.

Regulation of the calcium channel alpha(1G) subunit by divalent cations and organic blockers

The pharmacological properties of the expressed murine T-type alpha(1G) channel were characterized using the whole cell patch clamp configuration. Ba(2+) or Ca(2+) were used as charge carriers. Both I(Ba) and I(Ca) were blocked by Ni(2+) and Cd(2+) with IC(50) values of 0.47+/-0.04 and 1.13+/-0.06 mM (Ni(2+)) and 162+/-13 and 658+/-23 microM (Cd(2+)), respectively. Ni(2+), but not Cd(2+), modified the gating of channel activation. Ni(2+) consistently accelerated channel deactivation while Cd(2+) had a similar effect only on I(Ca). The alpha(1G) channel was potently blocked by mibefradil in a dose- and voltage-dependent manner. I(Ba) was moderately blocked by phenytoin (IC(50) 73.9+/-1.9 microM) and was resistant to the block by valproate. Also 3 mM ethosuximide blocked 20 and 35% of the I(Ba) at a HP of -100 and -60 mV, respectively, while 5 mM amiloride inhibited I(Ba) by 38% and significantly slowed current activation. The alpha(1G) channel was not affected by 10 microM tetrodotoxin. Both 1 microM (+)isradipine and 10 microM nifedipine inhibited 18 and 14% of I(Ba) amplitude at a HP of -100 mV, and 23% and 29% of I(Ba) amplitude at a HP of -60 mV, respectively. The alpha(1G) current was minimally activated by 1 microM Bay K 8644.

Neuronal distribution and functional characterization of the calcium channel alpha2delta-2 subunit

The auxiliary calcium channel alpha2delta subunit comprises a family of three genes, alpha2delta-1 to 3, which are expressed in a tissue-specific manner. alpha2delta-2 mRNA is found in the heart, skeletal muscle, brain, kidney, liver and pancreas. We report here for the first time the identification and functional characterization of alpha2delta-2 splice variants and their mRNA distribution in the mouse brain. The splice variants differ in the alpha2 and delta protein by eight and three amino acid residues, respectively, and are differentially expressed in cardiac tissue and human medullary thyroid carcinoma (hMTC) cells. In situ hybridization of mouse brain sections revealed the highest expression of alpha2delta-2 mRNA in the Purkinje cell layer of the cerebellum, habenulae and septal nuclei, and a lower expression in the cerebral cortex, olfactory bulb, thalamic and hypothalamic nuclei, as well as the inferior and superior colliculus. As the in situ data did not suggest a specific colocalization with any alpha1 subunit, coexpression studies of alpha2delta-2 were carried out either with the high-voltage-gated calcium channels, alpha1C, alpha1E or alpha1A, or with the low-voltage-gated calcium channel, alpha1G. Coexpression of alpha2delta-2 increased the current density, shifted the voltage dependence of channel activation and inactivation of alpha1C, alpha1E and alpha1A subunits in a hyperpolarizing direction, and accelerated the decay and shifted the steady-state inactivation of the alpha1G current.

Slowly inactivating sodium current (I(NaP)) underlies single-spike activity in rat subthalamic neurons

One-half of the subthalamic nucleus (STN) neurons switch from single-spike activity to burst-firing mode according to membrane potential. In an earlier study, the ionic mechanisms of the bursting mode were studied but the ionic currents underlying single-spike activity were not determined. The single-spike mode of activity of STN neurons recorded from acute slices in the current clamp mode is TTX-sensitive but is not abolished by antagonists of ionotropic glutamatergic and GABAergic receptors, blockers of calcium currents (2 mM cobalt or 40 microM nickel), or intracellular Ca(2+) ions chelators. Tonic activity is characterized by a pacemaker depolarization that spontaneously brings the membrane from the peak of the afterspike hyperpolarization (AHP) to firing threshold (from -57.1 +/- 0.5 mV to -42.2 +/- 0.3 mV). Voltage-clamp recordings suggest that the Ni(2+)-sensitive, T-type Ca(2+) current does not play a significant role in single-spike activity because it is totally inactivated at potentials more depolarized than -60 mV. In contrast, the TTX-sensitive, I(NaP) that activated at -54.4 +/- 0.6 mV fulfills the conditions for underlying pacemaker depolarization because it is activated below spike threshold and is not fully inactivated in the pacemaker range. In some cases, the depolarization required to reach the threshold for I(NaP) activation is mediated by hyperpolarization-activated cation current (I(h)). This was directly confirmed by the cesium-induced shift from single-spike to burst-firing mode which was observed in some STN neurons. Therefore, a fraction of I(h) which is tonically activated at rest, exerts a depolarizing influence and enables membrane potential to reach the threshold for I(NaP) activation, thus favoring the single-spike mode. The combined action of I(NaP) and I(h) is responsible for the dual mode of discharge of STN neurons.

Identification of a T-type Ca(2+) channel isoform in murine atrial myocytes (AT-1 cells)

Calcium channels are important targets for therapeutics, but their molecular diversity complicates characterization of these channels in native heart cells. In this study, we identify a new splice variant of a low-voltage activated, or T-type Ca(2+), channel in murine atrial myocytes. To date, alpha1G and alpha1H are the only 2 T-type Ca(2+) channel isoforms found in cardiovascular tissue. We compared alpha1G and alpha1H channel current heterologously expressed in HEK 293 cells with T-type current from the murine atrial tumor cell, AT-1. AT-1 cell T-type current (I(T)) has the same voltage dependence of activation and inactivation as alpha1G and alpha1H. The cloned T-type channels and AT-1 T-type current share similar kinetics of macroscopic inactivation and deactivation. The kinetics of recovery from inactivation of T-type currents serves as an electrophysiological signature for T-channel isoform. alpha1G and AT-1 I(T) have a similar recovery from inactivation time course that is faster than that for alpha1H. In all cases, T-type current recovers with a biexponential time course, and the relative amplitude of fast and slow time courses explains the slower alpha1H recovery kinetics, rather than differences in the time constants of the individual transitions. Thus, the T-type channels may be an important contributor to automaticity in heart cells, and molecular diversity is reflected in the pathway of recovery from inactivation.

Microarray analysis of the transcriptional network controlled by the photoreceptor homeobox gene Crx

BACKGROUND

Terminal differentiation of many cell types is controlled and maintained by tissue- or cell-specific transcription factors. Little is known, however, of the transcriptional networks controlled by such factors and how they regulate differentiation. The paired-type homeobox transcription factor, Crx, has a pivotal role in the terminal differentiation of vertebrate photoreceptors. Mutations in the human CRX gene result in either congenital blindness or photoreceptor degeneration and targeted mutation of the mouse Crx results in failure of development of the light-detecting outer segment of photoreceptors.

RESULTS

We have characterized the transcriptional network controlled by Crx by microarray analysis of gene expression in developing retinal tissue from Crx(+/+) and Crx(-/-) mice. These data were combined with analyses of gene expression in developing and adult retina, as well as adult brain. The most abundant elements of this network are ten photoreceptor-specific or -enriched genes, including six phototransduction genes. All of the available 5' regulatory regions of the putative Crx targets contain a novel motif that is composed of a head-to-tail arrangement of two Crx-binding-element-like sequences. Analysis of the 5' regions of a set of mouse and human genes suggests that this motif is specific to Crx targets.

CONCLUSIONS

This study demonstrates that cDNA microarrays can be successfully used to define the transcriptional networks controlled by transcription factors in vertebrate tissue in vivo.

Distribution of mapacalcine receptors in the central nervous system of rat using the [125I]-labeled mapacalcine derivative

Mapacalcine is a dimeric protein of Mr 19041 extracted from the marine sponge Cliona vastifica. Electrophysiological and pharmacological approaches have demonstrated that mapacalcine was blocking a calcium channel different from N-, L-, P-, T- or Q-type calcium channels on mouse intestinal smooth muscle. Recently a [125I]-labeled derivative of mapacalcine has been synthesized and characterized as a tool usable as a probe to investigate mapacalcine receptors. On rat brain membranes, it binds to its receptor with a K(d)=0.35 nM and a maximal binding capacity of 706 fmol/mg protein. We use here [125I]-mapacalcine to study the mapping of its receptors in the rat brain. Data obtained show a practically homogeneous labeling of the brain. Our experiments suggest that mapacalcine receptors are present on neuronal and glial cells. Interestingly, choroid plexus demonstrates a high density of mapacalcine receptors. These data would suggest that mapacalcine sensitive calcium channels could be involved in the control of calcium homeostasis of the cerebrospinal fluid.

Molecular and functional properties of the human alpha(1G) subunit that forms T-type calcium channels

We describe here several novel properties of the human alpha(1G) subunit that forms T-type calcium channels. The partial intron/exon structure of the corresponding gene CACNA1G was defined and several alpha(1G) isoforms were identified, especially two isoforms that exhibit a distinct III-IV loop: alpha(1G-a) and alpha(1G-b). Northern blot and dot blot analyses indicated that alpha(1G) mRNA is predominantly expressed in the brain, especially in thalamus, cerebellum, and substantia nigra. Additional experiments have also provided evidence that alpha(1G) mRNA is expressed at a higher level during fetal life in nonneuronal tissues (i.e. kidney, heart, and lung). Functional expression in HEK 293 cells of a full-length cDNA encoding the shortest alpha(1G) isoform identified to date, alpha(1G-b), resulted in transient, low threshold activated Ca(2+) currents with the expected permeability ratio (I(Sr) > I(Ca) >/= I(Ba)) and channel conductance ( approximately 7 pS). These properties, together with slowly deactivating tail currents, are typical of those of native T-type Ca(2+) channels. This alpha(1G)-related current was inhibited by mibefradil (IC(50) = 2 microM) and weakly blocked by Ni(2+) ions (IC(50) = 148 microM) and amiloride (IC(50) > 1 mM). We showed that steady state activation and inactivation properties of this current can generate a "window current" in the range of -65 to -55 mV. Using neuronal action potential waveforms, we show that alpha(1G) channels produce a massive and sustained Ca(2+) influx due to their slow deactivation properties. These latter properties would account for the specificity of Ca(2+) influx via T-type channels that occurs in the range of physiological resting membrane potentials, differing considerably from the behavior of other Ca(2+) channels.

TASK-1, a two-pore domain K+ channel, is modulated by multiple neurotransmitters in motoneurons

Inhibition of "leak" potassium (K+) channels is a widespread CNS mechanism by which transmitters induce slow excitation. We show that TASK-1, a two pore domain K+ channel, provides a prominent leak K+ current and target for neurotransmitter modulation in hypoglossal motoneurons (HMs). TASK-1 mRNA is present at high levels in motoneurons, including HMs, which express a K+ current with pH- and voltage-dependent properties virtually identical to those of the cloned channel. This pH-sensitive K+ channel was fully inhibited by serotonin, norepinephrine, substance P, thyrotropin-releasing hormone, and 3,5-dihydroxyphenylglycine, a group I metabotropic glutamate receptor agonist. The neurotransmitter effect was entirely reconstituted in HEK 293 cells coexpressing TASK-1 and the TRH-R1 receptor. Given its expression patterns and the widespread prevalence of this neuromodulatory mechanism, TASK-1 also likely supports this action in other CNS neurons.

Low-voltage-activated calcium channel subunit expression in a genetic model of absence epilepsy in the rat

The Genetic Absence Epilepsy Rats from Strasbourg (GAERS) are an inbred strain of rats that display many of the characteristics of human absence epilepsy. In these rats, reciprocal thalamocortical projections play a critical role in the generation of spike-and-wave discharges that characterize absence seizures. When compared to those of the non-epileptic control strain, juvenile animals of the GAERS strain reportedly possess higher-amplitude T-type calcium currents in neurons of the thalamic reticular nucleus (nRt). We hypothesized that differences in calcium currents seen between GAERS and controls result from differences in expression of genes for low-voltage-activated calcium channels. Quantitative in situ hybridization was used to compare expression of alpha1G, alpha1H, alpha1I, and alpha1E calcium channel subunit mRNAs from adult and juvenile animals of the two strains. We found higher levels of alpha1H mRNA expression in nRt neurons of juvenile animals (34.9+/-2. 3 vs. 28.4+/-1.8 grains/10(3) pixels, p<0.05), perhaps accounting in part for earlier reports of elevated T-type current amplitude in those cells. In adult GAERS animals, we found elevated levels of alpha1G mRNA in neurons of the ventral posterior thalamic relay nuclei (64.8+/-3.5 vs. 53.5+/-1.7 grains/10(3) pixels, p<0.05), as well as higher levels of alpha1H mRNA in nRt neurons (32.6+/-0.8 vs. 28.2+/-1.6 grains/10(3) pixels, p<0.05). These results suggest that the epileptic phenotype apparent in adult GAERS may result in part from these significant, albeit small ( approximately 15-25%), elevations in T-type calcium channel mRNA levels.

Continued morphine modulation of calcium channel currents in acutely isolated locus coeruleus neurons from morphine-dependent rats

1. The actions of the opioid agonists morphine and methionine-enkephalin (met-enkephalin) on the calcium channel currents (IBa) of acutely isolated locus coeruleus (LC) neurons from morphine-dependent and vehicle-treated rats were examined using whole cell patch clamp techniques. 2. In LC neurons maintained in 5 microM morphine, co-superfusion of naloxone (1 microM) or the mu-opioid receptor antagonist CTAP (D-Phe-Cys-Tyr-D-Trp-Arg-Thr-Pen-Thr-NH2 1 microM) with morphine resulted in a significant increase in the amplitude of IBa. The increases in IBa were not different in neurons from morphine-dependent or vehicle rats. The increase in IBa was mimicked by washing off morphine, but not by co-superfusion of the kappa-receptor antagonist norbinaltorphimine (300 nM) or the delta-receptor antagonist ICI-174864 (1 microM). 3. In spontaneously withdrawn LC neurons from morphine-dependent rats, met-enkephalin (pD2 7.1, maximum inhibition 49%) and morphine (pD2 6.5, maximum inhibition 33%), inhibited IBa in all cells. In cells from vehicle rats the pD2 for met-enkephalin was 7.3, maximum inhibition 52%, while the pD2 for morphine was 6.6 and the maximum inhibition 43% (P<0.05 versus cells from morphine-dependent rats). 4. IBa in LC neurons was mostly comprised of omega-conotoxin GVIA- (N-type) and omega-agatoxin IVA- (P/Q-type) sensitive components, with lesser amounts of nimodipine-sensitive current and current resistant to all three blockers. Neither the density of IBa nor the proportion of any of the components of IBa differed between neurons from morphine-dependent or vehicle-treated rats. 5. This study demonstrates that in morphine-dependent rats, morphine and met-enkephalin modulation of somatic IBa in LC neurons displays modest tolerance compared with untreated rats. Further, chronic morphine treatment does not alter the type or density of IBa in LC neurons. These results provide more evidence that functional mu-opioid receptor coupling is not dramatically altered in the LC in morphine-dependent rats.

Nickel block of three cloned T-type calcium channels: low concentrations selectively block alpha1H

Nickel has been proposed to be a selective blocker of low-voltage-activated, T-type calcium channels. However, studies on cloned high-voltage-activated Ca(2+) channels indicated that some subtypes, such as alpha1E, are also blocked by low micromolar concentrations of NiCl(2). There are considerable differences in the sensitivity to Ni(2+) among native T-type currents, leading to the hypothesis that there may be more than one T-type channel. We confirmed part of this hypothesis by cloning three novel Ca(2+) channels, alpha1G, H, and I, whose currents are nearly identical to the biophysical properties of native T-type channels. In this study we examined the nickel block of these cloned T-type channels expressed in both Xenopus oocytes and HEK-293 cells (10 mM Ba(2+)). Only alpha1H currents were sensitive to low micromolar concentrations (IC(50) = 13 microM). Much higher concentrations were required to half-block alpha1I (216 microM) and alpha1G currents (250 microM). Nickel block varied with the test potential, with less block at potentials above -30 mV. Outward currents through the T channels were blocked even less. We show that depolarizations can unblock the channel and that this can occur in the absence of permeating ions. We conclude that Ni(2+) is only a selective blocker of alpha1H currents and that the concentrations required to block alpha1G and alpha1I will also affect high-voltage-activated calcium currents.

Comparison of the Ca2 + currents induced by expression of three cloned alpha1 subunits, alpha1G, alpha1H and alpha1I, of low-voltage-activated T-type Ca2 + channels

Expression of rat alpha1G, human alpha1H and rat alpha1I subunits of voltage-activated Ca2 + channels in HEK-293 cells yields robust Ca2 + inward currents with 1.25 mM Ca2 + as the charge carrier. Both similarities and marked differences are found between their biophysical properties. Currents induced by expression of alpha1G show the fastest activation and inactivation kinetics. The alpha1H and alpha1I currents activate and inactivate up to 1.5- and 5-fold slower, respectively. No differences in the voltage dependence of steady state inactivation are detected. Currents induced by expression of alpha1G and alpha1H deactivate with time constants of up to 6 ms at a test potential of - 80 mV, but currents induced by alpha1I deactivate about three-fold faster. Recovery from short-term inactivation is more than three-fold slower for currents induced by alpha1H and alpha1I in comparison to alpha1G. In contrast to these characteristics, reactivation after long-term inactivation was fastest for currents arising from expression of alpha1I and slowest in cells expressing alpha1H calcium channels. The calcium inward current induced by expression of alpha1I is increased by positive prepulses while currents induced by alpha1H and alpha1G show little ( < 5%) or no facilitation. The data thus provide a characteristic fingerprint of each channel's activity, which may allow correlation of the alpha1G, alpha1H and alpha1I induced currents with their in vivo counterparts.

Distinct kinetics of cloned T-type Ca2 + channels lead to differential Ca2 + entry and frequency-dependence during mock action potentials

Voltage-dependent activity around the resting potential is determinant in neuronal physiology and participates in the definition of the firing pattern. Low-voltage-activated T-type Ca2 + channels directly affect the membrane potential and control a number of secondary Ca2 + -dependent permeabilities. We have studied the ability of the cloned T-type channels (alpha1G,H,I) to carry Ca2 + currents in response to mock action potentials. The relationship between the spike duration and the current amplitude is specific for each of the T-type channels, reflecting their individual kinetic properties. Typically the charge transfer increases with spike broadening, but the total Ca2 + entry saturates at different spike durations according to the channel type: 4 ms for alpha1G; 7 ms for alpha1H; and > 10 ms for alpha1I channels. During bursts, currents are inhibited and/or transiently potentiated according to the alpha1 channel type, with larger effects at higher frequency. The inhibition may be induced by voltage-independent transitions toward inactivated states and/or channel inactivation through intermediate closed states. The potentiation is explained by an acceleration in the channel activation kinetics. Relatively fast inactivation and slow recovery limit the ability of alpha1G and alpha1H channels to respond to high frequency stimulation ( > 20 Hz). In contrast, the slow inactivation of alpha1I subunits allows these channels to continue participating in high frequency bursts (100 Hz). The biophysical properties of alpha1G, H and I channels will therefore dramatically modulate the effect of neuronal activities on Ca2 + signalling.