NGF-induced neurite outgrowth in PC12 cells is independent of calcium entry through L-type calcium channels.

Neuronal growth factor (NGF) induces neurodifferentiation of PC12 cells into cholinergic neurons-like cells. It was shown that intracellular Ca2+ ions participate in regulation of the differentiation of PC12 cells. We tested whether L-type calcium channels contribute to Ca2+ entry which supports neurite outgrowth accompanying NGF-activated differentiation process. Development of morphological changes did correlate with increase of functional expression of L-type calcium channels. However, inhibition of L-type calcium channels by 1 µM of isradipine did not affect significantly an NGF-activated neurite outgrowth.

T-type calcium channel blockers - new and notable.

Since cloning of the T-type or Ca(V)3.n calcium channel family in 1998-1999 much progress was made in investigation of their regulation. Most effective metal Ca(V)3 channel blockers are trivalent cations from lanthanide group together with transition metals La(3+) and Y(3+). Divalent cations Zn(2+), Cu(2+) and Ni(2+) inhibit Ca(V)3.2 channels more efficiently than Ca(V)3.1 and Ca(V)3.3 channels via second high-affinity binding site including histidine H191 specific for the Ca(V)3.2 channel. Dihydropyridines and phenylalkylamines in addition to block of L-type calcium channel can inhibit Ca(V)3 channels in clinically relevant concentration.

Measurement of cellular excitability by whole cell patch clamp technique.

Patch clamp method developed more than 30 years ago is widely used for investigation of cellular excitability manifested as transmembrane ionic current and/or generation of action potentials. This technique could be applied to measurement of ionic currents flowing through individual (single) ion channels or through the whole assembly of ion channels expressed in the whole cell. Whole cell configuration is more common for measurement of ion currents and the only one enabling measurement of action potentials. This method allows detailed analysis of mechanisms and structural determinants of voltage-dependent gating of ion channels as well as regulation of channel activity by intracellular signaling pathways and pharmacological agents.

Haloperidol moderately inhibits cardiovascular L-type calcium current.

Effects of haloperidol on L-type CaV1.2 channel were studied. Calcium current was measured in whole cell patch-clamp using calcium as a charge carrier. Inhibition by haloperidol was investigated in CaV1.2 channel natively expressed in rat cardiac myocytes and recombinant cardiac (CaV1.2a) and vascular (CaV1.2b) splice variants of the channel expressed in HEK 293 cells. Haloperidol inhibited L-type calcium current in a concentration-dependent manner with a threshold of 1 nmol/l. 1 micromol/l haloperidol inhibited 20.6 +/- 3.6% of calcium current amplitude in cardiomyocytes, 25.4 +/- 2.6% of current amplitude through the CaV1.2b channel and 28.0 +/- 2.7% of current through the CaV1.2a channel. Inhibition was not accompanied by alteration of current waveform or by shift of current-voltage relation. In a current clamp haloperidol suppressed action potential generation. 1 micromol/l of the drug shortened the action potential duration in part of the cells and suppressed fully action potential in other cells. Moderate inhibition of the L-type calcium channels by haloperidol might cause shortening of action potential. Complete abolishment of action potential must have been mediated by inhibition of another, likely sodium channel.

Monovalent currents through the T-type Cav3.1 channels and their block by Mg2+.

We have investigated the permeability of the Cav3.1 channel for Ca2+ and different monovalent cations and the block of the currents by Mg2+ ions. In the absence of extracellular divalent cations, the Cav3.1 channel was more permeable for Na+ than for Cs+ and impermeable for NMDG+. Monovalent currents were inhibited by Mg2+ of near physiological concentration by three orders of magnitude more effectively than the Ca2+ current. Inhibition of outward, but not inward current by Mg2+ was voltage-dependent. Furthermore, magnesium slowed down channel deactivation presumably by interacting with an open channel state.

The effect of the outermost basic residues in the S4 segments of the Ca(V)3.1 T-type calcium channel on channel gating.

The contribution of voltage-sensing S4 segments in domains I to IV of the T-type Ca(V)3.1 calcium channel to channel gating was investigated by the replacement of the uppermost charged arginine residues by neutral cysteines. In each construct, either a single (R180C, R834C, R1379C or R1717C) or a double (two adjacent domains) mutation was introduced. We found that the neutralisation of the uppermost arginines in the IS4, IIS4 and IIIS4 segments shifted the voltage dependence of channel activation in a hyperpolarising direction, with the most prominent effect in the IS4 mutant. In contrast, the voltage dependence of channel inactivation was shifted towards more negative membrane potentials in all four single mutant channels, and these effects were more pronounced than the effects on channel activation. Recovery from inactivation was affected by the IS4 and IIIS4 mutations. In double mutants, the effects on channel inactivation and recovery from inactivation, but not on channel activation, were additive. Exposure of mutant channels to the reducing agent dithiothreitol did not alter channel properties. In summary, our data indicate that the S4 segments in all four domains of the Ca(V)3.1 calcium channels contribute to voltage sensing during channel inactivation, while only the S4 segments in domains I, II and III play such role in channel activation. Furthermore, the removal of the outermost basic amino acids from the IVS4 and IIIS4 and, to a lesser extent, from IS4 segments stabilised the open state of the channel, whereas neutralization from that of IIS4 destabilised it.

Modulation of expression of the sigma receptors in the heart of rat and mouse in normal and pathological conditions.

The aim of the present work was to study the effect of various stressors (hypoxia, cold, immobilization) on the gene expression of sigma receptors in the left ventricles of rat heart. We have clearly shown that gene expression of sigma receptors is upregulated by strong stress stimuli, such as immobilization and/or hypoxia. Nevertheless, cold as a milder stressor has no effect on sigma receptor's mRNA levels. Signalling cascade of sigma receptors is dependent on IP(3) receptors, since silencing of both, type 1 and 2 IP(3) receptors resulted in decreased mRNA levels of sigma receptors. Physiological relevance of sigma receptors in the heart is not clear yet. Nevertheless, based on the already published data we can assume that sigma receptors might participate in contractile responses in cardiomyocytes.

Modulation of expression of Na+/Ca2+ exchanger in heart of rat and mouse under stress.

AIM: The Na(+)/Ca(2+) exchanger (NCX) is a major Ca(2+) extrusion system in the plasma membrane of cardiomyocytes and an important component participating on the excitation-contraction coupling process in muscle cells. NCX1 isoform is the most abundant in the heart and is known to be changed after development of ischaemia or myocardial infarction. Objective of this study was to investigate the effect of stress factors (immobilization, cold and short-term hypoxia) on the expression of NCX1, in vivo, in the heart of rat and mouse. METHODS: We compared gene expression and protein levels of control and stressed animals. The activity of NCX was measured by the whole cell configuration using the patch clamp. We also measured physiological parameters of the heart in physiological conditions and under ischaemia-reperfusion to compare response of control and stressed hearts. RESULTS: We have found that only strong stress stimulus (hypoxia, immobilization) applied repeatedly for several days elevated the NCX1 mRNA level. Cold, which is a weaker stressor that activates mainly sympathoneural, and only marginally adrenomedullary system did not affect the gene expression of NCX1. Thus, from these results it appears that hormones produced by the adrenal medulla (mainly adrenaline) might be involved in this process. To study possible mechanism of the NCX1 regulation by stress, we focused on the possible role of the hypothalamo-pituitary-adrenocortical pathway in the activation of catecholamine synthesis in the adrenal medulla. We have already published that cortisol affects activity, but not the gene expression of NCX1. In this work, we used corticotropin-releasing hormone (CRH) knockout mice, where secretion of corticosterone and subsequently adrenaline is significantly suppressed. As no increase in NCX1 mRNA was observed in CRH knockout mice due to immobilization stress, we proposed that adrenaline (probably regulated via corticosterone) is involved in the regulation of NCX1 gene expression during stress. CONCLUSIONS: The gene expression and protein levels of the NCX1 are increased by the strong stress stimuli, e.g. hypoxia, or immobilization stress. The activity of NCX1 is decreased. Based on these results, we assume that the gene expression of NCX is increased as a consequence of suppressed activity of this transport system.

Modulation by 6-hydroxydopamine of expression of the phenylethanolamine N-methyltransferase (PNMT) gene in the rat heart during immobilization stress.

Phenylethanolamine N-methyltransferase (PNMT) is the final enzyme in the catecholamine synthesizing cascade that converts noradrenaline (NA) to adrenaline (Adr). Both of these catecholamines are physiologically important hormones and neurotransmitters in mammals with profound influence on the activity of the cardiovascular system. Although PNMT activity and gene expression have been reported in the neonatal and also adult rat heart, little is known about the identity of the cells expressing PNMT mRNA. In this study, we have shown that besides PNMT in neuronal and intrinsic cardiac cells, this enzyme is expressed also in rat cardiomyocytes, as shown by immunofluorescence in isolated cardiomyocytes. To determine which cells in the heart more sensitively show stress-induced changes in PNMT mRNA expression, we performed chemical sympathectomy by administration of 6-hydroxydopamine (6-OHDA), which destroys catecholaminergic terminals. We determined PNMT mRNA levels in the left atria and ventricles of control and stressed rats. In the rats treated with 6-OHDA, PNMT mRNA levels were not changed under normal, physiological conditions compared to vehicle treated rats. Similar results were observed on isolated cardiomyocytes from control and 6-OHDA treated rats. However, 6-OHDA treatment prevented immobilization-induced increase in PNMT mRNA expression. The results allow us to propose that in the heart, the immobilization-induced increase in PNMT gene expression is probably not in cardiomyocytes, but in neuronal cells.

Gating of the expressed T-type Cav3.1 calcium channels is modulated by Ca2+.

AIM: We have investigated the influence of Ca2+ ions on the basic biophysical properties of T-type calcium channels. METHODS: The Cav3.1 calcium channel was transiently expressed in HEK 293 cells. Current was measured using the whole cell patch clamp technique. Ca2+ or Na+ ions were used as charge carriers. The intracellular Ca2+ was either decreased by the addition of 10 mm ethyleneglycoltetraacetic acid (EGTA) or increased by the addition of 200 microm Ca2+ into the non-buffered intracellular solution. Various combinations of extra- and intracellular solutions yielded high, intermediate or low intracellular Ca2+ levels. RESULTS: The amplitude of the calcium current was independent of intracellular Ca2+ concentrations. High levels of intracellular Ca2+ accelerated significantly both the inactivation and the activation time constants of the current. The replacement of extracellular Ca2+ by Na+ as charge carrier did not affect the absolute value of the activation and inactivation time constants, but significantly enhanced the slope factor of the voltage dependence of the inactivation time constant. Slope factors of voltage dependencies of channel activation and inactivation were significantly enhanced. The recovery from inactivation was faster when Ca2+ was a charge carrier. The number of available channels saturated for membrane voltages more negative than -100 mV for the Ca2+ current, but did not reach steady state even at -150 mV for the Na+ current. CONCLUSIONS: Ca2+ ions facilitate transitions of Cav3.1 channel from open into closed and inactivated states as well as backwards transition from inactivated into closed state, possibly by interacting with its voltage sensor.

Effect of protein tyrosine kinase inhibitors on the current through the Ca(V)3.1 channel.

In the present study, we have investigated the effects of protein tyrosine kinase (PTK) inhibitors on the Ca(V)3.1 calcium channel stably transfected in HEK293 cells using the whole-cell configuration of the patch-clamp technique. We have tested two different tyrosine kinase inhibitors, genistein and tyrphostin AG213, and their inactive analogs, genistin and tyrphostin AG9. Bath application of genistein, but not genistin, decreased the T-type calcium current amplitude in a concentration-dependent manner with an IC(50) of 24.7+/-2.0 microM. This effect of genistein was accompanied by deceleration of channel activation and acceleration of channel inactivation. Intracellular application of neither genistein nor genistin had a significant effect on the calcium current. Extracellular application of 50 microM tyrphostin AG213 and its inactive analogue, tyrphostin AG9, did not affect the current through the Ca(V)3.1 channel. The effect of genistein on the channel was also not affected by the presence of catalytically active PTK, p60(c-src) inside the cell. We have concluded that genistein directly inhibited the channel. This mechanism does not involve a PTK-dependent pathway. The alteration of the channel kinetics by genistein suggests an interaction with the voltage sensor of the channel together with the channel pore occlusion.

IP3 type 1 receptors in the heart: their predominance in atrial walls with ganglion cells.

Previously we have shown that inositol 1,4,5-trisphosphate (IP3) receptors (IP3Rs) are abundantly expressed in the atria of rat hearts. Since arrangement of atria is very heterogeneous, in this work we focused on the precise localization of IP3 receptors in the left atrium, where the gene expression of the type 1 IP3R was the highest. The mRNA levels of the IP3 type 1 receptors in the left atrium, left ventricle and myocytes were determined using real-time polymerase chain reaction and Taqman probe. For precise localization, immunohistochemistry with the antibody against type 1 IP3Rs was performed. The mRNA of type 1 IP3 receptor was more than three times higher in the left atrium than in the left ventricle, as determined by real-time PCR. Expression of the type 1 IP3 receptor mRNA was higher in the atria, especially in parts containing cardiac ganglion cells. The atrial auricles, which are particularly free of ganglion cells, and the ventricles (wall of the right and left ventricle and ventricular septum) contained four to five times less IP3 receptors than atrial samples with ganglia. IP3R type 1 immunoreactivity detected by a confocal microscope attributed the most condensed signal on ganglionic cells, although light immunoreactivity was also seen in cardiomyocytes. These results show that type 1IP3 receptors predominate in intrinsic neuronal ganglia of cardiac atria.

Inorganic mercury and methylmercury inhibit the Cav3.1 channel expressed in human embryonic kidney 293 cells by different mechanisms.

Part of the neurotoxic effects of inorganic mercury (Hg(2+)) and methylmercury (MeHg) was attributed to their interaction with voltage-activated calcium channels. Effects of mercury on T-type calcium channels are controversial. Therefore, we investigated effects of Hg(2+) and MeHg on neuronal Ca(v)3.1 (T-type) calcium channel stably expressed in the human embryonic kidney (HEK) 293 cell line. Hg(2+) acutely inhibited current through the Ca(v)3.1 calcium channel in concentrations 10 nM and higher with an IC(50) of 0.63 +/- 0.11 microM and a Hill coefficient of 0.73 +/- 0.08. Inhibition was accompanied by strong deceleration of current activation, inactivation, and deactivation. The current-voltage relation was broadened, and its peak was shifted to a more depolarized membrane potentials by 1 microM Hg(2+). MeHg in concentrations between 10 nM and 100 microM inhibited the current through the Ca(v)3.1 calcium channel with an IC(50) of 13.0 +/- 5.0 microM and a Hill coefficient of 0.47 +/- 0.09. Low concentration of MeHg (10 pM to 1 nM) had both positive and negative effects on the current amplitude. Micromolar concentrations of MeHg reduced the speed of current activation and accelerated current inactivation and deactivation. The current-voltage relation was not affected. Up to 72 h of exposure to 10 nM MeHg had no significant effect on current amplitude, whereas 72-h-long exposure to 1 nM MeHg increased significantly current density. Acute treatment with Hg(2+) or MeHg did not affect HEK 293 cell viability. In conclusion, interaction with the Ca(v)3.1 calcium channel may significantly contribute to neuronal symptoms of mercury poisoning during both acute poisoning and long-term environmental exposure.

Voltage-dependent calcium channels.

Voltage-activated calcium channels can be divided into two subgroups based on their activation threshold, low-voltage-activated (LVA) and high-voltage-activated (HVA). Auxiliary subunits of the HVA calcium channels contribute significantly to biophysical properties of the channels. We have cloned and characterized members of two families of auxiliary subunits: alpha2delta and gamma. Two new alpha2delta subunits, alpha2delta-2 and alpha2delta-3, regulate all classes of HVA calcium channels. While the ubiquitous alpha2delta-2 modulates both neuronal and non-neuronal channels with similar efficiency, the alpha2delta-3 subunit regulates Ca(v)2.3 channels more effectively. Furthermore, alpha2delta-2 may modulate the LVA Ca(v)3.1 channel. Four new gamma subunits, gamma-2, gamma-3, gamma-4 and gamma-5, were characterized. The gamma-2 subunit modulated both the non-neuronal Ca(v)1.2 channel and the neuronal Ca(v)2.1 channel. The gamma-4 subunit affected only the Ca(v)2.1 channel. The gamma-5 subunit may be a regulatory subunit of the LVA Ca(v)3.1 channel. The Ca(v)1.2 channel is a major target for treatment of cardiovascular diseases. We have mapped the interaction site for clinically important channel blockers - dihydropyridines (DHPs) - and analysed the underlying inhibition mechanism. High-affinity inhibition is characterized by interaction with inactivated state of the channel. Its structural determinants are amino acids of the IVS6 segment, with smaller contribution of the IS6 segment, which contributes to voltage-dependence of DHP inhibition. Removal of amino acids responsible for the high-affinity inhibition revealed a low-affinity open channel block, in which amino acids of the IIIS5 and IIIS6 segments take part. Experiments with a permanently charged DHP suggested that there is another low-affinity interaction site on the alpha(1) subunit. We have cloned and characterized murine neuronal LVA Ca(v)3.1 channel. The channel has high sensitivity to the organic blocker mibefradil, moderate sensitivity to phenytoin, and low sensitivity to ethosuximide, amiloride and valproat. The channel is insensitive to tetrodotoxin and DHPs. The inorganic blockers Ni2+ and Cd2+ are moderately effective compared to La3+. The current through the Ca(v)3.1 channel inactivates faster with Ba2+ compared to Ca2+. Molecular determinants of fast inactivation are located in amino side of the intracellular carboxy terminus. The voltage dependence of charge movement is very shallow compared to the voltage dependence of current activation. Transfer of 30 % of charge correlates with activation of 70 % of measurable macroscopic current. Prolonged depolarization does not immobilize charge movement of the Ca(v)3.1 channel.

Ca2+- and voltage-dependent inactivation of the expressed L-type Ca(v)1.2 calcium channel.

Ca2+-dependent regulation of the ion current through the alpha1Cbeta2aalpha2delta-1 (L-type) calcium channel transiently expressed in HEK 293 cells was investigated using whole cell patch clamp method. Ca2+ or Na+ ions were used as a charge carrier. Intracellular Ca2+ was either buffered by 10 mM EGTA or 200 microM Ca2+ was added into non-buffered intracellular solution. Free intracellular Ca2+ inactivated permanently about 80% of the L-type calcium current. The L-type calcium channel inactivated during a depolarizing pulse with two time constants, tau(fast) and tau(slow). Free intracellular calcium accelerated both time constants. Effect on the tau(slow) was more pronounced. About 80% of the channel inactivation during brief depolarizing pulse could be attributed to a Ca2+-dependent mechanism and 20% to a voltage-dependent mechanism. When Na+ ions were used as a charge carrier, the L-type current still inactivated with two time constants that were 10 times slower and were virtually voltage-independent. Ca2+ ions stabilized the inactivated state of the channel in a concentration-dependent manner.

Pharmacology of recombinant low-voltage activated calcium channels.

Several types of voltage- or ligand-activated calcium channels contribute to the excitability of neuronal cells. Low-voltage-activated (LVA), T-type calcium channels are characterised by relatively negative threshold of activation and therefore they can generate low-threshold spikes, which are essential for burst firing. At least three different proteins form T-type calcium current in neurons: Ca(v)3.1, Ca(v)3.2 and Ca(v)3.3. Expression of these proteins in various brain regions is complementary. Individual channel types could be distinguished by different sensitivity towards inorganic cations. This inhibition can contribute to the toxicity of some heavy metals. Selective inhibition of T-type calcium channels by organic blockers may have clinical importance in some forms of epilepsy. Mibefradil inhibits the expressed Ca(v2)3.1, Ca(v)3.2 and Ca(v)3.3 channels in nanomolar concentrations with Ca(v)3.3 channel having lowest affinity. The sensitivity of the expressed Ca(v)3.1 channel to the antiepileptic drugs, valproate and ethosuximide, is low. Ca(v)3.1 channel is moderately sensitive to phenytoin. The Ca(v)3.2 channel is sensitive to ethosuximide, amlodipine and amiloride. All three LVA calcium channels are moderately sensitive to active metabolites of methosuximide, i.e. alpha-methyl-alpha-phenylsuccinimide. Several neuroleptics inhibit all three LVA channels in clinically relevant concentrations. All three channels are also inhibited by the endogenous cannabinoid anandamide. A high affinity peptide blocker for these Ca channels is the scorpion toxin kurtoxin which inhibits the Ca(v)3.1 and Ca(v)3.2, but not the Ca(v)3.3 channel in nanomolar concentrations. Nitrous oxide selectively inhibits the Ca(v)3.2, but not the Ca(v)3.1 channel. The Ca(v)3.2, but not the Ca(v)3.1 channel is potentiated by stimulation of Ca(2+)/CaM-dependent protein kinase.

Inhibition of Cav3.1 channel by silver ions.

We have investigated the effects of AgCl and AgNO3 on the Cav3.1 calcium channels stably expressed in the HEK 293 cells. Ca2+ was used as a charge carrier. Both forms of Ag+ blocked the Cav3.1 channel and negatively shifted the I-V relations in a concentration-dependent manner. The inhibition of current amplitude by AgCl was voltage-dependent and increased with increasing amplitude of the depolarizing pulse. Furthermore, AgCl but not AgNO3 accelerated the kinetics of current activation. No effect on current inactivation or steady-state inactivation of the channel was observed for AgCl or AgNO3.

Gating of the expressed Cav3.1 calcium channel.

Intramembrane charge movement originating from Cav3.1 (T-type) channel expressed in HEK 293 cells was investigated. Ion current was blocked by 1 mM La3+. Charge movement was detectable for depolarizations above approximately -70 mV and saturated above +60 mV. The voltage dependence of charge movement followed a single Boltzmann function with half-maximal activation voltage +12.9 mV and +12.3 mV and with slopes of 22.4 mV and 18.1 mV for the ON- and OFF-charge movement, respectively. Inactivation of I(Ca) by prolonged depolarization pulse did not immobilize intramembrane charge movement in the Cav3.1 channel.

The amino side of the C-terminus determines fast inactivation of the T-type calcium channel alpha1G.

We analysed the kinetic properties of the fast inactivating T-type calcium channel alpha1G in HEK 293 cells transfected with different alpha1G chimeras, containing the N-terminus, III-IV linker or various C-terminal regions of the slowly inactivating L-type alpha1C. A highly negatively charged region of 23 amino acids at the amino side of the intracellular carboxy terminus of alpha1G was found to be critical for fast inactivation. The N-terminus of alpha1G does not seem to be necessary for inactivation of the T-type calcium channel because replacement of the a1G N-terminus with the alpha1C N-terminus did not influence channel kinetics at all. Replacing the III-IV linker of alpha1G with that of a1C decreased the rate of inactivation at -20 mV from 15.8 +/- 1.8 to 8.5 +/- 1.1 ms, and shifted the potential for half-maximal inactivation from -69.6 +/- 0.8 to -54.0 +/- 1.7 mV. However, these parameters were not significantly different at other potentials. We suggest a putative 'ball-and-chain'-like mechanism for inactivation in which the negative charges function as an acceptor domain for a ball, hypothetically located at a different intracellular part of the channel. In addition, transferring the IQ motif and EF hand of alpha1C to alpha1G does not confer Ca2+-dependent inactivation on alpha1G, suggesting that other sequences besides the C-terminus are needed for Ca2+-dependent inactivation of alpha1C.

State- and isoform-dependent interaction of isradipine with the alpha1C L-type calcium channel.

We investigated the dihydropyridine (DHP) inhibition of barium current (I(Ba)) through the smooth muscle alpha1Ch and cardiac alpha1Ca splice variants of the L-type calcium channel using a whole-cell patch-clamp method. IC50 values for inhibition of current amplitude of the alpha1Cb channel were three to fivefold lower than for the alpha1Ca channel at holding potentials between -80 mV and -30 mV. No difference was found in either the transition of the channels into an inactivated state in the absence or presence of drug, or in the recovery from inactivation under control conditions. However, isradipine slowed the recovery from inactivation of alpha1Ca more effectively than alpha1Cb. To evaluate the interaction of isradipine with the open channel state of both splice variants, interactions with the inactivated state were selectively suppressed by the mutation of three amino acids in the IVS6 segment (Y1485I, M1486F, I1493L) in alpha1CbCh30 and alpha1CaCh30 channels. The extent of this interaction was seen by an acceleration of current decay. This was found to be identical for both splice variants. Our results suggest that the higher DHP selectivity of the alpha1Cb versus the alpha1Ca channel is caused by the structural difference in the binding site and not by different transitions between resting, open and inactivated states.