Ca2+ channel inactivation in small mesenteric arteries of WKY and SHR

BACKGROUND: This study was designed to test the hypothesis that differences exist in the inactivation properties of voltage-gated Ca(2+) channels (Ca(V)) in hypertensive arterial smooth muscle cells (ASMCs), and that these differences contribute to enhanced Ca(V) activity. METHODS: The properties of Ca(V) were studied in freshly isolated myocytes from small mesenteric arteries (SMAs) of Wistar-Kyoto (WKY) and spontaneously hypertensive rats (SHRs) using whole-cell patch-clamp methods. RESULTS: Peak currents (I(Ca)) were larger in SHR with either 2 mmol/l Ca(2+) or Ba(2+) as the charge carrier. In WKY and SHR, the peak current was larger with Ba(2+) than with Ca(2+) with no difference in their ratio. The voltage dependence of Ca(V) activation was shifted to the left in SHR as compared to WKY for Ca(2+) but not for Ba(2+), while availability was not different. The time course of inactivation of current could be represented by two time constants, both of which were larger in SHR than in WKY and also larger for Ba(2+) than for Ca(2+), with a greater fraction of inactivation being associated with the process slower in SHR and with Ba(2+). The time courses of availability, inactivation, and recovery from inactivation were faster in SHR than in WKY in the case of Ca(2+), but there was no difference in the case of Ba(2+). CONCLUSIONS: These results demonstrate that there are differences between WKY and SHR in the inactivation properties of SMA Ca(V), and that these differences could contribute to larger steady-state currents. The differences cannot be explained merely by the presence of a larger number of identical Ca(V) complexes, and it appears likely that differences in intrinsic compositions, primary structures, and/or regulation are involved.     

Engineered calmodulins reveal the unexpected eminence of Ca2+ channel inactivation in controlling heart excitation

Engineered calmodulins (CaMs), rendered Ca2+-insensitive by mutations, function as dominant negatives in heterologous systems, and have revealed mechanisms of ion channel modulation by Ca2+/CaM. The use of these CaMs in native mammalian cells now emerges as a strategy to unmask the biology of such Ca2+ feedback. Here, we developed recombinant adenoviruses bearing engineered CaMs to facilitate their expression in adult heart cells, where Ca2+ regulation may be essential for moment-to-moment control of the heartbeat. Engineered CaMs not only eliminated the Ca2+-dependent inactivation of native calcium channels, but exposed an unexpectedly large impact of removing such feedback: the unprecedented (4- to 5-fold) prolongation of action potentials. This striking result recasts the basic paradigm for action-potential control and illustrates the promise of virally delivered engineered CaM to investigate the biology of numerous other CaM-signaling pathways.     

Pharmacological basis of Ca2+ channels and Ca2+ channel antagonists

Ca2+ plays multiple roles in muscle E-C coupling, secretion, and neural transmission, in addition to survival, proliferation, and death of cells. The voltage-dependent L-type Ca2+ channel is a transmembrane protein that selectively permeates Ca2+ on activation by membrane depolarization. Ca2+ channel blockers (or Ca2+ antagonists) selectively block this channel. The blocking action is exerted in a tissue-specific manner, which underlies the unique pharmacological properties of Ca2+ channel blockers. The later generation of slowly-acting and long-lasting Ca2+ channel blockers has been designed to overcome the side effects of classical Ca2+ channel blockers. The pharmacological and molecular basis for the unique action of Ca2+ channel blockers will be discussed.     

Linoleic acid induces Ca2+-induced inactivation of voltage-dependent Ca2+ currents in rat pancreatic beta-cells

Free fatty acids (FFAs) regulate insulin secretion in a complex pattern and induce pancreatic beta-cell dysfunction in type 2 diabetes. Voltage-dependent Ca2+ channels (VDCC) in beta-cells play a major role in regulating insulin secretion. The aim of present study is to clarify the action of the FFA, linoleic acid, on VDCC in beta-cells. The VDCC current in primary cultured rat beta-cells were recorded under nystatin-perforated whole-cell recording configuration. The VDCC was identified as high-voltage-gated Ca2+ channels due to there being no difference in current amplitude under holding potential between -70 and -40 mV. Linoleic acid (10 microM) significantly inhibited VDCC currents in beta-cells, an effect which was fully reversible upon washout. Methyl-linoleic acid, which does not activate G protein coupled receptor (GPR)40, neither did alter VDCC current in rat beta-cells nor did influence linoleic acid-induced inhibition of VDCC currents. Linoleic acid-induced inhibition of VDCC current was not blocked by preincubation of beta-cells with either the specific protein kinase A (PKA) inhibitor, H89, or the PKC inhibitor, chelerythrine. However, pretreatment of beta-cells with thapsigargin, which depletes intracellular Ca2+ stores, completely abolished linoleic acid-induced decrease in VDCC current. Measurement of intracellular Ca2+ concentration ([Ca2+](i)) illustrated that linoleic acid induced an increase in [Ca2+](i) and that thapsigargin pretreatment inhibited this increase. Methyl-linoleic acid neither did induce increase in [Ca2+](i) nor did it block linoleic acid-induced increase in [Ca2+](i). These results suggest that linoleic acid stimulates Ca2+ release from intracellular Ca2+ stores and inhibits VDCC currents in rat pancreatic beta-cells via Ca2+-induced inactivation of VDCC.     

Ca2+-induced inhibition of the cardiac Ca2+ channel depends on calmodulin

Ca2+-induced inhibition of alpha1C voltage-gated Ca2+ channels is a physiologically important regulatory mechanism that shortens the mean open time of these otherwise long-lasting high-voltage-activated channels. The mechanism of action of Ca2+ has been a matter of some controversy, as previous studies have proposed the involvement of a putative Ca2+-binding EF hand in the C terminus of alpha1C and/or a sequence downstream from this EF-hand motif containing a putative calmodulin (CaM)-binding IQ motif. Previously, using site directed mutagenesis, we have shown that disruption of the EF-hand motif does not remove Ca2+ inhibition. We now show that the IQ motif binds CaM and that disruption of this binding activity prevents Ca2+ inhibition. We propose that Ca2+ entering through the voltage-gated pore binds to CaM and that the Ca/CaM complex is the mediator of Ca2+ inhibition.     

Ca2+ release-activated Ca2+ channel blockade as a potential tool in antipancreatitis therapy

Alcohol-related acute pancreatitis can be mediated by a combination of alcohol and fatty acids (fatty acid ethyl esters) and is initiated by a sustained elevation of the Ca²⁺ concentration inside pancreatic acinar cells ([Ca²⁺]_i), due to excessive release of Ca²⁺ stored inside the cells followed by Ca²⁺ entry from the interstitial fluid. The sustained [Ca²⁺]_i elevation activates intracellular digestive proenzymes resulting in necrosis and inflammation. We tested the hypothesis that pharmacological blockade of store-operated or Ca²⁺ release-activated Ca²⁺ channels (CRAC) would prevent sustained elevation of [Ca²⁺]_i and therefore protease activation and necrosis. In isolated mouse pancreatic acinar cells, CRAC channels were activated by blocking Ca²⁺ ATPase pumps in the endoplasmic reticulum with thapsigargin in the absence of external Ca²⁺. Ca²⁺ entry then occurred upon admission of Ca²⁺ to the extracellular solution. The CRAC channel blocker developed by GlaxoSmithKline, GSK-7975A, inhibited store-operated Ca²⁺ entry in a concentration-dependent manner within the range of 1 to 50 μM (IC₅₀ = 3.4 μM), but had little or no effect on the physiological Ca²⁺ spiking evoked by acetylcholine or cholecystokinin. Palmitoleic acid ethyl ester (100 μM), an important mediator of alcohol-related pancreatitis, evoked a sustained elevation of [Ca²⁺]_i, which was markedly reduced by CRAC blockade. Importantly, the palmitoleic acid ethyl ester-induced trypsin and protease activity as well as necrosis were almost abolished by blocking CRAC channels. There is currently no specific treatment of pancreatitis, but our data show that pharmacological CRAC blockade is highly effective against toxic [Ca²⁺]_i elevation, necrosis, and trypsin/protease activity and therefore has potential to effectively treat pancreatitis.     

Thalamic Cav3.1 T-type Ca2+ channel plays a crucial role in stabilizing sleep

It has long been suspected that sensory signal transmission is inhibited in the mammalian brain during sleep. We hypothesized that Cav3.1 T-type Ca2+ channel currents inhibit thalamic sensory transmission to promote sleep. We found that T-type Ca2+ channel activation caused prolonged inhibition (>9 s) of action-potential firing in thalamic projection neurons of WT but not Cav3.1 knockout mice. Inhibition occurred with synaptic transmission blocked and required an increase of intracellular Ca2+. Furthermore, focal deletion of the gene encoding Cav3.1 from the rostral-midline thalamus by using Cre/loxP recombination led to frequent and prolonged arousal, which fragmented and reduced sleep. Interestingly, sleep was not disturbed when Cav3.1 was deleted from cortical pyramidal neurons. These findings support the hypothesis that thalamic T-type Ca2+ channels are required to block transmission of arousal signals through the thalamus and to stabilize sleep.     

钙激活性钾通道是人小肠上皮细胞的容积调节性通道(英文)

目的 :研究细胞容积调节机制 ,探讨人类小肠上皮细胞调节性容积减小 （RVD）过程中离子通道的作用及其种类。方法 :膜片钳全细胞记录和单通道记录法记录培养的人类小肠上皮细胞 RVD过程中电流的变化 ,细胞容积测定法观察 RVD过程中特异性钙激活性钾通道阻断剂 （clotrimazole）的作用。结果 :全细胞记录法证实细胞 RVD过程中 K+通道和 Cl-通道电流同时被激活 ,该 K+通道电流具有明显的钙依赖性并可被 clotrim azole阻断。单通道记录法进一步证实 RVD过程中激活的 K+通道为 Interm ediate- conductance钙激活性钾通道。结论 :人类小肠上皮细胞在低渗溶液作用下具有 RVD过程 ,钙激活性钾通道在 RVD过程中具有十分重要的作用。     

Molecular coupling of a Ca2+-activated K+ channel to L-type Ca2+ channels via alpha-actinin2

Cytoskeletal proteins are known to sculpt the structural architecture of cells. However, their role as bridges linking the functional crosstalk of different ion channels is unknown. Here, we demonstrate that a small conductance Ca(2+)-activated K(+) channels (SK2 channel), present in a variety of cells, where they integrate changes in intracellular Ca(2+) concentration [Ca(2+)(i)] with changes in K(+) conductance and membrane potential, associate with L-type Ca(2+) channels; Ca(v)1.3 and Ca(v)1.2 through a physical bridge, alpha-actinin2 in cardiac myocytes. SK2 channels do not physically interact with L-type Ca(2+) channels, instead, the 2 channels colocalize via their interaction with alpha-actinin2 cytoskeletal protein. The association of SK2 channel with alpha-actinin2 localizes the channel to the entry of external Ca(2+) source, which regulate the channel function. Furthermore, we demonstrated that the functions of SK2 channels in atrial myocytes are critically dependent on the normal expression of Ca(v)1.3 Ca(2+) channels. Null deletion of Ca(v)1.3 channel results in abnormal function of SK2 channel and prolongation of repolarization and atrial arrhythmias. Our study provides insight into the molecular mechanisms of the coupling of SK2 channel with voltage-gated Ca(2+) channel, and represents the first report linking the coupling of 2 different types of ion channels via cytoskeletal proteins.     

钙池操纵的钙通道与支气管哮喘气道平滑肌功能调控

钙信号是调控气道平滑肌细胞功能的重要机制.细胞内钙离子浓度受肌浆网内钙释放和胞外钙内流的双重调控.钙池操纵的钙通道(SOC)是哮喘气道平滑肌细胞外钙内流的重要机制,在哮喘气道高反应性和气道重塑中具有重要作用.近年来,通过分子生物学方法,已经发现了SOC相关调控分子STIM1和通道组成分子Orail,为深入研究气道平滑肌SOC的结构和功能关系,以及在哮喘防治中的作用提供了基础.本文就SOC及其与气道平滑肌功能的关系作一综述.     

大电导钙离子激活钾通道在心血管疾病中的研究进展

冠状动脉平滑肌细胞膜上存在许多大电导钙离子激活钾（BKCa）通道,在维持细胞正常生理活动中起重要作用。研究发现当细胞膜去极化或/（和）细胞内钙离子增加时,BKCa通道激活,开放增加,钾离子外流,细胞膜超极化,血管舒张。而在高血压、糖尿病、缺氧、心力衰竭和老化等许多病理情况下,BKCa通道功能发生改变,从而影响对血管功能的调节。本文主要综述近年来BK通道在心血管疾病中的研究进展。     

K+ and Ca2+ channel activity and cytosolic [Ca2+] in oxygen-sensing tissues.

Ion channels are known to participate in the secretory or mechanical responses of chemoreceptor cells to changes in oxygen tension (P(O2)). We review here the modifications of K+ and Ca2+ channel activity and the resulting changes in cytosolic [Ca2+] induced by low P(O2) in glomus cells and arterial smooth muscle which are well known examples of O2-sensitive cells. Glomus cells of the carotid body behave as presynaptic-like elements where hypoxia produces a reduction of K+ conductance leading to enhanced membrane excitability, Ca2+ entry and release of dopamine and other neurotransmitters. In arterial myocytes, hypoxia can inhibit or potentiate Ca2+ channel activity, thus regulating cytosolic [Ca2+] and contraction. Ca2+ channel inhibition is observed in systemic myocytes and most conduit pulmonary myocytes, whereas potentiation is seen in a population of resistance pulmonary myocytes. The mechanism whereby O2 modulates ion channel activity could depend on either the direct allosteric modulation by O2-sensing molecules or redox modification by reactive chemical species.     

The auxiliary subunit gamma 1 of the skeletal muscle L-type Ca2+ channel is an endogenous Ca2+ antagonist

Ca2+ channels play crucial roles in cellular signal transduction and are important targets of pharmacological agents. They are also associated with auxiliary subunits exhibiting functions that are still incompletely resolved. Skeletal muscle L-type Ca2+ channels (dihydropyridine receptors, DHPRs) are specialized for the remote voltage control of type 1 ryanodine receptors (RyR1) to release stored Ca2+. The skeletal muscle-specific gamma subunit of the DHPR (gamma 1) down-modulates availability by altering its steady state voltage dependence. The effect resembles the action of certain Ca2+ antagonistic drugs that are thought to stabilize inactivated states of the DHPR. In the present study we investigated the cross influence of gamma 1 and Ca2+ antagonists by using wild-type (gamma+/+) and gamma 1 knockout (gamma-/-) mice. We studied voltage-dependent gating of both L-type Ca2+ current and Ca2+ release and the allosteric modulation of drug binding. We found that 10 microM diltiazem, a benzothiazepine drug, more than compensated for the reduction in high-affinity binding of the dihydropyridine agent isradipine caused by gamma 1 elimination; 5 muM devapamil [(-)D888], a phenylalkylamine Ca2+ antagonist, approximately reversed the right-shifted voltage dependence of availability and the accelerated recovery kinetics of Ca2+ current and Ca2+ release. Moreover, the presence of gamma 1 altered the effect of D888 on availability and strongly enhanced its impact on recovery kinetics demonstrating that gamma 1 and the drug do not act independently of each other. We propose that the gamma 1 subunit of the DHPR functions as an endogenous Ca2+ antagonist whose task may be to minimize Ca2+ entry and Ca2+ release under stress-induced conditions favoring plasmalemma depolarization.     

Voltage-gated Ca2+ channel in mouse myeloma cells.

Electrical properties of the cell membrane were studied in the neoplastic lymphocyte, mouse myeloma cell line S194, by using the whole-cell patch clamp technique. Inward Ca2+ currents due to voltage-gated Ca2+ channels were found. The current, which decayed exponentially after reaching a peak, was first activated at about -50 mV and attained its maximum peak amplitude at about -20 mV in a 10 mM Ca2+ solution. Outward current was negligible for the potential range more negative than +30 mV. The channel was permeable to Sr2+ and Ba2+ in addition to Ca2+. Among these species, Sr2+ carried the greatest current. The time constants of the decay of the current depended neither on the species nor on the concentration of charge carrier. The steady-state inactivation was observed at potentials more negative than those at which the inward Ca2+ current was activated. Thus, we concluded that the inactivation of the channel was mainly voltage dependent. For reasons that are not yet understood, the amplitude of the Ca2+ current varied greatly among cells.