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.
Inhibition of T-type Ca(2+) channels has been proposed to play a role in the therapeutic action of succinimide antiepileptic drugs. Despite the widespread acceptance of this hypothesis, recent studies using rat and cat neurons have failed to confirm inhibition of T-type currents at therapeutically relevant concentrations. The present study re-examines this issue using the three cloned human channels that constitute the T-type family: alpha 1G, alpha 1H, and alpha 1I. The cloned cDNAs were stably transfected and expressed into mammalian cells, leading to the appearance of typical T-type currents. The results demonstrate that both ethosuximide and the active metabolite of methsuximide, alpha-methyl-alpha-phenylsuccinimide (MPS), block human T-type channels in a state-dependent manner, with higher affinity for inactivated channels. In contrast, succinimide analogs that are not anticonvulsive were relatively poor blockers. The apparent affinity of MPS for inactivated states of the three channels was estimated using two independent measures: K(I) for alpha 1G and alpha 1I was 0.3 to 0.5 mM and for alpha 1H was 0.6 to 1.2 mM. T-type channels display current at the end of long pulses (persistent current), and this current was especially sensitive to block (ethosuximide IC(50) = 0.6 mM). These drugs also reduced both the size of the T-type window current region and the currents elicited by a mock low threshold spike. We conclude that succinimide antiepileptic drugs are capable of blocking human T-type channels at therapeutically relevant concentrations.
Functional activity of voltage-gated sodium channels (VGSC) has been associated to the invasion and metastasis behaviors of prostate, breast and some other types of cancer. We previously reported the functional expression of VGSC in primary cultures and biopsies derived from cervical cancer (CaC). Here, we investigate the relative expression levels of VGSC subunits and its possible role in CaC. Quantitative real-time PCR revealed that mRNA levels of Na V 1.6 a-subunit in CaC samples were~40-fold higher than in noncancerous cervical (NCC) biopsies. A Na V 1.7 a-subunit variant also showed increased mRNA levels in CaC (~20-fold). All four Na V b subunits were also detected in CaC samples, being Na V b1 the most abundant. Proteins of Na V 1.6 and Na V 1.7 a-subunits were immunolocalized in both NCC and CaC biopsies and in CaC primary cultures as well; however, although in NCC sections proteins were mainly relegated to the plasma membrane, in CaC biopsies and primary cultures the respective signal was stronger and widely distributed in both cytoplasm and plasma membrane. Functional activity of Na V 1.6 channels in the plasma membrane of CaC cells was confirmed by whole-cell patch-clamp experiments using Cn2, a Na V 1.6-specific toxin, which blocked 30% of the total sodium current. Blocking of sodium channels VGSC with tetrodotoxin and Cn2 did not affect proliferation neither migration, but reduced by~20% the invasiveness of CaC primary culture cells in vitro assays. We conclude that Na V 1.6 is upregulated in CaC and could serve as a novel molecular marker for the metastatic behavior of this carcinoma.Cervical cancer (CaC) is the third most common female tumor worldwide and the second in developing countries, with an estimated annual incidence of 452,000 cases. 1 In view of the finding that carcinogenic human papillomavirus (HPV) infections cause virtually all CaC cases, recently a new approach for CaC prevention has emerged with the HPV vaccination of younger women (aged 18 years). 2 Despite the highly significant advance that the vaccine itself represents, a mathematical model has predicted an increase in CaC incidence if vaccination is not followed by a continuous Pap smear screening program. 3 Therefore, the finding of effective diagnosis and therapeutic strategies for CaC still remains as a priority.Lately, there has been an increasing amount of evidences that correlate the function of ion channels with several aspects of cancer progression. 4,5 In particular, voltage-gated sodium channels (VGSC) have been clearly associated to invasion and metastasis behaviors in several types of cancer, including breast, colon, lung, ovary and prostate. 6-10 Sodium channels are protein complexes formed by a large a-subunit and smaller auxiliary b-subunits. The a-subunit alone is sufficient to form a functional channel, but its biophysical properties, trafficking and anchoring to the cell membrane are modulated by b-subunits. 11 The VGSC family is composed by nine different a-subunits (Na V 1.1-Na V 1.9) and four bsubunits (Na...
ABSTRACT-Over the past few years increasing attention has been focused on T-type calcium channels and their possible physiological and pathophysiological roles. Efforts toward elucidating the exact role(s) of these calcium channels have been hampered by the lack of T-type specific antagonists, resulting in the subsequent use of less selective calcium channel antagonists. In addition, the activity of these blockers often varies with cell or tissue type, as well as recording conditions. This review summarizes a variety of compounds that exhibit varying degrees of blocking activity towards T-type Ca 2+ channels. It is designed as an aid for researchers in need of antagonists to study the biophysical and pathological nature of T-type channels, as well as a starting point for those attempting to develop potent and selective antagonists of the channel.
Cervical cancer (CaC) is the third most frequent cause of death from cancer among women in the world and the first in females of developing countries. Several ion channels are upregulated in cancer, actually potassium channels have been suggested as tumor markers and therapeutic targets for CaC. Voltage-gated sodium channels (VGSC) activity is involved in proliferation, motility, and invasion of prostate and breast cancer cells; however, the participation of this type of channels in CaC has not been explored. In the present study, we identified both at the molecular and electrophysiological level VGSC in primary cultures from human cervical carcinoma biopsies. With the whole cell patch clamp technique, we isolated and identified a voltage-gated Na(+) current as the main component of the inward current in all investigated cells. Sodium current was characterized by its kinetics, voltage dependence, sensitivity to tetrodotoxin (TTX) block and dependence to [Na(+)](o). By analyzing the expression of mRNAs encoding TTX-sensitive Na(+) channel alpha subunits with standard RT-PCR and specific primers, we detected Na(v)1.2, Na(v)1.4, Na(v)1.6, and Na(v)1.7 transcripts in total RNA obtained from primary cultures and biopsies of CaC. Restriction enzyme analysis of PCR products was consistent with the molecular nature of the corresponding genes. Notably, only transcripts for Na(v)1.4 sodium channels were detected in biopsies from normal cervix. The results show for the first time the functional expression of VGSC in primary cultures from human CaC, and suggest that these channels might be considered as potential molecular markers for this type of cancer.
Numerous sperm functions including the acrosome reaction (AR) are associated with Ca 2+ in£ux through voltage-gated Ca 2+ (Ca V ) channels. Although the electrophysiological characterization of Ca 2+ currents in mature sperm has proven di⁄cult, functional studies have revealed the presence of lowthreshold (Ca V 3) channels in spermatogenic cells. However, the molecular identity of these proteins remains unde¢ned. Here, we identi¢ed by reverse transcription polymerase chain reaction the expression of Ca V 3.3 mRNA in mouse male germ cells, an isoform not previously described in these cells. Immunoconfocal microscopy revealed the presence of the three Ca V 3 channel isoforms in mouse spermatogenic cells. In mature mouse sperm only Ca V 3.1 and Ca V 3.2 were detected in the head, suggesting its participation in the AR. Ca V 3.1 and Ca V 3.3 were found in the principal and the midpiece of the £agella. All Ca V 3 channels are also present in human sperm, but only to a minor extent in the head. These ¢ndings were corroborated by immunogold transmission electron microscopy. Tail localization of Ca V 3 channels suggested they may participate in motility, however, mibefradil and gossypol concentrations that inhibit Ca V 3 channels did not signi¢cantly a¡ect human sperm motility. Only higher mibefradil doses that can block high-threshold (HVA) Ca V channels caused small but signi¢cant motility alterations. Antibodies to HVA channels detected Ca V 1.3 and Ca V 2.3 in human sperm £agella. ß 2004 Published by Elsevier B.V. on behalf of the Federation of European Biochemical Societies.
Bovine adrenal zona fasciculata (AZF) cells express a noninactivating K+ current (IAC) that is inhibited by adrenocorticotropic hormone and angiotensin II at subnanomolar concentrations. Since IAC appears to set the membrane potential of AZF cells, these channels may function critically in coupling peptide receptors to membrane depolarization, Ca2+ entry, and cortisol secretion. IAC channel activity may be tightly linked to the metabolic state of the cell. In whole cell patch clamp recordings, MgATP applied intracellularly through the patch electrode at concentrations above 1 mM dramatically enhanced the expression of IAC K+ current. The maximum IAC current density varied from a low of 8.45 ± 2.74 pA/pF (n = 17) to a high of 109.2 ± 26.3 pA/pF (n = 6) at pipette MgATP concentrations of 0.1 and 10 mM, respectively. In the presence of 5 mM MgATP, IAC K+ channels were tonically active over a wide range of membrane potentials, and voltage-dependent open probability increased by only ∼30% between −40 and +40 mV. ATP (5 mM) in the absence of Mg2+ and the nonhydrolyzable ATP analog AMP-PNP (5 mM) were also effective at enhancing the expression of IAC, from a control value of 3.7 ± 0.1 pA/pF (n = 3) to maximum values of 48.5 ± 9.8 pA/pF (n = 11) and 67.3 ± 23.2 pA/pF (n = 6), respectively. At the single channel level, the unitary IAC current amplitude did not vary with the ATP concentration or substitution with AMP-PNP. In addition to ATP and AMP-PNP, a number of other nucleotides including GTP, UTP, GDP, and UDP all increased the outwardly rectifying IAC current with an apparent order of effectiveness: MgATP > ATP = AMP-PNP > GTP = UTP > ADP >> GDP > AMP and ATP-γ-S. Although ATP, GTP, and UTP all enhanced IAC amplitude with similar effectiveness, inhibition of IAC by ACTH (200 pM) occurred only in the presence of ATP. As little as 50 μM MgATP restored complete inhibition of IAC, which had been activated by 5 mM UTP. Although the opening of IAC channels may require only ATP binding, its inhibition by ACTH appears to involve a mechanism other than hydrolysis of this nucleotide. These findings describe a novel form of K+ channel modulation by which IAC channels are activated through the nonhydrolytic binding of ATP. Because they are activated rather than inhibited by ATP binding, IAC K+ channels may represent a distinctive new variety of K+ channel. The combined features of IAC channels that allow it to sense and respond to changing ATP levels and to set the resting potential of AZF cells, suggest a mechanism where membrane potential, Ca2+ entry, and cortisol secretion could be tightly coupled to the metabolic state of the cell through the activity of IAC K+ channels.
Mutations in the I-II loop of Ca v 3.2 channels were discovered in patients with childhood absence epilepsy. All of these mutations increased the surface expression of the channel, whereas some mutations, and in particular C456S, altered the biophysical properties of channels. Deletions around C456S were found to produce channels that opened at even more negative potentials than control, suggesting the presence of a gating brake that normally prevents channel opening. The goal of the present study was to identify the minimal sequence of this brake and to provide insights into its structure. A peptide fragment of the I-II loop was purified from bacteria, and its structure was analyzed by circular dichroism. These results indicated that the peptide had a high ␣-helical content, as predicted from secondary structure algorithms. Based on homology modeling, we hypothesized that the proximal region of the I-II loop may form a helix-loophelix structure. This model was tested by mutagenesis followed by electrophysiological measurement of channel gating. Mutations that disrupted the helices, or the loop region, had profound effects on channel gating, shifting both steady state activation and inactivation curves, as well as accelerating channel kinetics. Mutations designed to preserve the helical structure had more modest effects. Taken together, these studies showed that any mutations in the brake, including C456S, disrupted the structural integrity of the brake and its function to maintain these low voltage-activated channels closed at resting membrane potentials.
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