Modulation of the epithelial calcium channel, ECaC, by intracellular Ca2+

We have studied the modulation by intracellular Ca2+ of the epithelial Ca2+ channel, ECaC, heterologously expressed in HEK 293 cells. Whole-cell and inside-out patch clamp current recordings were combined with FuraII-Ca2+ measurements:1. Currents through ECaC were dramatically inhibited if Ca2+ was the charge carrier. This inhibition was dependent on the extracellular Ca2+ concentration and occurred also in cells buffered intracellularly with 10 mM BAPTA.2. Application of 30 mM [Ca(2)]e induced in non-Ca2+] buffered HEK 293 cells at -80 m V an increase in intracellular Ca2+([Ca2]i) with a maximum rate of rise of 241 +/-15nM/s (n= 18 cells) and a peak value of 891 +/- 106 nM. The peak of the concomitant current with a density of 12.3 +/- 2.6 pA/pF was closely correlated with the peak of the first-time derivative of the Ca2+ transient, as expected if the Ca2+ transient is due to influx of Ca2+. Consequently, no Ca2+] signal was observed in cells transfected with the Ca2+ impermeable ECaC mutant, D542A, in which an aspartate in the pore region was neutralized.3. Increasing [Ca2+]i by dialyzing the cell with pipette solutions containing various Ca2+] concentrations, all buffered with 10 mM BAPTA, inhibited currents through ECaC carried by either Na+ or Ca2+] ions. Half maximal inhibition of Ca(2+)currents in the absence of monovalent cations occurred at 67 nM (n between 6 and 8), whereas Na+ currents in the absence of Ca2+] and Mg2+ were inhibited with an IC50 of 89 nM (n between 6 and 10). Currents through ECaC in the presence of 1 mM Ca2+ and Na+, which are mainly carried by Ca2+, are inhibited by [Ca2]i with an IC50of 82 nM (n between 6 and 8). Monovalent cation currents through the Ca2+impermeable D542A ECaC mutant were also inhibited by an elevation of [Ca2]i (IC50 = 123 nM, n between 7 and 18). 4. The sensitivity of ECaC currents in inside-out patches for [Ca2]i was slightly shifted to higher concentrations as compared with whole cell measurements. Half-maximal inhibition occurred at 169 nM if Na+ was the charge carrier (n between 4 and 11) and 228 nM at 1 mM [Ca2]e (n between 4 and 8).5. Recovery from inhibition upon washout of extracellular Ca2+ (whole-cell configuration) or removal of Ca2+ from the inner side of the channel (inside-out patches) was slow in both conditions. Half-maximal recovery was reached after 96 +/- 34 s (n= 15) in whole-cell mode and after 135 +/- 23 s (n = 17) in inside-out patches.6. We conclude that influx of Ca2+ through ECaC and [Ca2]i induce feedback inhibition of ECaC currents, which is controlled by the concentration of Ca2+ in a micro domain near the inner mouth of the channel. Slow recovery seems to depend on dissociation of Ca( 2+ from an internal Ca2+ binding site at ECaC.     

The epithelial calcium channel, ECaC, is activated by hyperpolarization and regulated by cytosolic calcium.

The recently cloned epithelial Ca(2+) channel, ECaC, which is expressed in the apical membrane of 1,25-dihydroxyvitamin D(3)-responsible epithelia, was characterized in Xenopus laevis oocytes by measuring the Ca(2+)-activated Cl(-) current which is a sensitive read-out of the Ca(2+) influx. ECaC-expressing oocytes responded to a voltage ramp with a maximal inward current of -2.1 +/- 0.3 microA at a holding potential of -99 +/- 1 mV. The inward current decreased progressively at less negative potentials and at +50 mV a small Ca(2+)-induced outward current was observed. The Ca(2+) influx-evoked current at a hyperpolarizing pulse to -100 mV displayed a fast activation followed by a rapid but partial inactivation. Loading of the oocytes with the Ca(2+) chelator BAPTA delayed the activation and blocked the inactivation of ECaC. When a series of brief hyperpolarizing pulses were given a significant decline in the peak response and subsequent plateau phase was observed. In conclusion, the distinct electrophysiological features of ECaC are hyperpolarization-dependent activation, Ca(2+)-dependent regulation of channel conductance and desensitization during repetitive stimulation.     

Functional properties of the epithelial Ca2+ channel, ECaC.

ECaC is the first member of a new subfamily of Ca2+ channels embedded in the large TRPC family that includes numerous channel proteins. The channel has been proposed as the main gatekeeper of transcellular Ca2+ transport in kidney and intestine. The functional characterization of this channel is evolving rapidly and may have far reaching consequences for other channels of the TRPC family. The goal of this mini-review is to summarize the major functional and structural characteristics of ECaC, including (i) its proposed functional role, (ii) its channel structure and expression pattern, (iii) its main electrophysiological characteristics and (iv) its regulation.     

Modulation of the epithelial calcium channel, ECaC, by intracellular Ca

We have studied the modulation by intracellular Ca²⁺of the epithelial Ca²⁺channel, ECaC, heterologously expressed in HEK 293 cells. Whole-cell and inside-out patch clamp current recordings were combined with FuraII-Ca²⁺measurements:1. Currents through ECaC were dramatically inhibited if Ca²⁺was the charge carrier. This inhibition was dependent on the extracellular Ca²⁺concentration and occurred also in cells buffered intracellularly with 10 mM BAPTA.2. Application of 30 mM [Ca²]_einduced in non-Ca²] buffered HEK 293 cells at −80 m V an increase in intracellular Ca²⁺([Ca²]_i) with a maximum rate of rise of 241 ±15nM/s (n= 18 cells) and a peak value of 891 ± 106 nM. The peak of the concomitant current with a density of 12.3 ± 2.6 pA/pF was closely correlated with the peak of the first-time derivative of the Ca²⁺transient, as expected if the Ca²⁺transient is due to influx of Ca²⁺. Consequently, no Ca²⁺] signal was observed in cells transfected with the Ca²⁺impermeable ECaC mutant, D542A, in which an aspartate in the pore region was neutralized.3. Increasing [Ca²⁺]_iby dialyzing the cell with pipette solutions containing various Ca²⁺] concentrations, all buffered with 10 mM BAPTA, inhibited currents through ECaC carried by either Na⁺or Ca²⁺] ions. Half maximal inhibition of Ca²⁺currents in the absence of monovalent cations occurred at 67 nM (n between 6 and 8), whereas Na⁺currents in the absence of Ca²⁺] and Mg²⁺were inhibited with an IC₅₀of 89 nM (n between 6 and 10). Currents through ECaC in the presence of 1 mM Ca²⁺and Na⁺, which are mainly carried by Ca²⁺, are inhibited by [Ca²]_iwith an IC₅₀of 82 nM (n between 6 and 8). Monovalent cation currents through the Ca²⁺impermeable D542A ECaC mutant were also inhibited by an elevation of [Ca²]_i(IC₅₀= 123 nM, n between 7 and 18).4. The sensitivity of ECaC currents in inside-out patches for [Ca²]_iwas slightly shifted to higher concentrations as compared with whole cell measurements. Half-maximal inhibition occurred at 169 nM if Na⁺was the charge carrier (n between 4 and 11) and 228 nM at 1 mM [Ca²]_e(n between 4 and 8).5. Recovery from inhibition upon washout of extracellular Ca²⁺(whole-cell configuration) or removal of Ca²⁺from the inner side of the channel (inside-out patches) was slow in both conditions. Half-maximal recovery was reached after 96 ± 34 s (n= 15) in whole-cell mode and after 135 ± 23 s (n= 17) in inside-out patches.6. We conclude that influx of Ca²⁺through ECaC and [Ca²]_iinduce feedback inhibition of ECaC currents, which is controlled by the concentration of Ca²⁺in a micro domain near the inner mouth of the channel. Slow recovery seems to depend on dissociation of Ca²⁺from an internal Ca²⁺binding site at ECaC.     

Effect of age, vitamin D, and calcium on the regulation of rat intestinal epithelial calcium channels

Transepithelial transport of calcium involves uptake at the apical membrane, movement across the cell, and extrusion at the basolateral membrane. Active vitamin D metabolites regulate the latter two processes by induction of calbindin D and the plasma membrane ATPase (calcium pump), respectively. The expression of calbindin D and the calcium pump declines with age in parallel with transepithelial calcium transport. The apical uptake of calcium is thought to be mediated by the recently cloned calcium channels-CaT1 (or ECaC2, TRPV6) and CaT2 (or ECaC1, TRPV5). The purpose of these studies was to determine whether there were age-related changes in intestinal calcium channel regulation and to identify the dietary factors responsible for their regulation. Young (2 months) and adult (12 months) rats were fed either a high calcium or low calcium diet for 4 weeks. The low calcium diet significantly increased duodenal CaT1 and CaT2 mRNA levels in both age groups, but the levels in the adult were less than half that of the young. The changes in calcium channel expression with age and diet were significantly correlated with duodenal calcium transport and with calbindin D levels. To elucidate the relative roles of serum 1,25(OH)2D3 and calcium in the regulation of calcium channel expression, young rats were fed diets containing varying amounts of calcium and vitamin D. Dietary vitamin D or exogenous 1,25(OH)2D3 more than doubled CaT1 mRNA levels, and this regulation was independent of dietary or serum calcium. These findings suggest that the apical calcium channels, along with calbindin and the calcium pump, may play a role in intestinal calcium transport and its modulation by age, dietary calcium, and 1,25(OH)2D3.     

Fast and slow inactivation kinetics of the Ca2+ channels ECaC1 and ECaC2 (TRPV5 and TRPV6). Role of the intracellular loop located between transmembrane segments 2 and 3

The Ca(2+) channels ECaC1 and ECaC2 (TRPV5 and TRPV6) share several functional properties including permeation profile and Ca(2+)-dependent inactivation. However, the kinetics of ECaC2 currents notably differ from ECaC1 currents. The initial inactivation is much faster in ECaC2 than in ECaC1, and the kinetic differences between Ca(2+) and Ba(2+) currents are more pronounced for ECaC2 than ECaC1. Here, we identify the structural determinants for these functional differences. Chimeric proteins were expressed heterologously in HEK 293 cells and studied by patch clamp analysis. Both channels retained their phenotype after exchanging the complete N termini, the C termini, or even both N and C termini, i.e. ECaC1 with the ECaC2 N or C terminus still showed the ECaC1 phenotype and vice versa. The substitution of the intracellular loop between the transmembrane domains 2 and 3 of ECaC2 with that of ECaC1 induced a delay of inactivation. Three amino acid residues (Leu-409, Val-411 and Thr-412) present in this loop determine the fast inactivation behavior. When this intracellular loop between the transmembrane domains 2 and 3 of ECaC1 was exchanged with the TM2-TM3 loop of ECaC2, the ECaC1 kinetics were analogous to ECaC2. In conclusion, the TM2-TM3 loop is a critical determinant of the inactivation in ECaC1 and ECaC2.     

Molecular determinants of Rem2 regulation of N-type calcium channels

Rem2 belongs to the RGK family of small GTPases whose members are known to interact with the voltage gated calcium channel β subunit, and to inhibit or abolish calcium currents. To identify the underlying functional domains of Rem2, we created several N- or C-terminally truncated Rem2 proteins and examined their abilities to interact with the Ca_v β subunit and to regulate the activities of Ca_v2.2 N-type calcium channels. Confocal imaging of Rem2 in tsA-201 cells revealed that it contains a membrane-targeting signal in its C-terminus, consistent with previous studies. Co-precipitation assays showed that Ca_v β₃ interaction depends on Rem2 residues 1-123. Only Rem2 proteins that targeted the cell membrane as well as bound the β subunit were able to reduce whole cell calcium currents.     

Aldosterone regulation of T-type calcium channels

Voltage-operated calcium channels play a crucial role in signal transduction in many excitable and non-excitable cell types. While a rapid modulation of their activity by hormone-activated kinases and/or G proteins has been recognized for a long time, a sustained control of their expression level has been only recently demonstrated. In adrenal H295R cells, for example, aldosterone treatment selectively increased low threshold T-type calcium current density without affecting L-type currents. Antagonizing the mineralocorticoid receptor (MR) with spironolactone prevented aldosterone action on T-type currents. By RT-PCR, we detected in these cells the presence of two different isoforms of L-type channels, alpha(1)C and alpha(1)D, and one isoform of T channel, alpha(1)H. A second T channel isoform (alpha(1)G) was also observed under particular culture conditions. Quantification of the specific messenger RNA by real time RT-PCR allowed us to show a 40% increase of the alpha1H messenger levels upon aldosterone treatment (alpha(1)G was insensitive), a response that was also completely prevented by spironolactone. Because T-type, but not L-type channel activity is linked to steroidogenesis, this modulation represents a positive, intracrine feed back mechanism exerted by aldosterone on its own production.Aldosterone has been also implicated in the pathogenesis and progression of ventricular hypertrophy and heart failure independently of its action on arterial blood pressure. We have observed that, in rat neonatal cardiomyocytes, aldosterone increases (by two-fold) L-type calcium current amplitude in ventricular but not in atrial cells. No significant effect of aldosterone could be detected on T-type currents, that were much smaller than L-type currents in these cells. However, aldosterone exerted opposite effects on T channel isoform expression, increasing alpha(1)H and decreasing alpha(1)G. Although the functional role of T channels is still poorly defined in ventricular cardiomyocytes, an overexpression of alpha(1)H could be partially responsible for the arrhythmias linked to hyperaldosteronism.Finally, T channels also appear to be involved in the neuroendocrine differentiation of prostate epithelial cells, a poor prognosis in prostate cancer. We have shown that the only calcium channel expressed in the prostatic LNCaP cells is the alpha(1)H isoform and that induction of cell differentiation with cAMP leads to a concomitant increase in both T-type current and alpha(1)H mRNA. In spite of the presence of MR in these cells, aldosterone only modestly increased alpha(1)H mRNA levels. A functional role for these channels was suggested by the observation that low nickel concentrations prevent neuritic process outgrowth.In conclusion, it appears that T-type calcium channel expression vary in different patho-physiological conditions and that aldosterone, in several cell types, is able to modulate this expression.     

RGK regulation of voltage-gated calcium channels

Voltage-gated calcium channels(VGCCs) play critical roles in cardiac and skeletal muscle contractions,hormone and neurotransmitter release,as well as slower processes such as cell proliferation,differentiation,migration and death.Mutations in VGCCs lead to numerous cardiac,muscle and neurological disease,and their physiological function is tightly regulated by kinases,phosphatases,G-proteins,calmodulin and many other proteins.Fifteen years ago,RGK proteins were discovered as the most potent endogenous regulators of VGCCs.They are a family of monomeric GTPases(Rad,Rem,Rem2,and Gem/Kir),in the superfamily of Ras GTPases,and they have two known functions: regulation of cytoskeletal dynamics including dendritic arborization and inhibition of VGCCs.Here we review the mechanisms and molecular determinants of RGK-mediated VGCC inhibition,the physiological impact of this inhibition,and recent evidence linking the two known RGK functions.     

Presynaptic calcium channels: Pharmacology and regulation

Voltage-dependent Ca²⁺ channels are considered as molecular trigger elements for signal transmission at chemical synapses. Due to their central role in this fundamental process, function and pharmacology of presynaptic Ca²⁺ channels have recently been the subject of extensive exploration employing various experimental techniques. Several lines of evidence indicate that, at nerve terminals in higher vertebrates, the evoked influx of Ca²⁺-ions is mainly mediated by Ca²⁺ channels of the P-type. The stringent regulation of presynaptic Ca²⁺ channels is supposed to be involved in fine-tuning the efficiency of synaptic transmission. Intrinsic control mechanisms, such as voltage- or Ca²⁺-dependent inactivation, or modulation of channel activity, either by G-proteins directly or via phosphorylation by protein kinases, may be of particular functional importance.     

Functional organization of TRPC-Ca2+ channels and regulation of calcium microdomains

TRP family of proteins are components of unique cation channels that are activated in response to diverse stimuli ranging from growth factor and neurotransmitter stimulation of plasma membrane receptors to a variety of chemical and sensory signals. This review will focus on members of the TRPC sub-family (TRPC1-TRPC7) which currently appear to be the strongest candidates for the enigmatic Ca(2+) influx channels that are activated in response to stimulation of plasma membrane receptors which result in phosphatidyl inositol-(4,5)-bisphosphate (PIP(2)) hydrolysis, generation of IP(3) and DAG, and IP(3)-induced Ca(2+) release from the intracellular Ca(2+) store via inositol trisphosphate receptor (IP(3)R). Homomeric or selective heteromeric interactions between TRPC monomers generate distinct channels that contribute to store-operated as well as store-independent Ca(2+) entry mechanisms. The former is regulated by the emptying/refilling of internal Ca(2+) store(s) while the latter depends on PIP(2) hydrolysis (due to changes in PIP(2) per se or an increase in diacylglycerol, DAG). Although the exact physiological function of TRPC channels and how they are regulated has not yet been conclusively established, it is clear that a variety of cellular functions are controlled by Ca(2+) entry via these channels. Thus, it is critical to understand how cells coordinate the regulation of diverse TRPC channels to elicit specific physiological functions. It is now well established that segregation of TRPC channels mediated by interactions with signaling and scaffolding proteins, determines their localization and regulation in functionally distinct cellular domains. Furthermore, both protein and lipid components of intracellular and plasma membranes contribute to the organization of these microdomains. Such organization serves as a platform for the generation of spatially and temporally dictated [Ca(2+)](i) signals which are critical for precise control of downstream cellular functions.     

Functional characterisation and genomic analysis of an epithelial calcium channel (ECaC) from pufferfish, Fugu rubripes

An orthologue to the mammalian epithelial calcium channels, ECaC1 (TRPV5) and ECaC2 (TRPV6), was cloned from gill of pufferfish (Fugu rubripes) and characterised, demonstrating that this gene predates the evolution of land-living vertebrates. The F. rubripes ECaC (FrECaC) protein displays all structural features typical for mammalian ECaCs including three ankyrin repeats, six transmembrane domains, and a putative pore region between TM V and TM VI. Functional expression of FrECaC in Madin-Darby canine kidney (MDCK) cells confirmed that the channel mediates Ca(2+) influx. FrECaC was also permeable to Zn(2+) and, to a small extent, to the Fe(2+) ion. Thus, in addition to a role in Ca(2+) uptake FrECaC might serve as a pathway for zinc and iron acquisition. FrECaC mRNA was highly abundant in the gill, but sparsely present in the intestine. Calcium absorption via FrECaC in pufferfish may be subject to the regulation of 1.25(OH)(2)D(3), estrogen and progesterone as consensus cis regulatory elements for the respective steroid hormone receptors were found in the upstream regulatory region of the FrECaC gene. FrECaC gene organisation is very conserved when compared with mammalian ECaCs. Only one ECaC gene seems to exist in the F. rubripes genome, and the corresponding protein clusters together with ECaC2 from mammals upon phylogenetic analysis. Thus, the two mammalian ECaC genes may originate from a single ancestral ECaC2 gene in vertebrates appearing early in evolution.     

Trafficking and regulation of neuronal voltage-gated calcium channels

The importance of voltage-gated calcium channels is underscored by the multitude of intracellular processes that depend on calcium, notably gene regulation and neurotransmission. Given their pivotal roles in calcium (and hence, cellular) homeostasis, voltage-gated calcium channels have been the subject of intense research, much of which has focused on channel regulation. While ongoing research continues to delineate the myriad of interactions that govern calcium channel regulation, an increasing amount of work has focused on the trafficking of voltage-gated calcium channels. This includes the mechanisms by which calcium channels are targeted to the plasma membrane, and, more specifically, to their appropriate loci within a given cell. In addition, we are beginning to gain some insights into the mechanisms by which calcium channels can be removed from the plasma membrane for recycling and/or degradation. Here we highlight recent advances in our understanding of these fundamentally important mechanisms.     

Receptor-mediated regulation of calcium channels and neurotransmitter release

Ca2+ influx into the nerve terminal is normally the trigger for the release of neurotransmitters. Many neurons possess presynaptic receptors whose activation results in changes in the quantity of neurotransmitter released by an action potential. This paper reviews studies that show that presynaptic receptors can regulate the activity of Ca2+ channels in the nerve terminal, resulting in changes in the influx of Ca2+ and in neurotransmitter release. Neurons possess several different types of voltage-sensitive Ca2+ channels. Ca2+ influx through N-type channels appears to trigger transmitter release in many instances. In other cases Ca2+ influx through L channels can influence transmitter release. Neurotransmitters can inhibit N channels through a G protein-mediated transduction mechanism. The G proteins are frequently pertussis toxin substrates. Inhibition of N channels appears to involve changes in their voltage dependence. Neurotransmitters can also regulate neuronal K+ channels. Activation of these K+ channels can lead to a reduction in Ca2+ influx and neurotransmitter release; these effects are also mediated by G proteins. Thus neurotransmitters may often regulate both presynaptic Ca2+ and K+ channels. These two effects may be synergistic mechanisms for the regulation of Ca2+ influx and neurotransmitter release.     

The epithelial calcium channels,TRPV5 & TRPV6: from identification towards regulation

The epithelial calcium channels, TRPV5 and TRPV6, have been extensively studied in epithelial tissues controlling the Ca(2+) homeostasis and exhibit a range of distinctive properties that distinguish them from other TRP channels. This review focuses on the tissue distribution, the functional properties, the architecture and the regulation of the expression and activity of the TRPV5 and TRPV6 channel.