Cation Permeability and Selectivity of a Root Plasma Membrane Calcium Channel

Calcium channels in the plasma membrane of root cells fulfill both nutritional and signaling roles. The permeability of these channels to different cations determines the magnitude of their cation conductances, their effects on cell membrane potential and their contribution to cation toxicities. The selectivity of the rca channel, a Ca²⁺-permeable channel from the plasma membrane of wheat (Triticum aestivum L.) roots, was studied following its incorporation into planar lipid bilayers. The permeation of K⁺, Na⁺, Ca²⁺ and Mg²⁺ through the pore of the rca channel was modeled. It was assumed that cations permeated in single file through a pore with three energy barriers and two ion-binding sites. Differences in permeation between divalent and monovalent cations were attributed largely to the affinity of the ion binding sites. The model suggested that significant negative surface charge was present in the vestibules to the pore and that the pore could accommodate two cations simultaneously, which repelled each other strongly. The pore structure of the rca channel appeared to differ from that of L-type calcium channels from animal cell membranes since its ion binding sites had a lower affinity for divalent cations. The model adequately accounted for the diverse permeation phenomena observed for the rca channel. It described the apparent submillimolar K _m for the relationship between unitary conductance and Ca²⁺ activity, the differences in selectivity sequences obtained from measurements of conductance and permeability ratios, the changes in relative cation permeabilities with solution ionic composition, and the complex effects of Ca²⁺ on K⁺ and Na⁺ currents through the channel. Having established the adequacy of the model, it was used to predict the unitary currents that would be observed under the ionic conditions employed in patch-clamp experiments and to demonstrate the high selectivity of the rca channel for Ca²⁺ influx under physiological conditions. Received: 23 August 1999/Revised: 12 November 1999     

An Energy-Barrier Model for the Permeation of Monovalent and Divalent Cations Through the Maxi Cation Channel in the Plasma Membrane of Rye Roots

The depolarization-activated, high-conductance ``maxi' cation channel in the plasma membrane of rye (Secale cereale L.) roots is permeable to a wide variety of monovalent and divalent cations. The permeation of K⁺, Na⁺, Ca²⁺ and Ba²⁺ through the pore could be simulated using a model composed of three energy barriers and two ion binding sites (a 3B2S model), which assumed single-file permeation and the possibility of double cation occupancy. The model had an asymmetrical free energy profile. Differences in permeation between cations were attributed primarily to differences in their free energy profiles in the regions of the pore adjacent to the extracellular solution. In particular, the height of the central free energy peak differed between cations, and cations differed in their affinities for ion binding sites. Significant ion repulsion occurred within the pore, and the mouths of the pore had considerable surface charge. The model adequately described the diverse current vs. voltage (I/V) relationships obtained over a wide variety of experimental conditions. It described the phenomena of non-Michaelian unitary conductance vs. activity relationships for K⁺, Na⁺ and Ca²⁺, differences in selectivity sequences obtained from measurements of conductance and permeability ratios, changes in relative cation permeabilities with solution composition, and the complex effects of Ba²⁺ and Ca²⁺ on K⁺ currents through the channel. The model enabled the prediction of unitary currents and ion fluxes through the maxi cation channel under physiological conditions. It could be used, in combination with data on the kinetics of the channel, as input to electrocoupling models allowing the relationships between membrane voltage, Ca²⁺ influx and Ca²⁺ signaling to be studied theoretically. Received: 29 April 1998/Revised: 20 November 1998     

Activation and Inhibition of TMEM16A Calcium-Activated Chloride Channels

Calcium-activated chloride channels (CaCC) encoded by family members of transmembrane proteins of unknown function 16 (TMEM16) have recently been intensely studied for functional properties as well as their physiological roles as chloride channels in various tissues. One technical hurdle in studying these channels is the well-known channel rundown that frequently impairs the precision of electrophysiological measurements for the channels. Using experimental protocols that employ fast-solution exchange, we circumvented the problem of channel rundown by normalizing the Ca²⁺-induced current to the maximally-activated current obtained within a time period in which the channel rundown was negligible. We characterized the activation of the TMEM16A-encoded CaCC (also called ANO1) by Ca²⁺, Sr²⁺, and Ba²⁺, and discovered that Mg²⁺ competes with Ca²⁺ in binding to the divalent-cation binding site without activating the channel. We also studied the permeability of the ANO1 pore for various anions and found that the anion occupancy in the pore–as revealed by the permeability ratios of these anions–appeared to be inversely correlated with the apparent affinity of the ANO1 inhibition by niflumic acid (NFA). On the other hand, the NFA inhibition was neither affected by the degree of the channel activation nor influenced by the types of divalent cations used for the channel activation. These results suggest that the NFA inhibition of ANO1 is likely mediated by altering the pore function but not through changing the channel gating. Our study provides a precise characterization of ANO1 and documents factors that can affect divalent cation activation and NFA inhibition of ANO1.     

Intracellular calcium release channels mediate their own countercurrent: the ryanodine receptor case study

Intracellular calcium release channels like ryanodine receptors (RyRs) and inositol trisphosphate receptors (IP₃Rs) mediate large Ca²⁺ release events from Ca²⁺ storage organelles lasting >5 ms. To have such long-lasting Ca²⁺ efflux, a countercurrent of other ions is necessary to prevent the membrane potential from becoming the Ca²⁺ Nernst potential in <1 ms. A recent model of ion permeation through a single, open RyR channel is used here to show that the vast majority of this countercurrent is conducted by the RyR itself. Consequently, changes in membrane potential are minimized locally and instantly, assuring maintenance of a Ca²⁺-driving force. This RyR autocountercurrent is possible because of the poor Ca²⁺ selectivity and high conductance for both monovalent and divalent cations of these channels. The model shows that, under physiological conditions, the autocountercurrent clamps the membrane potential near 0 mV within ∼150 μs. Consistent with experiments, the model shows how RyR unit Ca²⁺ current is defined by luminal [Ca²⁺], permeable ion composition and concentration, and pore selectivity and conductance. This very likely is true of the highly homologous pore of the IP₃R channel.     

Nonselective cation channel activated by patch excision from lobster olfactory receptor neurons

Summary A nonselective cation channel activated by patch excision was characterized in inside-out patches from spiny lobster olfactory receptor neurons. The channel, which was permeable to Na⁺, K⁺ and Cs⁺, had a conductance of 320 pS and was weakly voltage dependent in the presence of micromolar divalent cations. Millimolar internal divalent cations caused a voltage-and concentration-dependent block of Na⁺ permeation. Analysis of the voltage dependence indicated that the proportion of the membrane's electric field sensed by Mg²⁺ was >1, suggesting that the channel contains a multi-ion pore. Internal divalent cations also reduced the frequency of channel opening in a concentration-dependent, but not voltage-dependent, manner, indicating that different cation binding sites affect gating and conductance. While block of gating prevented determining if internal divalent cations permeate the channel, a channel highly permeable to external divalent cations was observed upon patch excision to the inside-out configuration. The monovalent and divalent cation conductances shared activation by patch excision, weak voltage dependence, and steady-state activity, suggesting that they are the same channel. These data extend our understanding of this type of channel by demonstrating permeation by monovalent cations, detailing Mg²⁺ block of Na^– permeation, and demonstrating the channel's presence in arthropods.     

A novel homology model of TRPC3 reveals allosteric coupling between gate and selectivity filter

Utilizing a novel molecular model of TRPC3, based on the voltage-gated sodium channel from Arcobacter butzleri (Na_VAB) as template, we performed structure-guided mutagenesis experiments to identify amino acid residues involved in divalent permeation and gating. Substituted cysteine accessibility screening within the predicted selectivity filter uncovered amino acids 629–631 as the narrowest part of the permeation pathway with an estimated pore diameter of <5.8 Å. E630 was found to govern not only divalent permeability but also sensitivity of the channel to block by ruthenium red. Mutations in a hydrophobic cluster at the cytosolic termini of transmembrane segment 6, corresponding to the S6 bundle crossing structure in Na_VAB, distorted channel gating. Removal of a large hydrophobic residue (I667A or I667E) generated channels with approximately 60% constitutive activity, suggesting I667 as part of the dynamic structure occluding the permeation path. Destabilization of the gate was associated with reduced Ca²⁺ permeability, altered cysteine cross-linking in the selectivity filter and promoted channel block by ruthenium red. Collectively, we present a structural model of the TRPC3 permeation pathway and localize the channel's selectivity filter and the occluding gate. Moreover, we provide evidence for allosteric coupling between the gate and the selectivity filter in TRPC3.     

Selectivity signatures of three isoforms of recombinant T-type Ca channels

Voltage-gated Ca²⁺ channels (VGCCs) are recognized for their superb ability for the preferred passage of Ca²⁺ over any other more abundant cation present in the physiological saline. Most of our knowledge about the mechanisms of selective Ca²⁺ permeation through VGCCs was derived from the studies on native and recombinant L-type representatives. However, the specifics of the selectivity and permeation of known recombinant T-type Ca²⁺-channel α1 subunits, Ca_v3.1, Ca_v3.2 and Ca_v3.3, are still poorly defined. In the present study we provide comparative analysis of the selectivity and permeation Ca_v3.1, Ca_v3.2, and Ca_v3.3 functionally expressed in Xenopus oocytes. Our data show that all Ca_v3 channels select Ca²⁺ over Na⁺ by affinity. Ca_v3.1 and Ca_v3.2 discriminate Ca²⁺, Sr²⁺ and Ba²⁺ based on the ion's effects on the open channel probability, whilst Ca_v3.3 discriminates based on the ion's intrapore binding affinity. All Ca_v3s were characterized by much smaller difference in the K_D values for Na⁺ current blockade by Ca²⁺ (K_D1 ∼ 6 μM) and for Ca²⁺ current saturation (K_D2 ∼ 2 mM) as compared to L-type channels. This enabled them to carry notable mixed Na⁺/Ca²⁺ current at close to physiological Ca²⁺ concentrations, which was the strongest for Ca_v3.3, smaller for Ca_v3.2 and the smallest for Ca_v3.1. In addition to intrapore Ca²⁺ binding site(s) Ca_v3.2, but not Ca_v3.1 and Ca_v3.3, is likely to possess an extracellular Ca²⁺ binding site that controls channel permeation. Our results provide novel functional tests for identifying subunits responsible for T-type Ca²⁺ current in native cells.     

Permeation and inhibition of polycystin-l channel by monovalent organic cations

Polycystin-L (PCL), homologous to polycystin-2 (71% similarity in protein sequence), is the third member of the polycystin family of proteins. Polycystin-1 and -2 are mutated in autosomal dominant polycystic kidney disease, but the physiological role of PCL has not been determined. PCL acts as a Ca-regulated non-selective cation channel permeable to mono- and divalent cations. To further understand the biophysical and pharmacological properties of PCL, we examined a series of organic cations for permeation and inhibition, using single-channel patch clamp and whole-cell two-microelectrode voltage clamp techniques in conjunction with Xenopus oocyte expression. We found that PCL is permeable to organic amines, methlyamine (MA, 3.8 Å), dimethylamine (DMA, 4.6 Å) and triethylamine (TriEA, 6 Å), and to tetra-alkylammonium cation (TAA) tetra-methylammonium (TMA, 5.5-6.4 Å). TAA compounds tetra-ethylammonium (TEA, 6.1-8.2 Å) and tetra-propylammonium (TPA, 9.8 Å) were impermeable through PCL and exhibited weak inhibition on PCL (IC₅₀ values>13 mM). Larger TAA cations tetra-butylammonium (TBA, 11.6 Å) and tetra-pentylammonium (TPeA, 13.2 Å) were impermeable through PCL as well and showed strong inhibition (IC₅₀ values of 2.7 mM and 1.3 μM, respectively). Inhibition by TBA was on decreasing the single-channel current amplitude and exhibited no effect on open probability (NP_o) or mean open time (MOT), suggesting that it blocks the PCL permeation pathway. In contract, TEA, TPA and TPeA reduced NP_o and MOT values but had no effect on the amplitude, suggesting their binding to a different site in PCL, which affects the channel gating. Taken together, our studies revealed that PCL is permeable to organic amines and TAA cation TMA, and that inhibition of PCL by large TAA cations exhibits two different mechanisms, presumably through binding either to the pore pathway to reduce permeant flux or to another site to regulate the channel gating. These data allow to estimate a channel pore size of ∼7 Å for PCL.     

Characterization of a Membrane Calcium Pathway Induced by Rotavirus Infection in Cultured Cells

Some viruses induce changes in membrane permeability during infection. We have shown previously that the porcine strain of rotavirus, OSU, induced an increase in the permeability to Na⁺, K⁺, and Ca²⁺ during replication in MA104 cells. In this work, we have characterized the divalent cation entry pathway by measuring intracellular Ca²⁺ in fura-2-loaded MA104 and HT29 cells in suspension. The permeability to Ca²⁺ and other cations was evaluated by the change of the intracellular concentration following an extracellular cation pulse. Rotavirus infection induced an increase in permeability to Ca²⁺, Ba²⁺, Sr²⁺, Mn²⁺, and Co²⁺. The rate of cation entry decreased over time as the intracellular concentration increased during the first 20 s. This indicates that regulatory mechanisms, including channel inactivation, are triggered. La³⁺ did not enter the cell and blocked the entry of the divalent cations in a dose-dependent manner. Metoxyverapamil (D600), a blocker of L-type voltage-gated channels, partially inhibited the entry of Ca²⁺ in virus-infected MA104 and HT29 cells. The results suggest that rotavirus infection of cultured cells activates a cation channel rather than nonspecific permeation through the plasma membrane. This activation involves the synthesis of viral proteins through mechanisms yet unknown. The increase in intracellular Ca²⁺ induced by the activation of this channel may be related to the increase in cytoplasmic and endoplasmic reticulum Ca²⁺ pools required for virus maturation and cell death.     

The single pore residue Asp in PKD2L1 determines Ca permeation of the PKD1L3/PKD2L1 complex

The polycystic kidney disease 1-like 3 (PKD1L3)–polycystic kidney disease 2-like 1 (PKD2L1) complex functions as a Ca²⁺-permeable, non-selective cation channel that is activated by acid and its subsequent removal; this is called an off-response. In this study, we identified a single aspartic residue in PKD2L1 that is responsible for the Ca²⁺ permeation of the PKD1L3/PKD2L1 complex. Calcium imaging analysis using point mutants of negatively charged amino acids present in the putative pore regions of PKD1L3 and PKD2L1 revealed that neutralization of the aspartic residue in PKD2L1 (D523N), which is conserved among PKD2 family members, abolished Ca²⁺ permeation, despite robust cell surface expression. In contrast, neutralization of the other negatively charged residues of PKD1L3 (D2049N and E2072Q) and PKD2L1 (D525N and D530N) as well as substitution of Asp⁵²³ with a glutamate residue (D523E) had little effect on Ca²⁺ permeation properties. These results demonstrate that Asp⁵²³ in PKD2L1 is a key determinant of Ca²⁺ permeation into the PKD1L3/PKD2L1 complex and that PKD2L1 contributes to forming the pore of the PKD1L3/PKD2L1 channel.     

Block of N-type Calcium Channels in Chick Sensory Neurons by External Sodium

L-type Ca²⁺ channels select for Ca²⁺ over sodium Na⁺ by an affinity-based mechanism. The prevailing model of Ca²⁺ channel permeation describes a multi-ion pore that requires pore occupancy by at least two Ca²⁺ ions to generate a Ca²⁺ current. At [Ca²⁺] < 1 μM, Ca²⁺ channels conduct Na⁺. Due to the high affinity of the intrapore binding sites for Ca²⁺ relative to Na⁺, addition of μM concentrations of Ca²⁺ block Na⁺ conductance through the channel. There is little information, however, about the potential for interaction between Na⁺ and Ca²⁺ for the second binding site in a Ca²⁺ channel already occupied by one Ca²⁺. The two simplest possibilities, (a) that Na⁺ and Ca²⁺ compete for the second binding site or (b) that full time occupancy by one Ca²⁺ excludes Na⁺ from the pore altogether, would imply considerably different mechanisms of channel permeation. We are studying permeation mechanisms in N-type Ca²⁺ channels. Similar to L-type Ca²⁺ channels, N-type channels conduct Na⁺ well in the absence of external Ca²⁺. Addition of 10 μM Ca²⁺ inhibited Na⁺ conductance by 95%, and addition of 1 mM Mg²⁺ inhibited Na⁺ conductance by 80%. At divalent ion concentrations of 2 mM, 120 mM Na⁺ blocked both Ca²⁺ and Ba²⁺ currents. With 2 mM Ba²⁺, the IC₅₀ for block of Ba²⁺ currents by Na⁺ was 119 mM. External Li⁺ also blocked Ba²⁺ currents in a concentration-dependent manner, with an IC₅₀ of 97 mM. Na⁺ block of Ba²⁺ currents was dependent on [Ba²⁺]; increasing [Ba²⁺] progressively reduced block with an IC₅₀ of 2 mM. External Na⁺ had no effect on voltage-dependent activation or inactivation of the channel. These data suggest that at physiological concentrations, Na⁺ and Ca²⁺ compete for occupancy in a pore already occupied by a single Ca²⁺. Occupancy of the pore by Na⁺ reduced Ca²⁺ channel conductance, such that in physiological solutions, Ca²⁺ channel currents are between 50 and 70% of maximal.     

Single channel measurements demonstrate the voltage dependence of permeation through N-type and L-type CaV channels

The delivery of Ca²⁺ into cells by Ca_V channels provides the trigger for many cellular actions, such as cardiac muscle contraction and neurotransmitter release. Thus, a full understanding of Ca²⁺ permeation through these channels is critical. Using whole-cell voltage-clamp recordings, we recently demonstrated that voltage modulates the apparent affinity of N-type (Ca_V2.2) channels for permeating Ca²⁺ and Ba²⁺ ions. While we took many steps to ensure the high fidelity of our recordings, problems can occur when Ca_V currents become large and fast, or when currents run down. Thus, we use here single channel recordings to further test the hypothesis that permeating ions interact with N-type channels in a voltage-dependent manner. We also examined L-type (Ca_V1.2) channels to determine if these channels also exhibit voltage-dependent permeation. Like our whole-cell data, we find that voltage modulates N-channel affinity for Ba²⁺ at voltages > 0 mV, but has little or no effect at voltages < 0 mV. Furthermore, we demonstrate that permeation through L-channel is also modulated by voltage. Thus, voltage-dependence may be a common feature of divalent cation permeation through Ca_V1 and Ca_V2 channels (i.e. high-voltage activated Ca_V channels). The voltage dependence of Ca_V1 channel permeation is likely a mechanism mediating sustained Ca²⁺ influx during the plateau phase of the cardiac action potential.     

Single channel measurements demonstrate the voltage dependence of permeation through N-type and L-type CaV channels

The delivery of Ca²⁺ into cells by Ca_V channels provides the trigger for many cellular actions, such as cardiac muscle contraction and neurotransmitter release. Thus, a full understanding of Ca²⁺ permeation through these channels is critical. Using whole-cell voltage-clamp recordings, we recently demonstrated that voltage modulates the apparent affinity of N-type (Ca_V2.2) channels for permeating Ca²⁺ and Ba²⁺ ions. While we took many steps to ensure the high fidelity of our recordings, problems can occur when Ca_V currents become large and fast, or when currents run down. Thus, we use here single channel recordings to further test the hypothesis that permeating ions interact with N-type channels in a voltage-dependent manner. We also examined L-type (Ca_V1.2) channels to determine if these channels also exhibit voltage-dependent permeation. Like our whole-cell data, we find that voltage modulates N-channel affinity for Ba²⁺ at voltages > 0 mV, but has little or no effect at voltages < 0 mV. Furthermore, we demonstrate that permeation through L-channel is also modulated by voltage. Thus, voltage-dependence may be a common feature of divalent cation permeation through Ca_V1 and Ca_V2 channels (i.e. high-voltage activated Ca_V channels). The voltage dependence of Ca_V1 channel permeation is likely a mechanism mediating sustained Ca²⁺ influx during the plateau phase of the cardiac action potential.     

A Single Amino Acid Change in CaV1.2 Channels Eliminates the Permeation and Gating Differences Between Ca2+ and Ba2+

Glutamate scanning mutagenesis was used to assess the role of the calcicludine binding segment in regulating channel permeation and gating using both Ca²⁺ and Ba²⁺ as charge carriers. As expected, wild-type Ca_V1.2 channels had a Ba²⁺ conductance ~2× that in Ca²⁺ (G_Ba/G_Ca = 2) and activation was ~10 mV more positive in Ca²⁺ vs. Ba²⁺. Of the 11 mutants tested, F1126E was the only one that showed unique permeation and gating properties compared to the wild type. F1126E equalized the Ca_V1.2 channel conductance (G_Ba/G_Ca = 1) and activation voltage dependence between Ca²⁺ and Ba²⁺. Ba²⁺ permeation was reduced because the interactions among multiple Ba²⁺ ions and the pore were specifically altered for F1126E, which resulted in Ca²⁺-like ionic conductance and unitary current. However, the high-affinity block of monovalent cation flux was not altered for either Ca²⁺ or Ba²⁺. The half-activation voltage of F1126E in Ba²⁺ was depolarized to match that in Ca²⁺, which was unchanged from that in the wild type. As a result, the voltages for half-activation and half-inactivation of F1126E in Ba²⁺ and Ca²⁺ were similar to those of wild-type in Ca²⁺. This effect was specific to F1126E since F1126A did not affect the half-activation voltage in either Ca²⁺ or Ba²⁺. These results indicate that residues in the outer vestibule of the Ca_V1.2 channel pore are major determinants of channel gating, selectivity, and permeation.     

Asp residues of the Glu-Glu-Asp-Asp pore filter contribute to ion permeation and selectivity of the Cav3.2 T-type channel

Voltage-activated Ca²⁺ channels are membrane protein machinery performing selective permeation of external calcium ions. The main Ca²⁺ selective filters of all high-voltage-activated Ca²⁺ channel isoforms are commonly composed of four Glu residues (EEEE), while those of low-voltage-activated T-type Ca²⁺ channel isoforms are made up of two Glu and two Asp residues (EEDD). We here investigate how the Asp residues at the pore loops of domains III and IV affect biophysical properties of the Ca_v3.2 channel. Electrophysiological characterization of the pore mutant channels in which the pore Asp residue(s) were replaced with Glu, showed that both Asp residues critically control the biophysical properties of Ca_v3.2, including relative permeability between Ba²⁺ and Ca²⁺, anomalous mole fraction effect (AMFE), voltage dependency of channel activation, Cd²⁺ blocking sensitivity, and pH effects, in distinctive ways.     

TRPA1 is functionally co-expressed with TRPV1 in cardiac muscle: Co-localization at z-discs,costameres and intercalated discs

Transient receptor potential channels of the ankyrin subtype-1 (TRPA1) and vanilloid subtype-1 (TRPV1) are structurally related, non-selective cation channels that show a high permeability to calcium. Previous studies indicate that TRP channels play a prominent role in the regulation of cardiovascular dynamics and homeostasis, but also contribute to the pathophysiology of many diseases and disorders within the cardiovascular system. However, no studies to date have identified the functional expression and/or intracellular localization of TRPA1 in primary adult mouse ventricular cardiomyocytes (CMs). Although TRPV1 has been implicated in the regulation of cardiac function, there is a paucity of information regarding functional expression and localization of TRPV1 in adult CMs. Our current studies demonstrate that TRPA1 and TRPV1 ion channels are co-expressed at the protein level in CMs and both channels are expressed throughout the endocardium, myocardium and epicardium. Moreover, immunocytochemical localization demonstrates that both channels predominantly colocalize at the Z-discs, costameres and intercalated discs. Furthermore, specific TRPA1 and TRPV1 agonists elicit dose-dependent, transient rises in intracellular free calcium concentration ([Ca²⁺]_i) that are abolished in CMs obtained from TRPA1^?/? and TRPV1^?/? mice. Similarly, we observed a dose-dependent attenuation of the TRPA1 and TRPV1 agonist-induced increase in [Ca²⁺]_i when WT CMs were pretreated with increasing concentrations of selective TRPA1 or TRPV1 channel antagonists. In summary, these findings demonstrate functional expression and the precise ultrastructural localization of TRPA1 and TRPV1 ion channels in freshly isolated mouse CMs. Crosstalk between TRPA1 and TRPV1 may be important in mediating cellular signaling events in cardiac muscle.     

Orai1 mutations alter ion permeation and Ca2+-dependent fast inactivation of CRAC channels: evidence for coupling of permeation and gating

Ca²⁺ entry through store-operated Ca²⁺ release-activated Ca²⁺ (CRAC) channels is an essential trigger for lymphocyte activation and proliferation. The recent identification of Orai1 as a key CRAC channel pore subunit paves the way for understanding the molecular basis of Ca²⁺ selectivity, ion permeation, and regulation of CRAC channels. Previous Orai1 mutagenesis studies have indicated that a set of conserved acidic amino acids in trans membrane domains I and III and in the I–II loop (E106, E190, D110, D112, D114) are essential for the CRAC channel's high Ca²⁺ selectivity. To further dissect the contribution of Orai1 domains important for ion permeation and channel gating, we examined the role of these conserved acidic residues on pore geometry, properties of Ca²⁺ block, and channel regulation by Ca²⁺. We find that alteration of the acidic residues lowers Ca²⁺ selectivity and results in striking increases in Cs⁺ permeation. This is likely the result of enlargement of the unusually narrow pore of the CRAC channel, thus relieving steric hindrance for Cs⁺ permeation. Ca²⁺ binding to the selectivity filter appears to be primarily affected by changes in the apparent on-rate, consistent with a rate-limiting barrier for Ca²⁺ binding. Unexpectedly, the mutations diminish Ca²⁺-mediated fast inactivation, a key mode of CRAC channel regulation. The decrease in fast inactivation in the mutant channels correlates with the decrease in Ca²⁺ selectivity, increase in Cs⁺ permeability, and enlargement of the pore. We propose that the structural elements involved in ion permeation overlap with those involved in the gating of CRAC channels.     

In yeast, Ca and octylguanidine interact with porin (VDAC) preventing the mitochondrial permeability transition

In yeast, Ca²⁺ and long chain alkylguanidines interact with mitochondria modulating the opening of the yeast mitochondrial unspecific channel. Mammalians possess a similar structure, the mitochondrial permeability transition pore. The composition of these pores is under debate. Among other components, the voltage-dependent anion channel has been proposed as a component of either pore. In yeast from an industrial strain, octylguanidine and calcium closed the yeast mitochondrial unspecific channel. Here, the effects of the cations Ca²⁺ or octylguanidine and the voltage-dependent anion channel effector decavanadate were evaluated in yeast mitochondria from either a wild type or a voltage-dependent anion channel deletion laboratory strain. It was observed that in the absence of voltage-dependent anion channel, the yeast mitochondrial unspecific channel was desensitized to Ca²⁺, octylguanidine or decavanadate but remained sensitive to phosphate. It is thus suggested that in yeast mitochondria, the voltage-dependent anion channel has a cation binding site where Ca²⁺ and octylguanidine interact, conferring cation sensitivity to the yeast mitochondrial unspecific channel.     

Salak Plum Peel Extract as a Safe and Efficient Antioxidant Appraisal for Cosmetics

We searched in this study for novel agonists of transient receptor potential cation channel, subfamily V, member 1 (TRPV1) and transient receptor potential cation channel, subfamily A, member 1 (TRPA1) in pepper, focusing attention on 19 compounds contained in black pepper. Almost all the compounds in HEK cells heterogeneously expressed TRPV1 or TRPA1, increased the intracellular Ca²⁺ concentration ([Ca²⁺]_i) in a concentration-dependent manner. Among these, piperine, isopiperine, isochavicine, piperanine, pipernonaline, dehydropipernonaline, retrofractamide C, piperolein A, and piperolein B relatively strongly activated TRPV1. The EC₅₀ values of these compounds for TRPV1 were 0.6–128 μM. Piperine, isopiperine, isochavicine, piperanine, piperolein A, piperolein B, and N-isobutyl-(2E,4E)-tetradeca-2,4-diamide also relatively strongly activated TRPA1, the EC₅₀ values of these compounds for TRPA1 were 7.8–148 μM. The Ca²⁺ responses of these compounds for TRPV1 and TRPA1 were significantly suppressed by co-applying each antagonist. We identified in this study new transient receptor potential (TRP) agonists present in black pepper and found that piperine, isopiperine, isochavicine, piperanine, piperolein A, and piperolein B activated both TRPV1 and TRPA1.     

Divalent cation gating of an ammonium permeable channel in the symbiotic membrane from soybean nodules

The symbiotic membrane between N₂-fixing bacteroids and plant cytoplasm in nodules of soybean contains a sub-picoSiemen cation channel permeable to NH₄⁺. With millimolar concentrations of Ca²⁺ or Mg²⁺ on the cytoplasmic side, the channel rectifies current in the direction of cation influx to the cytoplasm. When Ca²⁺ is present on the bacteroid side of the membrane the current is rectified in the opposite direction. With submicromollar concentrations of divalent on both sides, the channel no longer rectifies. The channel is inhibited by verapamil on the bacteroid side of the membrane with a K_d of 2.6 μM. In the presence of millimolar concentrations of divalents on the cytoplasmic side, the conductance as a function of voltage is fitted by a simple Boltzmann equation with an effective gating charge equal to one. The voltage at which the conductance reaches 50% of maximum is dependent on external NH₄⁺, shifting negative at lower concentrations. The time-course of activation upon hyperpolarisation can be described by the Hodgkin-Huxley equation with Ca²⁺present on the cytoplasmic side. With Mg²⁺ the channel activates with single exponential kinetics. The time constant for activation is weakly voltage dependent. Upon depolarisation of the membrane the channel deactivates with double exponential kinetics, the time constants being slightly voltage dependent. We propose a model of the channel in which divalent block is relieved when the blocking ion is dislodged by univalent cation flux into the pore. Mg²⁺ on the cytoplasmic side may function in vivo as the gating particle of the channel.