Permeable Cation Research Articles

Prolactin stimulates transepithelial calcium transport and modulates paracellular permselectivity in Caco-2 monolayer: mediation by PKC and ROCK pathways

Prolactin (PRL) was previously demonstrated to rapidly enhance calcium absorption in rat duodenum and the intestine-like Caco-2 monolayer. However, its mechanism was not completely understood. Here, we investigated nongenomic effects of PRL on the transepithelial calcium transport and paracellular permselectivity in the Caco-2 monolayer by Ussing chamber technique. PRL increased the transcellular and paracellular calcium fluxes and paracellular calcium permeability within 60 min after exposure but decreased the transepithelial resistance of the monolayer. The effects of PRL could not be inhibited by RNA polymerase II inhibitor (5,6-dichloro-1-beta-D-ribobenzimidazole), confirming that PRL actions were nongenomic. Exposure to protein kinase C (PKC) or RhoA-associated coiled-coil forming kinase (ROCK) inhibitors (GF-109203X and Y-27632, respectively) abolished the stimulatory effect of PRL on transcellular calcium transport, whereas ROCK inhibitor, but not PKC inhibitor, diminished the PRL effect on paracellular calcium transport. Knockdown of the long isoform of PRL receptor (PRLR-L) also prevented the enhancement of calcium transport by PRL. In addition, PRL markedly increased paracellular sodium permeability and the permeability ratio of sodium to chloride, which are indicators of the paracellular charge-selective property and are known to be associated with the enhanced paracellular calcium transport. The permeability of other cations in the alkali metal series was also increased by PRL, and such increases were abolished by ROCK inhibitor. It could be concluded that PRL stimulated transepithelial calcium transport through PRLR-L and increased paracellular permeability to cations in the Caco-2 monolayer. These nongenomic actions of PRL were mediated by the PKC and ROCK signaling pathways.

Cysteine mutagenesis to study the structure of claudin‐2 paracellular pores

Claudins are tight junction proteins that control passive paracellular transport of small ions across epithelia. Claudin‐2 is expressed in proximal renal tubules which partly re‐absorb Na(+) via the paracellular pathway and it forms cation‐selective paracellular pores in high resistance cell lines. To test the hypothesis that amino acid residues in the 1st extracellular loop line the paracellular pore, we used cysteine mutagenesis of Y35, H57, D65 and I66 in claudin‐2 and expressed these mutants in stable transfected MDCK I cells. H57C and D65C showed a partial loss of cation permeability (50% of P(Na+) of wild‐type claudin‐2), suggesting that these residues may participate in cation permeation. D65C also exhibited marked loss of charge and size selectivity and appeared as a dimer on non‐reducing polyacrylamide gels, indicating that conformational changes resulting from intermolecular disulfide bonding disrupted the pore structure. Permeability and selectivity of Y35C and I66C were preserved. Addition of cationic methanethiosulfonate reagents to I66C caused a prompt decrease in conductance of up to 35%, suggesting that this residue may line the pore lumen and be accessible to extracellular cations. By applying methods used to investigate transcellular ion channels, we are beginning to map the position of key residues within the paracellular pore and develop MTS reagents as potential pore blocking tools.

Role of TRPV4 channels in agonist‐induced endothelial Ca2+ entry and vasodilation: Evidence from TRPV4‐deficient mice

Transient receptor potential vallinoid 4 (TRPV‐4), is a Ca2+‐permeant cation channel implicated in endothelial‐dependent vasorelaxation to mechanical stimuli but limited information exists for agonist‐induced responses. We hypothesized that TRPV‐4 is required for agonist‐induced vasodilation by regulating Ca2+ entry. Isometric tension was measured in isolated mesenteric arteries (MA) from wild type (WT) and TRPV‐4 knockout mice using a wire myograph. Dilation to acetylcholine (Ach, 10−9–10−5 M) was diminished in TRPV‐4−/− vs. WT MA (% max relaxation, 44±12 and 86±5, respectively n=4, P<0.05). L‐NAME, blocked Ach relaxation in TRPV‐4−/− and WT MA (11±4 and 35±11, respectively n=4, P<0.05). Responses to papaverine were similar in WT and TRPV‐4−/− MA. Intracellular calcium ([Ca2+]i) was assessed after intraluminal fura‐2 (fluorescence) in MA. Ach (10−5 M) increased endothelial [Ca2+]i in WT and TRPV‐4−/− MA (Δ[Ca2+]i, 49±4.6nM and 26±2.1nM, respectively n=4). The addition of 4α‐PDD, a TRPV4 opener, increased [Ca2+]i in WT but not in TRPV‐4−/− (Δ[Ca2+]i, 164±30nM and 15±1.3nM, respectively n=4). In endothelium of WT MA the increase in [Ca2+] was abolished by the TRPV‐4 blocker ruthenium red (Δ[Ca2+]i, RR, 19±1.2nM n=4). These data suggest an important role for the TRPV‐4 channels in vasodilation to Ach, and regulation of endothelial intracellular Ca2+in mice MA.

On the Role of the First Transmembrane Domain in Cation Permeability and Flux of the ATP-gated P2X2 Receptor

P2X receptors are a family of seven ligand-gated ion channels (P2X1-P2X7) that open in the presence of ATP. We used alanine-scanning mutagenesis and patch clamp photometry to study the role of the first transmembrane domain of the rat P2X2 receptor in cation permeability and flux. Three alanine-substituted mutants did not respond to ATP, and 19 of the 22 functional receptors resembled the wild-type receptor with regard to the fraction of the total ATP-gated current carried by calcium or the permeability of calcium relative to cesium. The remaining three mutants showed modest changes in calcium dynamics. Two of these occurred at sites (Gly30 and Phe44) that are unlikely to interact with permeating cations in a meaningful way. The third was a conserved tyrosine (Tyr43) that may form an inter-pore binding site for calcium. The data suggest that, with the possible exception of Tyr43, the first transmembrane domain contributes little to the permeation properties of the P2X2 receptor.

Control of Cation Permeation through the Nicotinic Receptor Channel

We used molecular dynamics (MD) simulations to explore the transport of single cations through the channel of the muscle nicotinic acetylcholine receptor (nAChR). Four MD simulations of 16 ns were performed at physiological and hyperpolarized membrane potentials, with and without restraints of the structure, but all without bound agonist. With the structure unrestrained and a potential of −100 mV, one cation traversed the channel during a transient period of channel hydration; at −200 mV, the channel was continuously hydrated and two cations traversed the channel. With the structure restrained, however, cations did not traverse the channel at either membrane potential, even though the channel was continuously hydrated. The overall results show that cation selective transport through the nAChR channel is governed by electrostatic interactions to achieve charge selectivity, but ion translocation relies on channel hydration, facilitated by a trans-membrane field, coupled with dynamic fluctuations of the channel structure.

Cation channels in human embryonic kidney cells mediating calcium entry in response to extracellular low glucose

Glucose sensing mechanism has been intensively studied in pancreatic cells and neurons. Depolarization of membrane potential by closure of K ATP , Kv and TASK channel, and subsequently Ca 2+ entry via L-type voltage gated Ca 2+ channel (VGCC) are implicated to mediate the signal transduction in these cells. However, the mechanism of non-excitable cells, which are lacking VGCC, for sensing glucose remains unclear. In this study, we utilized the calcium ratio measurement and patch clamping technique to study the effects of low glucose on [Ca 2+] i and currents in the human embryonic kidney epithelial cells (HEK 293). We found low glucose evoked a significant reversible [Ca 2+] i elevation in HEK 293 independent of the closure of Kv channels. This increase of [Ca 2+] i was mediated by Ca 2+ entry across plasma membrane and exhibited a dosage dependent behaviour to external glucose concentration. The low glucose-induced entry of Ca 2+ was characterized as a voltage independent behaviour and had cation permeability to Na + and Ca 2+. The modulation of PLC, AMPK, tyrosine kinase and cADPribose failed to regulate this glucose-sensitive Ca 2+ entry. In addition, the entry of Ca 2+ was insensitive to nifedipine, 2APB, SKF, La 3+, Gd 3+, and KBR9743, suggesting a novel signal pathway in mediating glucose sensing.

Activating mutation in a mucolipin transient receptor potential channel leads to melanocyte loss in varitint–waddler mice

Transient receptor potential (TRP) genes of the mucolipin subfamily (TRPML1-3 and MCOLN1-3) are presumed to encode ion channel proteins of intracellular endosomes and lysosomes. Mutations in human TRPML1 (mucolipin 1/MCOLN1) result in mucolipidosis type IV, a severe inherited neurodegenerative disease associated with defective lysosomal biogenesis and trafficking. A mutation in mouse TRPML3 (A419P; TRPML3(Va)) results in the varitint-waddler (Va) phenotype. Va mice are deaf, exhibit circling behavior due to vestibular defects, and have variegated/dilute coat color as a result of pigmentation defects. Prior electrophysiological studies of presumed TRPML plasma membrane channels are contradictory and inconsistent with known TRP channel properties. Here, we report that the Va mutation produces a gain-of-function that allows TRPML1 and TRPML3 to be measured and identified as inwardly rectifying, proton-impermeant, Ca(2+)-permeant cation channels. TRPML3 is highly expressed in normal melanocytes. Melanocyte markers are lost in the Va mouse, suggesting that their variegated and hypopigmented fur is caused by severe alteration of melanocyte function or cell death. TRPML3(Va) expression in melanocyte cell lines results in high resting Ca(2+) levels, rounded, poorly adherent cells, and loss of membrane integrity. We conclude that the Va phenotype is caused by mutation-induced TRPML3 gain-of-function, resulting in cell death.

SIK1 is part of a cell sodium-sensing network that regulates active sodium transport through a calcium-dependent process

In mammalian cells, active sodium transport and its derived functions (e.g., plasma membrane potential) are dictated by the activity of the Na(+),K(+)-ATPase (NK), whose regulation is essential for maintaining cell volume and composition, as well as other vital cell functions. Here we report the existence of a salt-inducible kinase-1 (SIK1) that associates constitutively with the NK regulatory complex and is responsible for increases in its catalytic activity following small elevations in intracellular sodium concentrations. Increases in intracellular sodium are paralleled by elevations in intracellular calcium through the reversible Na(+)/Ca(2+) exchanger, leading to the activation of SIK1 (Thr-322 phosphorylation) by a calcium calmodulin-dependent kinase. Activation of SIK1 results in the dephosphorylation of the NK alpha-subunit and an increase in its catalytic activity. A protein phosphatase 2A/phosphatase methylesterase-1 (PME-1) complex, which constitutively associates with the NK alpha-subunit, is activated by SIK1 through phosphorylation of PME-1 and its dissociation from the complex. These observations illustrate the existence of a distinct intracellular signaling network, with SIK1 at its core, which is triggered by a monovalent cation (Na(+)) and links sodium permeability to its active transport.

Cloning of a putative hypersensitive induced reaction gene from wheat infected by stripe rust fungus

The hypersensitive response (HR) is one of the most efficient forms of plant defense against biotrophic pathogens and results in localized cell death and the formation of necrotic lesions. In this study, a novel putative hypersensitive induced reaction (HIR) gene from wheat leaves infected by incompatible stripe rust pathogen CY23, designated as Ta-hir1, was identified by using rapid amplification of cDNA ends (RACE). Ta-hir1 encodes 284 amino acids, with a predicted molecular mass of 31.31 KDa. A phylogenetic analysis showed that Ta-hir1 was highly homologous to Hv-hir1 from barley at both cDNA and deduced amino-acid levels. Amino-acid sequence analysis of the wheat HIR protein indicated the presence of the SPFH (Stomatins, Prohibitins, Flotillins and HflK/C) protein domain typical for stomatins which served as a negative regulator of univalent cation permeability, especially for potassium. The expression profile of the Ta-hir1 transcript detected by reverse transcriptase-polymerase chain reaction (RT-PCR) and real-time polymerase chain reaction (real time-PCR), respectively, showed that the highest expression occurred 48 h post inoculation (hpi), which is consistent with our previous histopathology observations during the stripe rust fungus–wheat incompatible reaction.

The regulation of intracellular pH in bacteria.

The regulation of intracellular pH (pHi) in bacterial cells is achieved through control over cation (and anion) permeability. In addition to the active components of homeostasis there are contributions from essentially passive elements, such as the lipid composition of the membrane and the buffering capacity of the cytoplasm. Active homeostasis involves control over the movement of K+, Na+ and H+. Alterations in the membrane permeability for any of these cations may cause perturbation of homeostasis. In Escherichia coli this is exemplified by the controlled activation of K+ efflux systems by glutathione adducts leading to temporary acidification of the cytoplasm. This is achieved by sophisticated control over the KefB and KefC systems, and is tightly integrated with glutathione-dependent detoxification mechanisms. Such control over pHi facilitates survival of the cell following exposure to toxic electrophiles. The components of pH homeostasis will be reviewed and the molecular mechanisms, and role of, the KefB and KefC systems will be discussed.

Transduction mechanisms of P2Z purinoceptors.

The ability of extracellular ATP to increase the cation permeability of a variety of fresh and cultured cells has been known for decades, but evidence of a separate class of P2 purinoceptor, termed P2Z, which mediates this effect has only recently been obtained. Several features of the P2Z purinoceptor clearly distinguish it from other P2 purinoceptors and show that it is a ligand-gated ion channel. P2Z purinoceptors are highly selective for the ATP4- species and addition of Mg2+ in excess over ATP closes the channel. The most potent agonist is 3'-O-(4-benzoyl)benzoyl ATP which has a 10-fold lower EC50 than ATP. Ca2+ is the preferred permeant for the P2Z ion channel although it will pass ions up to the size of ethidium(+) (314 Da) in lymphocytes or fura-2 (813 Da) in macrophages. The inhibitors of the P2Z purinoceptor or its associated ion channel include suramin, amiloride analogues, high extracellular Na+ concentrations and 2',3'-dialdehyde ATP (oxidized ATP), which blocks irreversibly. Occupancy of P2Z purinoceptors stimulates a phospholipase D activity, which may be involved in membrane remodelling. Moreover, extracellular ATP causes loss of the glycosylated adhesion molecule L-selection from the surfaces of human lymphocytes by enzymic cleavage, suggesting a possible role for P2Z purinoceptors in intercellular interactions.

Molecular Determinant for Specific Ca/Ba Selectivity Profiles of Low and High Threshold Ca2+ Channels

Voltage-gated Ca2+ channels (VGCC) play a key role in many physiological functions by their high selectivity for Ca2+ over other divalent and monovalent cations in physiological situations. Divalent/monovalent selection is shared by all VGCC and is satisfactorily explained by the existence, within the pore, of a set of four conserved glutamate/aspartate residues (EEEE locus) coordinating Ca2+ ions. This locus however does not explain either the choice of Ca2+ among other divalent cations or the specific conductances encountered in the different VGCC. Our systematic analysis of high- and low-threshold VGCC currents in the presence of Ca2+ and Ba2+ reveals highly specific selectivity profiles. Sequence analysis, molecular modeling, and mutational studies identify a set of nonconserved charged residues responsible for these profiles. In HVA (high voltage activated) channels, mutations of this set modify divalent cation selectivity and channel conductance without change in divalent/monovalent selection, activation, inactivation, and kinetics properties. The CaV2.1 selectivity profile is transferred to CaV2.3 when exchanging their residues at this location. Numerical simulations suggest modification in an external Ca2+ binding site in the channel pore directly involved in the choice of Ca2+, among other divalent physiological cations, as the main permeant cation for VGCC. In LVA (low voltage activated) channels, this locus (called DCS for divalent cation selectivity) also influences divalent cation selection, but our results suggest the existence of additional determinants to fully recapitulate all the differences encountered among LVA channels. These data therefore attribute to the DCS a unique role in the specific shaping of the Ca2+ influx between the different HVA channels.

Canine erythrocytes express the P2X7receptor: greatly increased function compared with human erythrocytes

Over three decades ago, Parker and Snow (Am J Physiol 223: 888-893, 1972) demonstrated that canine erythrocytes undergo an increase in cation permeability when incubated with extracellular ATP. In this study we examined the expression and function of the channel/pore-forming P2X(7) receptor on canine erythrocytes. P2X(7) receptors were detected on canine erythrocytes by immunocytochemistry and immunoblotting. Extracellular ATP induced (86)Rb(+) (K(+)) efflux from canine erythrocytes that was 20 times greater than that from human erythrocytes. The P2X(7) agonist 2'(3')-O-(4-benzoylbenzoyl)adenosine 5'-trisphosphate (BzATP) was more potent than ATP, and both stimulated (86)Rb(+) efflux from erythrocytes in a dose-dependent fashion with EC(50) values of approximately 7 and approximately 309 microM, respectively. 2-Methylthioadenosine 5'-triphosphate and adenosine 5'-O-(3-thiotriphosphate) induced a smaller (86)Rb(+) efflux from erythrocytes, whereas ADP, AMP, UTP, or adenosine had no effect. ATP-induced (86)Rb(+) efflux from erythrocytes was inhibited by oxidized ATP, KN-62, and Brilliant blue G, known P2X(7) antagonists. ATP also induced uptake of choline(+) into canine erythrocytes that was 60 times greater than that into human erythrocytes. Overnight incubation of canine erythrocytes with ATP and BzATP induced phosphatidylserine exposure in >80% of cells and caused up to 20% hemolysis. In contrast, <30% of human erythrocytes showed phosphatidylserine exposure after overnight incubation with ATP and BzATP, and hemolysis was negligible. Flow cytometric measurements of ATP-induced ethidium(+) uptake showed that P2X(7) function was three times lower in canine monocytes than in human monocytes. These data show that the massive cation permeability increase induced by extracellular ATP in canine erythrocytes results from activation and opening of the P2X(7) receptor channel/pore.

Effects of age-dependent membrane transport changes on the homeostasis of senescent human red blood cells

AbstractLittle is known about age-related changes in red blood cell (RBC) membrane transport and homeostasis. We investigated first whether the known large variation in plasma membrane Ca2+ (PMCA) pump activity was correlated with RBC age. Glycated hemoglobin, Hb A1c, was used as a reliable age marker for normal RBCs. We found an inverse correlation between PMCA strength and Hb A1c content, indicating that PMCA activity declines monotonically with RBC age. The previously described subpopulation of high-Na+, low-density RBCs had the highest Hb A1c levels, suggesting it represents a late homeostatic condition of senescent RBCs. Thus, the normal densification process of RBCs with age must undergo late reversal, requiring a membrane permeability increase with net NaCl gain exceeding KCl loss. Activation of a nonselective cation channel, Pcat, was considered the key link in this density reversal. Investigation of Pcat properties showed that its most powerful activator was increased intracellular Ca2+. Pcat was comparably selective to Na+, K+, choline, and N-methyl-D-glucamine, indicating a fairly large, poorly selective cation permeability pathway. Based on these observations, a working hypothesis is proposed to explain the mechanism of progressive RBC densification with age and of the late reversal to a low-density condition with altered ionic gradients.

A light switch controlling Ca2+‐permeable AMPA receptors in the retina

At most excitatory, glutamatergic synapses in the brain, AMPA and NMDA-type glutamate receptors (AMPARs and NMDARs) make distinct contributions to the postsynaptic response: AMPARs mediate transient conductances that are well suited to fast information transfer; NMDARs associate glutamate binding with postsynaptic depolarization to mediate a slower conductance that, unlike that of most AMPARs, includes Ca2+ influx that can trigger long-lasting changes in synaptic strength. This delegation of postsynaptic roles has been blurred recently by evidence implicating Ca2+-permeable AMPARs (CP-AMPARs) in different forms of synaptic transmission and plasticity. AMPARs are heterotetramers comprising various combinations of subunits GluR1–4, each of which is coded to express an uncharged glutamine in the pore region that permits permeation of divalent cations. In GluR2, RNA editing recodes this glutamine to a positively charged arginine, rendering GluR2-containing AMPARs Ca2+ impermeable (Dingledine et al. 1992). Many neurons, however, express AMPARs that lack GluR2 and are, consequently, Ca2+ permeable. Particularly in interneurons, CP-AMPARs often replace NMDARs as the primary source of postsynaptic Ca2+ influx. For example, Ca2+ influx through CP-AMPARs induces long-term potentiation (LTP) of excitatory synapses onto interneurons in the amygdala (Mahanty & Sah, 1998) and triggers GABA release from A17 amacrine cells in the retina (Chavez et al. 2006). CP-AMPAR channels are distinguished electrophysiolgically via voltage-dependent block by (and eventual permeation of) endogenous intracellular polyamines that confers biphasic rectification on an otherwise linear I–V relationship (Bahring et al. 1997). CP-AMPARs also are blocked by exogenous extracellular polyamines such as philanthotoxin (Washburn et al. 1997). Ca2+ permeability and polyamine sensitivity typically go hand in hand, but a paper in this issue of The Journal of Physiology reports CP-AMPARs in rat retinal interneurons that are insensitive to philanthotoxin (Osswald et al. 2007). The expression of these receptors coincides with eye opening and is delayed by rearing animals in darkness, suggesting that they may participate in a critical phase of retinal development. Functional CP-AMPARs are detected using cobalt staining and electrophysiology. Cobalt permeates CP-AMPARs and so fills cells expressing activated receptors. Following exposure to cobalt and glutamate, retinas were fixed according to a protocol that rendered cobalt-positive horizontal and amacrine cells a deep orange. Particularly strong staining was observed in AII amacrine cells, glycinergic interneurons known to express CP-AMPARs. Cobalt staining was not induced by membrane depolarization in the absence of glutamate and was unaffected by NMDAR and metabotropic glutamate receptor (mGluR) antagonists but was abolished by AMPAR antagonists, including philanthotoxin. During the third postnatal week, around the time of eye opening (∼P14), cobalt staining persisted, but philanthotoxin sensitivity disappeared in horizontal cells and was reduced in AII cells, particularly in processes ramifying in the outer portion of the inner plexiform layer (IPL), where synapses transmitting ‘OFF’ visual signals are made. AII cells, but not horizontal cells, recovered philanthotoxin sensitivity 2 weeks later. Decreased philanthotoxin sensitivity did not occur in dark-reared animals, suggesting that light-induced activity may trigger the change. Interestingly, voltage clamp recordings of spontaneous synaptic currents in AII cells also reflected the transient disappearance of philanthotoxin sensitivity. This, together with the morphological data described above, would suggest that most spontaneous activity in AIIs arises at synapses in the ‘OFF’ region of the IPL. This is a bit surprising, as most synapses onto AIIs are made by rod bipolar cells (RBCs) in the ON region, and spontaneous events in AIIs are indistinguishable from evoked quantal events from RBCs (Singer et al. 2004). The molecular mechanism underlying this peculiar developmental switch remains unknown, but the authors propose the possibility of a novel AMPAR subtype (or novel RNA editing of known subunits), a reasonable suggestion given that other glutamate receptors (e.g. mGluR6) and transporters (e.g. EAAT5) appear unique to the retina. The functional impact of these philanthotoxin-insensitive CP-AMPARs also remains to be determined. Relief of polyamine sensitivity could change postsynaptic responsivity to patterns of synaptic input (Rozov & Burnashev, 1999) during a time when excitatory synaptic connections with bipolar cells are first being established (Horsburgh & Sefton, 1987). Alternatively, the authors suggest that these receptors may act as temporary molecular cues to direct formation of synaptic connections within specific sublaminae of the IPL, a critical step in the proper wiring of ON and OFF visual pathways.

Sodium Flux Ratio in Na/K Pump-Channels Opened by Palytoxin

Palytoxin binds to Na+/K+ pumps in the plasma membrane of animal cells and opens an electrodiffusive cation pathway through the pumps. We investigated properties of the palytoxin-opened channels by recording macroscopic and microscopic currents in cell bodies of neurons from the giant fiber lobe, and by simultaneously measuring net current and 22Na+ efflux in voltage-clamped, internally dialyzed giant axons of the squid Loligo pealei. The conductance of single palytoxin-bound “pump-channels” in outside-out patches was ∼7 pS in symmetrical 500 mM [Na+], comparable to findings in other cells. In these high-[Na+], K+-free solutions, with 5 mM cytoplasmic [ATP], the K 0.5 for palytoxin action was ∼70 pM. The pump-channels were ∼40–50 times less permeable to N-methyl-d-glucamine (NMG+) than to Na+. The reversal potential of palytoxin-elicited current under biionic conditions, with the same concentration of a different permeant cation on each side of the membrane, was independent of the concentration of those ions over the range 55–550 mM. In giant axons, the Ussing flux ratio exponent (n') for Na+ movements through palytoxin-bound pump-channels, over a 100–400 mM range of external [Na+] and 0 to −40 mV range of membrane potentials, averaged 1.05 ± 0.02 (n = 28). These findings are consistent with occupancy of palytoxin-bound Na+/K+ pump-channels either by a single Na+ ion or by two Na+ ions as might be anticipated from other work; idiosyncratic constraints are needed if the two Na+ ions occupy a single-file pore, but not if they occupy side-by-side binding sites, as observed in related structures, and if only one of the sites is readily accessible from both sides of the membrane.

Selectivity in K+ channels is due to topological control of the permeant ion's coordinated state.

The selectivity filter of K+ channels provides specific coordinative interactions between dipolar carbonyl ligands, water, and the permeant cation, which allow for selective flow of K+ over (most importantly) Na+ across the cell membrane. Although a structural viewpoint attributes K+ selectivity to coordination geometry provided by the filter, recent molecular dynamics simulation studies attribute it to dynamic and unique chemical/electrostatic properties of the filter's carbonyl ligands. Here we provide a simple theoretical analysis of K+ and Na+ complexation with water in the context of simplified binding site models and bulk solution. Our analysis reveals that water molecules and carbonyl groups can both provide K+ selective environments if equivalent constraints are imposed on the coordination number of the complex. Absence of such constraints annihilates selectivity, demonstrating that whether a coordinating ligand is a water molecule or a carbonyl group, "external" or "topological" constraints/forces must be imposed on an ion-coordinated complex to elicit selective binding. These forces must inevitably originate from the channel protein, because in bulk water, which, by definition, presents a nonselective medium, the coordination number is allowed to relax to suit the ion. We show that the coordination geometry of K+ channel binding sites is replicated by 8-fold complexation of K+ in both water and simplified binding site models due to dominance of local interactions within a complex and is thus a requirement for topologically constraining the coordination number to a specific value.

Claudin-8 Expression in Renal Epithelial Cells Augments the Paracellular Barrier by Replacing Endogenous Claudin-2

Claudins are transmembrane proteins of the tight junction that determine and regulate paracellular ion permeability. We previously reported that claudin-8 reduces paracellular cation permeability when expressed in low-resistance Madin-Darby canine kidney (MDCK) II cells. Here, we address how the interaction of heterologously expressed claudin-8 with endogenous claudin isoforms impacts epithelial barrier properties. In MDCK II cells, barrier improvement by claudin-8 is accompanied by a reduction of endogenous claudin-2 protein at the tight junction. Here, we show that this is not because of relocalization of claudin-2 into the cytosolic pool but primarily due to a decrease in gene expression. Claudin-8 also affects the trafficking of claudin-2, which was displaced specifically from the junctions at which claudin-8 was inserted. To test whether replacement of cation-permeable claudin-2 mediates the effect of claudin-8 on the electrophysiological phenotype of the host cell line, we expressed claudin-8 in high-resistance MDCK I cells, which lack endogenous claudin-2. Unlike in MDCK II cells, induction of claudin-8 in MDCK I cells (which did not affect levels of endogenous claudins) did not alter paracellular ion permeability. Furthermore, when endogenous claudin-2 in MDCK II cells was downregulated by epidermal growth factor to create a cell model with low transepithelial resistance and low levels of claudin-2, the permeability effects of claudin-8 were also abolished. Our findings demonstrate that claudin overexpression studies measure the combined effect of alterations in both endogenous and exogenous claudins, thus explaining the dependence of the phenotype on the host cell line.

Permeation of 6-nitro-3-phenylacetamide benzoic acid (NIPAB) and hydrolysis by penicillin acylase immobilized in emulsion liquid membranes.

The effects of various commercial and model surfactants of different structure and hydrophilicity were studied on water-in-oil (w/o) emulsion stability, potassium cation leakage and permeation of 6-nitro-3-phenylacetamide benzoic acid in a model system using Penicillin acylase (EC 3.5.1.11) immobilized in a liquid membrane. Both emulsion stability, potassium leakage and permeation of organic substances depend upon hydrophilicity of surfactants. Hydrophilic surfactants may be used to stabilize emulsions only in mixtures with hydrophobic emulsifiers. Additions of small quantities of hydrophilic surfactants to the system in which permeation occurs together within an enzymatic process may be advantageous. Both the rate of permeation and potassium transfer significantly increase when hydrophilic surfactants are present. There was no relationship observed between potassium cation transfer from the internal phase and emulsion stability in the storage test.

Ivermectin Interaction with Transmembrane Helices Reveals Widespread Rearrangements during Opening of P2X Receptor Channels

P2X receptors are trimeric cation channels that open in response to binding of extracellular ATP. Each subunit contains a large extracellular ligand binding domain and two flanking transmembrane (TM) helices that form the pore, but the extent of gating motions of the TM helices is unclear. We probed these motions using ivermectin (IVM), a macrocyclic lactone that stabilizes the open state of P2X(4) receptor channels. We find that IVM partitions into lipid membranes and that transfer of the TM regions of P2X(4) receptors is sufficient to convey sensitivity to the lactone, suggesting that IVM interacts most favorably with the open conformation of the two TM helices at the protein-lipid interface. Scanning mutagenesis of the two TMs identifies residues that change environment between closed and open states, and substitutions at a subset of these positions weaken IVM binding. The emerging patterns point to widespread rearrangements of the TM helices during opening of P2X receptor channels.